Chapter 6: Educational Games
Contents
1. UNLIKES WHERE THE ANALOGY BREAKS DOWN Student Centred Approaches for Science Education Part 3 29 Light rays are very narrow whereas wheels are quite wide Two wheels are needed to represent one ray of light Optical density of the glass slows the light whereas friction slows the wheels 5 Bridging analogies for the balanced forces of a book on a table Link with curriculum Grade 8 chapter 2 lesson 1 3 2010 Objects like tables exert an upward reaction force on objects placed on them Newton s Third Law Objects such as books do not move because the upward and downward forces are balanced A bridging analogy is a series of small analogies that is used to bridge the gap towards an understanding of a concept Balanced forces in squeezing a spring act as an anchor for understanding similar situations such as a book on a flimsy table or the book on a normal table This analogy helps understanding action and reaction forces Anchor Bridging Case Target Source Clement 2003 LIKES WHERE THE ANALOG MATCHES THE CONCEPT A compressed spring exerts force back on a Book has a downward weight but no hand deformation can be seen or felt Flimsy table bends under the book sitting on The table must push back on the book on top it of it UNLIKES WHERE THE ANALOGY BREAKS DOWN The table exerts a reaction force but does not visibly bend under the book s weight T2. UNLIKES WHERE THE ANALOGY BREAKS DOWN The domelike shape of the sky is only apparent there is no real dome Because of various landforms we seldom see the horizon as a circle 6 The Motion of the Planets in the solar system Link with Curriculum Grade 7 chapter 1 chapter 3 2009 Many students have a wrong or incomplete understanding of motions and scales in the solar system It is important to spend enough time developing conceptual understanding with the students Using models and role plays as analogies is an excellent way to achieve this A mechanical model of a part of the solar system called an orrery can show relative motions of Earth Moon and Sun Otherwise in a role play students can play the different planets moons and the Sun This can vary from a simple model with only a few planets to a full scale role play with many planets moons and even comets or asteroids Prepare cards with the names and a picture of planets moons the sun etc Every student picks a card They discuss with each other where they have to stand how they need to move how fast etc You can make a set of cards for each group of students You may repeat the activity a few times until everyone has a firm grasp of the structure of the solar system Discussion questions after the role play may include Why do the Moon and Venus have phases and Jupiter not On which planet takes a year the longest What are the limitati
3. 6 Loop games 1 Introduction A loop game is an interactive review game that can be played in various ways 2 Objectives To increase students understanding on a topic or unit of instruction by presenting it in a different context Tomake students familiar with the idea of loop games 3 Link with curriculum A loop game can be played with many topics in all science subjects 4 When to use this technique As a review activity during stage 4 of the lesson 5 Material needed Prepare as many cards as there are students Laminate cards to make them more durable Student Centred Approaches for Science Education Part 3 91 6 Procedure 8 x M Each student receives one card Each card contains a question and an answer on a different question One student starts reading his question aloud The student who thinks the answer on this question is on his card stands up and reads the answer If it s correct the student goes on to read the question on his card The student who has the correct answer stands up to read the answer and so until all questions and answers have been read f there is time left you can play the game a second time Encourage students to beat the time from the first round 7 Examples See annex for a set of cards for chemistry atoms The questions are a starting point You can change the questions according to the level of the students and the content of the less
4. Divide students in small groups Let students discuss and try to fill in each square of the table Stimulate them to find creative but correct relationships between the analog and the items in the Square Afterwards let them present their results Provide feedback on the correctness of the analogies used Stimulate students to try and recognize when analogies are not correctly used This helps them to develop critical thinking skills 3 Material No material is needed unless pictures to illustrate the items in the table Y 4 When to use this technique You can apply synectics as a consolidation activity to strengthen your students understanding of the topic stage 3 You can use it to explain a difficult or abstract concept stage 3 You can use it as a review activity at the end of a series of lessons stage 4 5 Examples from curriculum A list of topics and suitable analogies is listed in annex If you have multiple analogies for a concept you can use synectics For chemistry structure of the atom Grade 8 chapter 1 lesson 1 2010 is a possible topic For physics electric circuits Grade 7 chapter 3 lesson 6 2009 are an excellent example For earth and environmental science the solar system its structure origin Grade 7 chapter 1 lesson 1 2009 could be described with multiple analogies Student Centred Approaches for Science Education Part 3 16 3 Models 1 Introduction gt
5. Analogies are a two edged sword They offer enormous potential for student centred learning but on the other hand when used without care they can develop or enhance misconceptions Every analogy breaks down at a certain point the point where the analogy is not a correct explanation of the concept This point should be clear for all students For example when a teacher compares solid matter with students sitting in the classroom at their desks and liquid matter with students doing a group activity in the class students may wrongly derive that atomic particles are like little organisms and act purposefully This unit presents a set of analogies for wide range of science subjects Besides it offers effective and student centred ways to integrate them in your lessons However these analogies should be regarded as a starting point Don t be afraid to change adapt or improve them Or even better let your students create their own analogies This chapter introduces 5 techniques to integrate analogies in your science lessons They are ordered loosely in order of student involvement We mentioned above that the more students are invited to think and develop the analogy the stronger its effect will be Student Centred Approaches for Science Education Part 3 9 Activities 1 Using the Focus Action Reflection FAR Guide 1 Introduction The Focus Action Reflection FAR guide offers a carefully planned strategy in orde
6. 2 Objectives A Students practice their knowledge of key concepts definitions and formulas Students are engaged with the lesson content Students can make and apply a memory game with their students 3 Link with curriculum This game can be applied with many topics from all sciences Student Centred Approaches for Science Education Part 3 79 4 When to play the game 5 Material needed You need a set of approx 20 cards The more cards the more difficult the game gets Two cards always belong together For example a keyword and its explanation Or a concept and its opposite a symbol and its meaning etc Make sure the back sides are identical so matching cards cannot be easily recognized You need one set of cards per 4 or 5 people If you have different sets of cards groups of students can pass them on when they have finished You may laminate the cards to make them more durable 6 Procedure CLs T a Give one set of cards to each group of students The game is best played in groups of 4 or 5 students The smaller the groups the more active their involvement but the more sets you need to make Students mix the cards and place them in front of them with back sides up They re not allowed to see which card is where Student take turns in flipping two cards If the two cards match the student can take them from the table and put them on a personal stack If they don t match he p
7. Models can be seen as simplified constructions of reality and are thus a type of analogy They have the advantage that they can be seen and touched by students increasing their familiarity with the analog and improving the relation with the concept Constructing models creates a concrete immediate image to students and reduces the chance that they will misunderstand the analogy SN 2 Objectives Students develop higher order thinking skills Students develop creative thinking skills Students learn to link prior knowledge with new concepts Students learn to work together 3 How to use this technique e NT 7 d Try to let students discover the relation between the model and the concept for themselves Of course this depends on their prior knowledge If necessary you need to help the students The more they can find out themselves the stronger they will make the relation between concept and model However be sure to point out where the model does not correspond with reality in order to avoid misconceptions Student Centred Approaches for Science Education Part 3 17 4 Material This depends on the type of model Many models can be constructed with low cost materials Sometimes you can let students construct their own model Building their own model increases the memorability and their motivation 5 When to use this technique You can apply model building as a consolidation activity to strengthen yo
8. The game usually takes a full hour to play It is best used as a review activity at the end of a unit of instruction 5 Material needed Game board Dice Questions on sheet of paper Whiteboard Markers If available it is useful to attach the game board to a magnetic plate The pawns of each group are magnets that can move but stick on the board 6 Procedure e NIC XM Description of the game board There are 5 colours of numbers Each colour corresponds with a topic In the prototype green means a question on mechanics yellow a question on light red a question on heat brown on electricity and magnetism and orange on pressure The game board counts some special fields When players reach these fields they need to do 1 exercise When they have completed the exercise they ask for a teacher to verify the answer This numbers counts as a skip one turn number but if the students are fast they can prevent having to skip one turn It could also result in having to skip 2 turns this is the maximum You may include other special fields allowing for example players to move 5 spaces ahead or making them go back 5 spaces Student Centred Approaches for Science Education Part 3 101 In the prototype we included a Swap field shown below If a team stops on this field it can swap position with another team usually the team at first position This introduces an element of luck in the g
9. Water flow rates decline as the bottle gets emptier a battery may have reduced potential difference across its terminals but it is not empty 8 The analogy of doors in a meeting hall for parallel circuits Link with curriculum Grade 7 chapter 3 lesson 6 2009 Parallel electric circuits function as independent circuits Two light bulbs connected in parallel glow equally bright Each light receives the battery s full voltage and they divide the current between them A useful analog is that of students leaving a big meeting room The rate that students can leave the meeting room depends on the number of doors open This is like a circuit with light bulbs connected in parallel Teaching this analogy can be combined with a role play exercise You can lead the role play or let students organize it depending on student age LIKES WHERE THE ANALOG MATCHES THE CONCEPT Meeting room full of students Fully charged battery Students exiting through 1 door open One bulb in the circuit Students exiting through 2 doors open Two bulbs connected in parallel Students exiting through 2 consecutive doors Two bulbs connected in series in one hallway Speed of exit through each door is the same Each bulb receives the same voltage and current 2 doors open hall empties twice as fast 2 bulbs in parallel battery runs flat twice as fast UNLIKES WHERE THE ANALOGY BREAKS DOWN Two light bulbs often do not
10. 7 Important tips Make sure that students are sufficiently familiar with the analog before doing the activity Explicitly mapping the similarities and dissimilarities between the concept and the analog is important since it avoids creating new misconceptions with the students Student Centred Approaches for Science Education Part 3 14 2 Synectics 1 Introduction The word synectics is derived from the Greek language It means fitting together items that appear to be completely unrelated This technique uses analogies to connect students ideas with a concept 2 Objectives Students learn to examine abstractly what they know about a concept Students link prior knowledge with new concepts Students learn to think creatively and outside the box Students learn to make new connections Teacher discovers difficulties students have in understanding science concepts 3 How to use this technique C MM Provide students with a chart containing four to six boxes In the box list items that could be used to describe the scientific concept you want to explain You can write the table on the whiteboard or give students a copy A chart to explain cell structure could be like the one below Student Centred Approaches for Science Education Part 3 15 A cellis like a because LLL LLL rl l l Market School Brick wall Company
11. CONCEPT Rice grain Atom or ion Large country such as China covered with rice grains to depth of approx 5 km Avogadro s number of rice grains Student Centred Approaches for Science Education Part 3 67 UNLIKES WHERE THE ANALOGY BREAKS DOWN Rice grains are much larger than atoms 5 Therole play for chemical reactions Link with Curriculum chemical reactions electrolysis Grade 11 chapter 3 lesson 5 2009 Chemical reactions can be visualized in a fun way using role plays An example is the extraction of copper metal from copper carbonate involving the electrolysis of copper sulphate There are three steps in this reaction process The dissolution of copper carbonate Formation of copper sulphate Electrolysis of copper sulphate carbon cethode 7 CafDOn anoce bubbles of oxygen gas copper it sulfate solution copper gepos Source Harrison and Coll 2008 Reaction equation At cathode Cu aq 2 gt Cu s At Anode 2H 0 I gt 4H O g 4e Students are assigned roles as atoms or ions and make labels Five students make up copper carbonate CuCO3 Linking of arms represents covalent bonds within the complex ion and an ionic bond between copper ions and the electrons are represented by two books held in the hand which rests on the shoulder Thus before dissolution in water we have a group of four students linked together by thei
12. Improvements Are there any changes to be made next time you use this analogy Summary of the FAR guide technique for analogies The focus part includes identifying the concept that you expect students to have difficulty with to understand What is it that makes the concept difficult to understand Is it the small or large scale of the concept cell atom Avogadro s number Is it the function or structure that is difficult to understand DNA ATP Or is the concept counterintuitive to daily life atomic structure electric current Next you need to know what prior knowledge students already have about the concept If it is correct you can build on it In case it is incorrect it needs to be changed by the teacher There are tools that you can use to assess the students prior knowledge brainstorming concept cartoons Finally evaluate whether your students are familiar with the analog that you want to use For example comparing a cell with a city doesn t make sense if students are not familiar with a big city It is useful to check whether students are familiar with the solar system before using it as an analog for the atomic structure You can illustrate the analog with pictures or a poster During the lesson students study the analog and its relation with the concept Let them work in small groups to fill in a table like the one below They map the similarities and dissimilarities between the concept and the analog while di
13. Student Centred Approaches for Science Education Part 3 93 6 Procedure Las 72 Lupo Give each group of students 4 to 5 students a set of domino cards nstruct students to work together to match domino cards together You can organize a competition in which students try to complete the domino as soon as possible For every mistake they lose a number of seconds 7 Examples In the annex we have included an example for each topic Biology genetics Earth science space Chemistry symbols Physics general You can make and play domino games for many other topics 8 Important Tips The more domino cards the more difficult to solve the game and the longer it will take the students An average set contains around 20 cards You may let students try to develop their own domino game in groups Then groups play each other s game Student Centred Approaches for Science Education Part 3 94 8 Chemistry Element Bingo 1 Introduction Elements Bingo is a game for learning about the Periodic Table of Elements Students play just like a normal Bingo Game except all items and cards have a chemistry element topic This kind of game is expected to stimulate students enjoy and enthusiasm while they actively participate 2 Objectives This game is designed to help students learn how to become acquainted with the elements in the periodic table and determine element symbols and names 3 Lin
14. connected to students daily lives MoEYS strongly encourages all teacher trainers to use this manual to teach science in the teacher training centres and thus contribute to improve the quality of science education in Cambodia On behalf of MoEYS I would like to express sincere thanks to the team and educational advisors of the Flemish Association for Cooperation Development and Technical Assistance VVOB for their energy motivation and intellectual spirit to develop these useful manuals Phnom Penh March 15 2012 Minister of Education Youth and Sport H E Im Sethy signature and seal Student Centred Approaches for Science Education Part 3 3 Preface The manual on Student Centred Approaches SCA in Science Education is compiled in order to support science teacher trainers in their teaching In 6 chapters we present a wide range of tools and techniques to increase the student centred character of science lessons A student centred approach means literally that the student is placed in the centre of the learning process Some characteristics of a student centred approach include Active involvement of the students in the lesson Students learn from each other not only from the teacher Students are more responsible for their own learning Differences among students are taken into account The tools and techniques in this manual were first introduced at RTTC Kandal A team of teacher trainers and teachers tried ou
15. from the heart to the lungs and body respectively Taps can be closed to prevent the water from Heart valves prevent blood from flowing in flowing backwards the wrong direction Needles can inject substances into places The lungs put oxygen into the blood coming from the right ventricle Factories use up raw materials The body is like a factory that uses up the oxygen in the blood UNLIKES WHERE THE ANALOGY BREAKS DOWN Buckets have an open top where water overflows whereas the atria have valves that allow the movement of blood to the ventricles The movement of gases into and out of the blood in the lungs happens by diffusion bot by an active injection The heart is made of organic substances whereas buckets and pumps are made from inorganic substances The atria actively pump blood to the ventricles It is not a passive process like the dripping of water from a bucket 8 An Origami Paper Model for the Structure of DNA Link with Curriculum Structure of DNA Grade 12 chapter 5 lesson 1 2010 The double helix structure of DNA is made up of two molecular strands twisted into a helix A clear understanding of the chemical structure of DNA and the relation with the production of amino acids and genes is important in biology With a few simple materials students can create a concrete and easy to make model to help them understand the basic structure of DNA Students only need a copy of
16. image formation with convex lenses and candle flames The analogy can work in both directions It can use prior knowledge about the eye from biology lesson to teach about the camera and lenses or it can use knowledge about convex lenses to teach about the eye Student Centred Approaches for Science Education Part 3 Both the camera and the eye form images Real images are formed when light rays from a source point focus on an image point LIKES WHERE THE ANALOG MATCHES THE CONCEPT Convex lens focuses light on film The cornea and lens focus light onto the retina Lens changes position to focus on near and Lens changes shape to focus on near and distant objects distant objects Aperture size controls exposure brightness The pupil controls the brightness of light on the retina Black interior prevents multiple reflections Black interior prevents multiple reflections Lens cap protects the lens Eyelids protect the cornea An image is captured on film or chip Image is captured on the retina UNLIKES WHERE THE ANALOGY BREAKS DOWN A camera has one lens at the front of the camera The eye has two lenses the cornea at the front not adjustable and an adjustable lens behind it A camera captures single images whereas the eye captures continuous images A camera works in a limited range of brightness whereas the eye can work in a vast range of brightness Student Cent
17. the air conditioning However cooling the atmosphere is a very complex scientific and political problem Student Centred Approaches for Science Education Part 3 52 2 The Time Line Analogy for Deep Time Geological Time Link with Curriculum Grade 10 chapter 1 lesson 4 2010 Scientists believe that the history of the earth covers about 4 6 billion years Humans and other mammals have been present in only very recent geological times However many students have difficulty visualizing the magnitude of time intervals involved in geological history relative to their own experiences An analogy between the history of the earth and a roll of paper can be developed as a group activity Students determine the position of key geological events on the paper strip The teacher can decide on the scale of the time line For example a scale in which one A4 sheet takes up 100 million years would require 46 sheets The model can be created and displayed in various ways made outside and photographed or filmed hung around in the classroom just below the ceiling etc Adapted from Harrison and Coll 2008 LIKES WHERE THE ANALOG MATCHES THE CONCEPT A long strip of paper toilet roll connected A4 The earth s 4600 million year history sheets etc Markers on the time line Key geological events Long empty intervals and short crowded Long periods of little biological development sections contrasting with a g
18. the next page and preferably some colour pencils Start with colouring each of the 4 nitrogen bases of the DNA Each colour represents one of the 4 bases in DNA adenine thymine cytosine and guanine Further detailed instructions how to make a model with your students are included on the next page Challenge students to work out appropriate details of the model using their knowledge of DNA You can also stimulate them to develop an alternative analogy to explain the structure of DNA and processes such as transcription and replication Student Centred Approaches for Science Education Part 3 43 The DNA backbone LIKES WHERE THE ANALOG MATCHES THE CONCEPT 4 colours on paper Nitrogen bases 4 types Central structure Desoxyribose and phosphate group Paper parts connected with two or three lines Weak hydrogen bonds between nitrogen bases double and triple bonds UNLIKES WHERE THE ANALOGY BREAKS DOWN DNA molecules are very long consisting of thousands of base pairs whereas this model is relatively short The papers have physical bonds whereas the bonds between the nitrogen bases are chemical bonds Student Centred Approaches for Science Education Part 3 44 How to make your own origami paper DNA model 1 Fold your DNA model Mountain fold Valley fold Abit Solid lines are mountains and are to be folded away from you wit
19. the role play in front of the class whereas one students acts as presenter LIKES WHERE THE ANALOG MATCHES THE CONCEPT Individual Students Atoms Four students linking arms Complex ions Book resting on shoulder person Electron ion Students separating dissolution Air Water Linking with one arm Single bond Linking with two arms Double bond Chair Positive electrode Chair with books on it Negative electrode UNLIKES WHERE THE ANALOGY BREAKS DOWN Students and books are much larger than atoms or electrons Forces bonding atoms together are much stronger than the linked arms There are many more atoms and electrons present than students in the classroom The shape of ions is different from the student arrangements Student Centred Approaches for Science Education Part 3 69 6 The bread analogy for stoichiometry Link with Curriculum stoichiometry Grade 10 chapter 1 lesson 1 2008 Stoichiometry is a difficult concept for many students The basic principles of stoichiometry can be explained with a simple analogy Making a sandwich and representing the recipe using symbols can be used to model the stoichiometry of a chemical reaction the ratios involved as well as the limiting reagent concept For example a sandwich made from two slices of bread and one slice of ham has a ratio of 1 2 By using the masses of ham and bread per slice it is possible to model mas
20. the students 2 Objectives toincrease students understanding of abstract and difficult concepts toincrease student engagement and motivation to stimulate higher order understanding and lateral thinking skills with students 3 How to use this technique E NT 1 Divide students in groups of approx 6 students Assign one student per group to take notes 2 Explain the topic on which students need to develop an analogy 3 During the activity Student Centred Approaches for Science Education Part 3 22 e Provide needed information to the groups give tips and help students to develop their ideas e Provide sufficient time for students to find and develop analogies e Stimulate students to make drawings to illustrate the analogy 4 Let groups present their analogy Let them focus on e Where is the analogy alike the analog e Where is it breaking down 5 Stimulate students to develop their analogy further by asking questions This forces them to think about the concept and will increase their understanding 6 Avoid saying this is right and that is wrong but praise students for their creativity 7 You may use student generated analogies afterwards in a synectics activity 4 Material 5 When to use this technique Use this technique in stage 3 of the lesson as an activity to strengthen students understanding You can combine the technique with other techniques such as the FAR guide Afte
21. Curriculum Grade 8 chapter 1 lesson 3 2010 The role of ATP in living cells is an important biochemical concept but it is abstract and difficult for many students All living cells make and use ATP in their energy releasing and energy using process Most students will have experienced rechargeable batteries used in various devices class or show pictures if you re not sure LIKES WHERE THE ANALOG MATCHES THE CONCEPT A charged battery has the ability to provide energy ATP has the ability to provide energy Batteries move energy to where it s needed ATP is moved to where energy is needed in Student Centred Approaches for Science Education Part 3 Bring one to 38 to power an electronic device the cell A charged battery turns into a flat battery as energy is used ATP converts to ADP as energy is used A rechargeable battery can be used over and over again ATP can be used over and over again The chemical reaction is reversible A battery recharger is the site where energy is reintroduced into the battery Mitochondria are the sites where energy is used to change ADP back into ATP Recharged batteries can be used in many devices ATP can be used at many sites in the cell for example ribosomes cell membrane for different functions UNLIKES WHERE THE ANALOGY BREAKS DOWN A battery s energy is released gradually whereas a single molecule
22. Kingdom of Cambodia Nation Religion King Student Centred Approaches for Science Education Part 3 Chapter 5 Analogies and Models Chapter 6 Educational Games Teacher Training Department 2012 Part 3 Chapter 5 Analogies and Models Chapter 6 Educational Games Published by the Ministry of Education Youth and Sport of the Kingdom of Cambodia Printed in Cambodia 2013 First edition The development and publication of this document has been funded by the General Directorate for Development Cooperation and Humanitarian Aid DGD with technical support from the Flemish Association for Development Cooperation and Technical Assistance VVOB The Flemish and the Belgian governments cannot be held responsible for the content of this publication Copyright Notice Unless otherwise noted in the materials excluded and rights reserved list below material in this publication is licensed under a Creative Commons Attribution NonCommercial ShareAlike 3 0 Unported License This means that you may distribute copy remix and build upon this work non commercially without prior permission of the publisher as long as you credit and license your new creations under identical terms More information on this license is available at http creativecommons org licenses by nc sa 3 0 Material excluded and rights reserved Some material in this publication is not being made available under the terms of this license These are Third Party mater
23. REAKS DOWN Sun is hot whereas nucleus is not Orbits of planets are elliptical whereas orbits of electrons are circular Student Centred Approaches for Science Education Part 3 64 Electrons can change their orbits if they gain or lose energy Planets cannot change their orbits Real electrons occupy clouds of space around the nucleus rather than a strict orbital path Protons and electrons have electrical charges unlike the sun and the planets Some planets have moons whereas electrons are alone in their orbits Electrons are all the same size unlike planets 3 The tunnel analogy for catalysis Link with Curriculum Catalysers This model helps students to understand activated complexes activation barriers and the role of catalysers in chemical reactions Catalysts speed up chemical reactions by providing an alternative pathway with a much lower energy barrier Because the reactants do not require so much energy input to reach an activated complex the reaction happens more rapidly The analogy consists of the idea of a car trying to drive over a steep mountain The steep hill is replaced by a tunnel which is the analog of the catalyst s alternative reaction pathway Adapted from Harrison and Coll 2008 LIKES WHERE THE ANALOG MATCHES THE CONCEPT Height of the hill Height of energy barrier Car Reactants Driving over hill Reactions overcoming
24. TCHES THE CONCEPT Students Particles of matter Students sitting at their desk Matter in solid state fixed positions Students breathing moving while sitting at Vibrating of atoms around fixed position desk Students walking around class during class Movement of particles in liquid state similar activity spacing higher energy Classroom walls Boundaries of vessel containing liquid Students running around school during break Movement of particles in gaseous state more energy Student Centred Approaches for Science Education Part 3 74 School boundaries Walls of vessel containing gas UNLIKES WHERE THE ANALOGY BREAKS DOWN Particles especially in the gaseous state move very rapidly compared to students All particles look the same unlike students Particles in solids and liquids are much more closely packed than students in a class Particles do not move purposely whereas students may do In the gaseous state particles move around independently whereas students may play together in groups 11 The dance party for chemical equilibrium Link to curriculum chemical reactions equilibrium Grade 12 chapter 4 lesson 1 2010 Almost all chemical reactions ultimately reach a state of equilibrium This means that the rate of forward and reverse reactions is the same and that there are no further changes in the concentration of reactants or product
25. ame Game rules Divide the class in teams of maximum 4 students You can choose the amount of groups but it is recommended to have no more than 5 of 6 groups Each group has one dice to roll You may appoint one assistant during the game who helps moving the game pieces The game board hangs in front of the classroom so all the players can view it clearly Each group rolls the dice who throws the highest amount starts the game with the number of eyes played Read the question about the topic that corresponds with the question that the team hit Allow a short amount of time for discussion and giving the answer Only members of the team whose turn itis are allowed to answer You may assign one person per team as the spokesperson A right answer lets the team stay on the number a wrong answer results in the team moving back 2 numbers The first team that reaches the finish wins the game Student Centred Approaches for Science Education Part 3 102 Questions You can use different kinds of questions You can let students make a drawing on the board use true false questions multiple choice questions or short exercises 7 Examples The annex includes examples of questions for a physics game For biology you can play a game where the colours represent the different parts of the human body For earth and environmental science you can play the game to revise what students have learned about astronomy for example Red qu
26. art 3 89 Student moves Action From to Clouds All Collect 1 as airborne contaminants are absorbed Animal Soil Collect 2 for wastes Animal Clouds Remove all as water is purified as it is respired Soil plants Remove 1 as some plants absorb pollutants Soil River Collect 2 as run off collects pollutants Soil Groundwater Remove 1 as soil filters some pollutants Soil Clouds Remove all as water is purified as it evaporates Plants Animals Collect 1 as contaminants are ingested Plants Clouds Remove all as water is purified as it transpires Ocean Clouds Remove all as water is purified as it transpires Lake Clouds Remove all as water is purified as it transpires Lake Groundwater Remove 1 as soil filters some pollutants Lake Animal Collect 1 as pollutants are ingested Lake River Remove 1 as water moves downstream Glacier Groundwater Remove 1 as soil filters some pollutants Glacier River Collect 1 as runoff collects pollutants Glacier Clouds Remove 1 as water is purified as it sublimates Groundwater Lake river Remove 1 as soil filters some pollutants River Groundwater Remove 1 as soil filters some pollutants River Lake ocean Collect 1 as water moves downstream River Clouds Remove all as water is purified as it evaporates River Animal Collect 1 as contaminants are ingested Compare for each station the amount of pollution units before and after the game Discuss h
27. build a house as planned Translation of DNA code into mRNA The same kinds of bricks arranged differently can build lots of different houses The same kinds of amino acids can be arranged to build lots of different proteins Mistakes made by bricklayers Mutations UNLIKES WHERE THE ANALOGY BREAKS DOWN Protein synthesis is sub microscopic whereas houses are not Bricks can be cut up whereas amino acids are always used in their entirety An architect can make changes to a design whereas in protein synthesis no intentional changes can be made 7 The buckets and pumps analogy for the heart Link with curriculum Structure of the Heart Grade 8 chapter 4 lesson 4 2010 Students often find the dual system of pumps in the heart confusing and cannot distinguish between the pathways of the oxygenated and deoxygenated blood An analogy can help them to understand the structure and role of the different parts of the heart This analogy can be used in combination with a model of the heart or the dissection of a pig heart Boor Source Wilkins 1991 Student Centred Approaches for Science Education Part 3 42 LIKES WHERE THE ANALOG MATCHES THE CONCEPT Buckets collect water The right and left atria collect blood as it returns from the body and lungs respectively Pumps actively pump water to places where The right and left ventricles actively pump itis needed blood
28. crystals resulting in convection currents that students can observe as the crystals dissolve The model is not a perfect analogy to plate tectonics However even flawed analogies can act as strong learning activities as long as the flaws are clearly discussed with the students cold water PET polystyrene shapes convecton current basin stand potassium permanganate heat source Source Harrison and Coll 2008 LIKES WHERE THE ANALOG MATCHES THE CONCEPT Purple liquid moving up from the area of Upwelling of magma into the earth s crust heating Candle Radioactive reactions in the earth s core generate heat Spreading chalk powder The movement of the earth s crust in response of the convection currents Purple liquid subsiding at the edges of the Sinking of the magma at the edges of container tectonic plates subduction Polystyrene shapes on top of the chalk Continents floating on the tectonic plates Student Centred Approaches for Science Education Part 3 55 powder UNLIKES WHERE THE ANALOGY BREAKS DOWN Subduction happens at the edges of continents not at a fixed location on the earth s crust Continent continent collisions and resulting mountain formation is not represented in the analogy The speed of the model is much higher than the actual speed of plate tectonics New crust is created at the mid oceanic ridges but the purp
29. d Approaches for Science Education Part 3 31 Water can flow in an incomplete circuit electricity needs a complete circuit to flow Water flow depends on the pump output and pressure electric current is determined by the entire circuit the circuit must be looked at as a whole 7 Voltage is like water pressure analogy Link to curriculum Grade 7 chapter 3 lesson 3 2009 Potential difference or voltage is measured in volts and is a difficult concept for students to visualize It is a measure of the force with which the battery can push electrons around Understanding potential difference is crucial when working with electric circuits The analogy with water pressure can help to understand this concept Students are familiar with water pressure and depth and this relation can easily be demonstrated by the teacher Adapted from Harrison and Coll 2008 LIKES WHERE THE ANALOG MATCHES THE CONCEPT Water bottle Battery or dynamo Hole for water to escape Battery in a circuit so current can flow Deeper the water over the hole Higher the potential difference Deeper hole more water flows Higher potential difference more current flows Flow rate is proportional to depth Current flow is proportional to potential difference UNLIKES WHERE THE ANALOGY BREAKS DOWN Student Centred Approaches for Science Education Part 3 32 Electricity is not a material substance
30. d experience of students They are invisible to the naked eye like atoms and molecules are counterintuitive like atom models or are too fast or slow to Observe like some chemical reactions Analogies therefore possess considerable potential to aid students understanding They are sometimes called the special language of chemistry 1 The sports stadium analogy for the hydrogen atom Link with Curriculum Structure of the atom Grade 10 chapter 1 lesson 2 2008 An atom is mostly space The ratio the nucleus diameter atomic diameter is approx 1 100 000 However students often visualize the atom as a solid sphere and have great difficulty visualizing that atoms are mostly empty space and that the nucleus is so tiny and dense Show a picture of a large sports stadium such as the Olympic Stadium if your students are not familiar with the image Let students think of another analogy for example a tennis ball as the nucleus and the distance home school as the size of the electron cloud LIKES WHERE THE ANALOG MATCHES THE CONCEPT Grain of rice Nucleus of a hydrogen atom one proton Playing area and seats out to the last row of Region where the electron might be found Olympic Stadium Ratio of grain of rice whole stadium Ratio of hydrogen nucleus electron cloud UNLIKES WHERE THE ANALOGY BREAKS DOWN The analog is two dimensional whereas the atom is three dimensional The ratio is slightl
31. dents can use model making equipment paper glue matches colour pencils etc to illustrate the analogy Student Centred Approaches for Science Education Part 3 12 Source Harrison and Coll 2008 5 When to use this technique to strengthen your students understanding of the topic stage 3 to explain a difficult or abstract concept stage 3 6 Examples from curriculum Biology Structure of the cell Grade 7 chapter 3 lesson 1 2009 Grade 11 chapter 1 lesson 2 2009 The organelles of a cell have similar functions to some parts of a city Work with the students in your group to identify parts of a city that have similar functions to the organelles that you have learned about You may use your textbook Write down the organelle the part of the city that your group thinks is similar and the function they have in common CELL FUNCTION ANALOG CITY How the cell is like a city Nucleus The nuclear controls and The city council controls coordinates all the cell s roads buildings shops and structures and functions so makes sure that everyone that all the parts work respects the law together How the cell is NOT like a city Cell wall The cel has a wall that A city doesn t have a wall encloses the cell s content around it Student Centred Approaches for Science Education Part 3 13 Other examples can be found in the annex
32. dents participate in the game but those who answer a question wrong drop out the game The student s still standing after the last question wins the game 2 Objectives To review an instruction unit in an active way To increase understanding about an instruction unit Students learn how to use Last Man Standing in their lessons 3 Link with curriculum This game can be applied with many topics from all sciences 4 When to play the game As a review activity at the end of a lesson or unit of instruction stage 3 stage 4 Student Centred Approaches for Science Education Part 3 83 5 Material needed A list of around 10 multiple choice questions in order of increasing difficulty Voting cards see Concept Tests or Traffic Light Cards See Teaching the Scientific Method for the students A projector to project the questions optional A price for the winner 6 Procedure E ZA r Have all students stand up Read the first question and after a short amount of thinking time let students vote their answer Tell the correct answer Students with the wrong answer have to sit down Continue with the second question repeat the process Remember which questions result in a lot of wrong answers in order to explain in more detail after the quiz The quiz ends after the last question or when only one student is left standing You may create a price or award
33. draw as much current as two separate circuits of 1 globe and 1 battery Students stop and talk and bump against each other as they leave the meeting room Electron flow is regular Student Centred Approaches for Science Education Part 3 33 9 Theanalogy of a bicycle chain for current conservation in a series circuit Link with curriculum Grade 7 chapter 3 lesson 6 2009 The idea that current is used up in an electric circuit is a common belief with many students They think that current is consumed because batteries go flat or flashlights go dim An analogy can be useful to teach students the difference between electric current and electric energy Adapted from Harrison and Coll 2008 LIKES WHERE THE ANALOG MATCHES THE CONCEPT Bicycle chain Electric current in closed circuit Energy going from pedals to back wheel Electrical energy Feet driving the pedals Battery Rotation of rear wheel Light bulb Bicycle chain parts Charge carriers or electrons UNLIKES WHERE THE ANALOGY BREAKS DOWN The analogy only works for simple series circuits Student Centred Approaches for Science Education Part 3 34 10 The candy circle analogy for electric current Link with curriculum Grade 7 chapter 3 lesson 2 2009 Another way to help students differentiate between electrical energy and electric current is a role play A role play engages students at many levels from telling
34. e 25 Formative Assessment Probes Vol 1 NSTA Press Keeley P et al 2007 Uncovering Student Ideas in Science 25 Formative Assessment Probes Vol 2 NSTA Press Keeley P et al 2009 Uncovering Student Ideas in Science 25 Formative Assessment Probes Vol 4 NSTA Press Mazur E 1997 Peer Instruction A User s Manual Prentice Hall McDaniel M A and Donnelly C M 1996 Learning with Analogy and Elaborative Interrogation Naylor S Downing B and Keogh B 2001 An empirical study of argumentation in primary science using Concept Cartoons as the stimulus Third International Conference of the European Science Education Research Association Thessaloniki Greece Naylor S and Keogh B 2000 Concept Cartoons in Science Education Millgate House Publishers Tweed A 2009 Designing Effective Science Instruction NSTA press Arlington Virginia USA Student Centred Approaches for Science Education Part 3 107 Websites Physics http galileo harvard edu Chemistry http www chem wisc edu concept http www chemcollective org find php Earth and environmental science http serc carleton edu resources 1302 html Assessment and Active Learning Strategies for Introductory Geology Courses http serc carleton edu resources 21699 html Using ConcepTests to Assess and Improve Student Conceptual Understanding in Introductory Geoscience Courses http serc carleton edu introgeo inte
35. e table below You may limit the role play to the inner solar system but let students calculate the sizes and distances for all the planets PLANET SCALED PLANET SUGGESTED MODEL DISTANCE FROM THE DIAMETER SUN Sun 30 cm Yellow plastic ball Mercury 1 mm Seed 12m Venus 3 mm Dried pea 23m Earth 3mm Dried pea 32m Mars 2mm Pepper corn 49m Jupiter 30 mm Tennis ball 167m Saturn 26 mm Tennis ball 300m If you have a lot of space around the school Uranus 10 mm Marble Approx 600m Neptune 10 mm Marble Approx 900m Student Centred Approaches for Science Education Part 3 59 LIKES WHERE THE ANALOG MATCHES THE CONCEPT Spheres of different sizes Planets of the solar system Relative distances between spheres Relative distances between planets UNLIKES WHERE THE ANALOGY BREAKS DOWN There is air between the spheres but in reality there is a vacuum between the planets The planets are positioned on a straight line In reality they are positioned on various points of their orbit 8 The Supernova Water analogy for Exploding Stars Link with Curriculum Grade 12 chapter 3 lesson 2 2011 Shockwaves are very powerful They occur when bombs go off or when stars explode as supernovas Students are generally not familiar with shock waves This model can be used to show how a shock wave works and relate it to the process of a supernova explosion Fi
36. ectricity Mitochondria provide chemical energy ATP Construction companies build houses Ribosomes construct proteins Roads cars and trucks provide transportation Endoplasmic reticulum is a transportation System Shops store food clothes and hardware Plastids store substances like starch Garment factories make things for export Golgi bodies produce substances exported to other cells e g hormones Bakeries make bread Chloroplasts make the cell s sugars Post office Golgi bodies Fence around the city council building Nuclear membrane Student Centred Approaches for Science Education Part 3 36 Bricks to build houses proteins Waste disposal facility lysosomes UNLIKES WHERE THE ANALOGY BREAKS DOWN Chloroplasts use sunlight energy but a bakery uses wheat and electricity 2 The super market analogy for a classification system Link with Curriculum Taxonomy Classification of Living Matter Grade 10 chapter 1 lesson 1 2008 Biologists have named 2 million species of plants and animals The total number of species may be 10 times as much Scientists bring order in this huge amount by using a classification system There is the traditional classification system of 5 kingdoms Molecular biology has resulted in an alternative domain system based on ribosomal RNA An analogy is useful to help students understand how a classification system works Show some pictures of a supermarket shelves to in
37. ed Introduce the topic by asking where they think the water they drank today came from 2 Objectives p Students learn about the complex movement of water through the water cycle Students can identify the state of water and changes in state as it moves though the water cycle Students understand the central role of water in our environment 3 Link with curriculum Grade 8 chapter 6 Lesson 14 4 When to use this technique You can play this game during instruction on the water cycle stage 3 or as a review activity Student Centred Approaches for Science Education Part 3 88 5 Material needed Station cards print the cards in annex Laminate them to make them more durable Worksheet make a copy of the worksheet in annex for every student or let them copy the worksheet in their notebooks You may develop your own worksheet 9 dice one per station card A card that explains what each number means for that station See the nitrogen cycle material for an example 6 Procedure B Part I Before the game class discussion Explain the students that they will play the role of tiny water molecules in the water cycle Introduce the game with a few discussion questions Where can water be found on Earth Compare the result of their brainstorming with the 9 stations of the game Select a few places stations and let students write down where they think water can go from there Compare their notes w
38. energy barrier the reaction takes place Tunnel Alternative pathway provided by catalyst Ease of travelling through tunnel Reaction speed tunnel can be reused Reactants can overcome energy barrier Student Centred Approaches for Science Education Part 3 65 again and again UNLIKES WHERE THE ANALOGY BREAKS DOWN There is only one car whereas there are many reactants The car and hill are large but atoms are very small Cars move very slowly compared to atoms 4 Therice grains analogy for Avogadro s number Link with Curriculum Mole Grade 10 chapter 1 lesson 2 2008 Avogadro s number is an important and useful construct used by chemists to deal with large quantities of matter and to perform calculations on chemical reactions Students may be able to recite the value of Avogadro s number but often it lacks them appreciation on how big the number really is or what its meaning is The analogy uses the visualization of rice grains covering a large land area such as China It will help students to imagine the size of the number You can also show a mole of substance of a common material such as water 18 grams of water is 1 mole Some key data to do the exercise are listed below Student Centred Approaches for Science Education Part 3 66 9 63E 12larea china m 6 02E 23 1 50F 05 1 00E 01 height rice grain mm Base 800028 545114 1 84 LIKES WHERE THE ANALOG MATCHES THE
39. estion about planets of solar system Yellow question about Sun Blue question about Earth Grey question about Moon Green question about Universe 8 Important tips IL Evaluate the game with the students after playing it What would they change in order to improve the game Did they find it a good revision activity And did they learn something Organize a short class discussion Student Centred Approaches for Science Education Part 3 103 11 Chemistry Poker 1 Introduction gt This game based on the popular card game helps students to construct chemical formulas 2 Objectives to review and improve understanding of chemical formulas to stimulate collaborative learning to increase students interest in chemical formulas 3 Link with curriculum Grade 8 chapter 2 lesson 2 4 When to use this technique You can play the game in stage 3 of the lesson to deepen students understanding or in stage 4 of the lesson as a review activity sins 5 Material needed uel You need to make As many sets of cards as you have groups in the class Laminate cards to make them more durable One scorecard per group You can also draw the scorecard on the whiteboard and ask each group to copy it Student Centred Approaches for Science Education Part 3 104 Make playing cards with the following information o Atleast one card with the ions listed below 47 cards o O
40. for the winning student During the game take a note of the questions that many students answer wrong After the game you can explain these questions in more detail 7 Examples Example biology the respiratory system Example physics chemistry energy Example earth science the universe Example chemistry the periodic table of elements Student Centred Approaches for Science Education Part 3 84 4 Earth Science Rock Cycle Game earth and environmental science 1 Introduction The rock cycle game is an interactive game that teaches students about the different stages in the rock cycle how rocks travel between stages and about the relation between the rock type and the physical environment In the rock cycle game students play the role of a stone and simulate its journey between places and through geological processes 2 Objectives 5 f To teach students that rocks cycle indefinitely through the Earth system To teach students that the cycle is complex and nonlinear To improve students insight in the relation between rock type and the physical environment To generate student interest in rock types and geological processes 3 Link with curriculum Grade 8 chapter 2 lessons 3 and 4 4 When to use this technique During step 3 of the lesson 5 Material needed Station cards print the cards in annex Laminate them to make them more durable Worksheet make a copy of the workshee
41. h faster than blades Fan can be switched off but electrons cannot be stopped Blades are fixed to the fan centre but electrons are not fixed to the nucleus In most atoms there are multiple electrons at various distances from the nucleus The fan is two dimensional whereas the electron clouds are three dimensional Student Centred Approaches for Science Education Part 3 72 9 The bookshelf analogy for atomic energy levels in the atom Link with Curriculum Atomic energy levels in the atom Grade 10 chapter 1 lesson 2 2008 The concept that electrons can only reside at certain energy levels is difficult to grasp as well as the fact that electrons need or emit a fixed energy amount when moving between energy levels These concepts can be clarified using the analogy of a bookshelf filled with books Let students make a drawing of the analog in which they explain the analogy LIKES WHERE THE ANALOG MATCHES THE CONCEPT Bookshelf energy levels in an atom Shelves Specific energy levels Books Electrons Capacity of shelves Capacity of electrons in energy level Lifting the book to higher shelf requires Raising electron to higher energy level energy from your body requires electromagnetic energy Shifting the book from higher to lower level Electron going from higher to lower energy level UNLIKES WHERE THE ANALOGY BREAKS DOWN An electron going from a higher to a l
42. h the peak pointing towards you Dashed lines are valleys and are to be folded towards you with the peak pointed away from you 2 Making your DNA model e Cut the white border off the top bottom and sides of the template e Colour the 4 nitrogen bases each with a different colour optional or can be done in advance at home e Fold all solid lines going lengthwise down the page into mountain folds e Fold all dashed lines going lengthwise down into valley folds Mountoin folds along solid lines Volley folds along dashed lines 3 Bring the two sides of the model together similar to an I beam see picture above right 4 Look for the words front and back at the top of your model Hold the model with the front side facing you Student Centred Approaches for Science Education Part 3 45 This side should be facing you 5 Fold the two sides of the DNA model so that the front side is flat AE ios Cap Fro 6 Crease each solid horizontal line into a mountain fold away from you EP D 7 Flip the model to the back side Crease each solid diagonal line into a mountain fold away from you Your model should look like the picture below 1 5 WES 8 Fold ALL of the creases together in the directions of the folds made in steps 5 and 6 Your model will fold up like an accordion While you are folding pinch the middle of the model to keep it together to make a cylind
43. he analogies could be used examples Student Centred Approaches for Science Education Part 3 30 6 The Water circuit analogy for a simple series circuit Link with curriculum Grade 7 chapter 3 lesson 6 2009 This analogy addresses the common misconception that current is used up in electric circuits In fact energy can only be changed into another form it s never used up Use a picture or drawing of an aquarium or swimming pool filter system in order to make sure that all students understand the analog An aquarium filter draws water in through a pipe a pump pushes it through another pipe into a filter that resists water flow and then the water exits through another pipe into the aquarium Pipe Filter Source Harrison and Coll 2008 If possible combine the use of this analogy with practical activities Let students make simple series and parallel circuits using a battery wires and a few light bulbs LIKES WHERE THE ANALOG MATCHES THE CONCEPT water Electricity Flowing water Electric current Pipes carrying water Wires carrying electricity Pump pushing water pressure Battery pushing electrons voltage Pump pressure Battery voltage Filter resists water flow Thin wire in light bulb resistance No water lost Current is conserved UNLIKES WHERE THE ANALOGY BREAKS DOWN Water is a liquid electricity is a flow of charge in an electric field Student Centre
44. he greenhouse effect The analogy can be introduced as a group challenge If students know why the interior of a car in the sun heats up they can try to work out why increased concentrations of greenhouse gases result in higher atmospheric temperatures Most radiation from the Radiation entering sun reflects off the metal through the glass is surface trapped heating tho interior Source Ernst 2010 LIKES WHERE THE ANALOG MATCHES THE CONCEPT Heat entering the car through the windows Heat entering the Earth s atmosphere The glass windows and windscreen Layer of gases in the atmosphere Student Centred Approaches for Science Education Part 3 51 Heat cannot escape easily from the car Excess heat is trapped in the atmosphere Air within the car warming up Atmosphere warming up UNLIKES WHERE THE ANALOGY BREAKS DOWN The interior of a car heats up much faster than the Earth s atmosphere However it should also be pointed out to students that in terms of geological time the atmosphere heats up very rapidly In a car the solid exterior acts as the insulator In the atmosphere gases play this role Re radiation and the resulting lengthening of wavelength of the electromagnetic rays is a much more significant factor in the warming up of the atmosphere than in the interior of a car It s easy to cool down the interior of a car by opening the windows or switching on
45. hing and learning method Games can be used in the classroom to stimulate inquiry make students familiar with abstract concepts and expose students to higher level thinking Teaching with games enhances motivation by involving students in the lesson Games in the classroom can serve several objectives a to review a topic b to develop new relationships among concepts and principles creating deeper understanding c to identify gaps or weaknesses in knowledge skills or attitudes Educational games have important advantages They provide opportunities for students to apply what they have learned in a new context They are interactive and increase student interest and motivation Successful educational games have following characteristics 1 Winning should be based only on the demonstration of knowledge and skills Games that are based solely on luck or strategy are not suitable 2 The game should address important concepts or content 3 The rules of the game should fit the age and developmental level of the players 4 Students should not lose points for wrong answers x 5 All players should be able to win from time to time When introducing games in the classroom following tips are worthwhile Make teams of equal strength When preparing the game think about how the game design provides you with feedback on student learning Grievances should be dealt with after the game and outside class so as not to di
46. hing them 1 The Dominoes and Books analogy for Conduction of Heat Link with curriculum Grade 7 chapter 2 lesson 1 2009 Heat transfer by conduction can easily be introduced with practical activities For example hold the end of a wooden stick and a piece of wire in a candle flame You quickly drop the wire but you can hold the wooden stick Another way is to let students feel at the tap their desk and a wooden cupboard Afterwards they measure the temperature of the objects Although objects feel warmer or colder they have the same temperature Conduction of heat relies on particles Students can visualize solids as close particles that jostle each other and transmit heat energy from one particle to another Metals conduct heat quickly while wood and plastic are poor conductors because of the difference in structure Metals are good conductors because they have free electrons Wood and plastic are poor conductors because they don t have free electrons Adapted from Harrison amp Coll 2008 Student Centred Approaches for Science Education Part 3 25 To explain why some materials are good conductors and others not an analogy can be useful LIKES WHERE THE ANALOG MATCHES THE CONCEPT Dominoes standing up that can fall over Free electrons that can move around Books standing up that can fall over Atoms and molecules that can vibrate Dominoes falling over another in a line quickly one after F
47. ials that are being used under fair use or with permission The publisher will not be liable on any legal basis including negligence for any loss or damage suffered through the use of Third Party material Student Centred Approaches for Science Education Part 3 2 Prologue Capacity building and human resource development are one of the crucial angles in the rectangular strategy of the Royal Government of Cambodia Qualitative science education is an important factor in creating a well educated workforce Not only is there a strong need for people with degrees in scientific domains but science education also contributes to developing students into well informed critically and creatively thinking citizens In cooperation with development partners and international organizations the Ministry of Education Youth and Sport MoEYS has developed educational materials to fulfil the need of teaching and learning The process of material development and capacity building consisted of joint efforts of the technical expertise of both the MoEYS and VVOB educational experts This enabled us to design materials that focus on basic scientific knowledge and teaching methodology for science subjects This manual focuses on the theory and practice of science education and the promotion of problem Solving skills reasoning skills reading comprehension creativity and deeper understanding of Science The manual also offers solutions to make science lessons more
48. ime you play the game you only need to change these cards Prepare a list of questions per category on a sheet of paper so you can quickly read the selected question aloud Student Centred Approaches for Science Education Part 3 81 Mutations 6 Procedure E NT d 1 Divide the class in three of four teams and assign a team captain for each team 2 The first team starts by selecting a category 3 Read the question aloud If none of the team members knows the correct answer or if the majority votes for the wrong answer the next group can answer The team that answers correctly gets a point The team captain of this team selects a next topic 4 The first question of a topic is worth 100 points The next question 200 and so on The first question has to be answered correctly before a team can choose the second question 5 The jeopardy ends when all answers have been answered The team with the most points is the winner 7 Examples Jeopardy biology biological cycles ecology population growth Jeopardy earth science Earth s atmosphere Moon planets stars Jeopardy chemistry acids amp bases salts oxygen hydrogen Student Centred Approaches for Science Education Part 3 82 3 Science quizzes Last Man Standing 1 Introduction Last Man Standing from which the successful Who Wants to be a Millionaire is derived is an interactive quiz that you can easily use to review a topic All stu
49. ing similar things Student Centred Approaches for Science Education Part 3 40 are grouped together UNLIKES WHERE THE ANALOGY BREAKS DOWN Monotonous sections along a road can be very productive whereas strands of repetitive DNA do not code for proteins Cities manufacture goods on site whereas genes code for proteins that are manufactured in the ribosomes There about 25 000 working genes in the human genome much more than there are cities between Phnom Penh and Bangkok 6 The Building a House Analogy for Protein Synthesis Link with Curriculum Grade 12 chapter 4 lesson 2 2010 Protein synthesis is a complicated process involving many components and sites of activity lt is difficult for students to get a big picture of the process and at the same time understand the functions of each of the individual components You can also use this analogy to explain the concept of phenotype LIKES WHERE THE ANALOG MATCHES THE CONCEPT Master plan of house DNA Architect s office Nucleus Copying of the master plan for use on Transcription construction site Student Centred Approaches for Science Education Part 3 41 Copy of master plan mRNA Tradesmen bringing bricks and other tRNA materials Bricks Amino acids Mortar to bond bricks together Energy to bond amino acids to form a protein Following the plan to organize bricks and
50. ining Department Officer Teacher Training Department Officer Department of Curriculum Development Officer General Secondary Education Department Vice director Teacher Training Department Technical Advisor Facilitator Science RTTC Student Centred Approaches for Science Education Part 3 Table of contents igife oe tM EET E 3 Prelic o to EMT EE 4 Manual Development Committee sssssssssssssseseses enne enne enne enses n annann annen nnna 5 Management Committee sessssssssssssesseeeeen eene then nennen sn nrns sitet enne denn s intrent tenen nene 5 Approval Commitee ssion anse n o ode eli be ag Fuit e D pe aE Foi pda oves 5 Committee of AUthOIrs ite te lei n Lope e a pei S team Lo Foi Rea Daa aE 5 Editorial Gommntitteg 2 2 i etia te nb ERR E Re ttd XR UL Rote RE eggs 6 Tegne AVISI S aoaaa a et tes tech oo ERE Ln tae aea e RO ETE A R NAR 6 BicaiEuscm e ES 6 Tabe OF contents a eoe aditu ta e Eun ictu ata hoe nitantur eu ta tte capote at 7 Chapter 5 Analogies and Models sss eseeeennneeen nennen entem en nennen sn nnne nennen 9 nu orelireiTe DERE ENORMI E TT 9 hiuc EEUU 10 1 Using the Focus Action Reflection FAR Guide sse 10 2 Syniectics siete reis i nio ut testis n ebur Ee E Ee a a 15 Ja GModelsgzs seu ts Ratten stis ttates bee dat oe ee dot ret iene 17 4 iBole Playssumd dutem ni das ure icti irte 19 5 Student Generated a
51. ith the instructions from the dice code card Assign approx an equal number of students to each station Explain that this station is their starting position Part II Playing the game Students roll the die and perform the action that corresponds with the number They write down in their worksheet where they are going and what happens to them After about 10 turns end the game and put students in groups of 4 Let the members compare their journey Do they find differences Where in their journey do phase changes occur Part Ill Group and class discussion after the game Have students identify the various stages of the water cycle and the states in which water may be found You can let students write an essay about their journey How and why is it different from other students journeys f 7 Variant include the concept of contamination Lm e Ue p With a few extra elements you can teach students about contaminants and how they spread through the water cycle What you need are approx 50 small blocks or units small stones paperclips tooth picks and 9 small containers or boxes The blocks represent amounts of pollution Place a container at every station Put an equal number of units in each container except for Animals and Plants where you put no units Play the game but at every station the players collect or remove units according to the table below Student Centred Approaches for Science Education P
52. k with curriculum Grade 8 chapter 1 lesson 2 4 When to use this technique As a learning and review activity step 3 and step 4 5 Material needed is Create as many bingo cards as there are students The annex contains 30 cards but you can easily make more Student Centred Approaches for Science Education Part 3 95 Prepare a list of elements in the order that you will call them out You can use the list to check whether a student s bingo is correct You need as many lists as you plan to play the game 6 Procedure P o x Wp Give each student a game card see annex This will be their answer key Students place the bingo cards in front of them Then teacher calls out elements students place a coloured marker on the appropriate square The first person to get five in a row vertical horizontal or diagonal is the winner 7 Examples The game is designed for the topic on the periodic system of elements chemistry but you may use the bingo format in other topics as well For example for biology you could develop a bingo game on parts of the human body 8 Important Tips This game can be played by individual students pairs or teams The best option is to play individually as to promote each student s in depth understanding of element and self regulated study of element symbols and names Instead of calling out the elements yourself you can ask a student to call out the elements one by o
53. le liquid doesn t turn into chalk 4 The Mini Sundial Analogy for Day and Night Link with Curriculum Grade 8 chapter 3 lesson 1 2010 Many students fail to explain the origin of day and night in a scientifically correct way Using a model provides a strong visual representation for the students of how the rotation of the earth in combination with the Sun causes day and night Let students illuminate a globe of the earth on one side and then rotating it slowly to model how different places enter day and night The model can then be further developed by adding a mini sun dial like a match to the globe and demonstrating that the length and orientation of shadows is a result of the earth s rotation This seems to change the elevation of the sun during the day You can combine the use of this model with a concept cartoon The model can also be replaced by a role play activity in which students play the role of Earth Sun and Moon and use a low intensity flashlight Source Harrison and Coll 2008 LIKES WHERE THE ANALOG MATCHES THE CONCEPT A stationary light source Sun A matchstick stuck to the globe Sundial Student Centred Approaches for Science Education Part 3 56 UNLIKES WHERE THE ANALOGY BREAKS DOWN The matchstick is much taller relative to the globe than a sundial on Earth Students rotate the globe much faster than the Earth s real rotation rate 5 The Mini Dome A
54. ler than the enzymes they react with The matching between key and lock is based on physical shape whereas the matching between enzyme and substrate is based on chemical bonding patterns Padlocks don t break apart to form different products as some substrate molecules do A key can only lock or unlock a padlock whereas an enzyme speeds up a chemical reaction 5 The geography analogy for the human genome Link with Curriculum Grade 2 chapter 5 lesson 2 2010 Chromosomes are made up of long strands of repetitive DNA which are not part of the direct code for proteins but which are important in the regulation of the genes Genes are part of the chromosomes that contain the code for producing a protein They make up only 5 of the human genome This analogy helps students understanding the relation between chromosomes genes DNA and proteins A map or atlas could be useful to help students imagining the geography analog LIKES WHERE THE ANALOG MATCHES THE CONCEPT 1600 km road journey 3 x from Phnom Penh Length of the human genome to Bangkok Provinces along the journey Chromosomes Monotonous sections of the journey such as Repetitive DNA with regulation functions fields or forests Busy towns Genes Some cities are smaller than others Genes vary in size with some being many DNA letters long and others relatively short Some cities are grouped together Families of genes produc
55. ll a water bottle full with water and keep the lid off the bottle Hold the bottle in your hand about 30 40 cm above a solid object such as a table or the floor and bang it bottom down with a sudden move on the table or floor The water suddenly decelerates creates a shock wave that continues on hits the bottom rebounds and blows much of the water up and out of the bottle Take care use a strong plastic bottle and do the experiment outside Student Centred Approaches for Science Education Part 3 60 Adapted from Harrison and Coll 2008 LIKES WHERE THE ANALOG MATCHES THE CONCEPT Plastic bottle with lid off Star bigger than our sun Water in the bottle Star s gases mostly the outer half Rapid downward motion Star s gases collapsing under intense gravity Shock wave generated when the bottle stops moving Shock wave generated when gases cannot collapse any further Shock wave reflected off the bottle s bottom Shock wave reflected off maximum density layer Water blown out from the top Gases blasted off the star s outer half UNLIKES WHERE THE ANALOGY BREAKS DOWN Water is a cool liquid Stars are made of very hot gases plasma Stars are much bigger than a water bottle Water just sprays out into the air whereas the gases become a nebula and later can form planets Student Centred Approaches for Science Education Part 3 61 9 Role play o
56. lot bursting into flames Be careful for the students safety You can use the model to explain a sustained nuclear fission reaction like in a nuclear reactor each match ignites on average one other match and to explain an exponential nuclear fission reaction like in an atomic bomb each match lights two other matches Student Centred Approaches for Science Education Part 3 Adapted from Harrison amp Coll 2008 LIKES WHERE THE ANALOG MATCHES THE CONCEPT Matches can ignite rapidly U 235 hit by a neutron splits into pieces immediately Matches must be close to ignite each other U 235 atoms must capture a neutron Match ignition spreads exponentially U 235 fission spreads exponentially Energy is released A huge amount of energy is released UNLIKES WHERE THE ANALOGY BREAKS DOWN There are many more U 235 atoms than matches U 235 atoms release 3 neutrons each Matches just affect one other match 3 Theeyeis like a camera analogy Link with curriculum Physics Grade 9 chapter 5 lesson 4 2011 Biology Grade 12 chapter 3 lesson 2 2010 This analogy is often used by science teachers to explain how an eye forms images However the analogy assumes that students know how a camera works and that they understand image formation with convex lenses and pinholes If not its advised to include a practical activity where students make a pinhole camera or experience real
57. m Student Centred Approaches for Science Education Part 3 eo LA The game is easily scalable depending on the available time If you have only 5 minutes left you play two rounds whereas more time available enables to play more rounds Let students make their own taboo cards Give them empty cards like the one below Using pencil and if available colours they make their cards 10 Game of the Goose gt 1 Introduction Game of the Goose is a board game where teams of players try to cross the board as quickly as possible They do this by throwing the dice and answering questions Some of the spots require special actions of the players such as solving a calculating question or moving an opponent s pawn The game takes at least one hour depending on the number of teams and the difficulty level of the questions However it s an excellent revision activity 2 Objectives m Students increase their understanding of science topics Students recognize the use of educational games in science lessons Students can integrate an educational game in their science lessons 3 Link with curriculum The game can be used for all kinds of topics Since it takes up a lot of time it s mostly suitable as a revision activity The game can cover multiple topics such as all the content of the semester or year Student Centred Approaches for Science Education Part 3 100 4 When to use this technique
58. n Tides Link with Curriculum Grade 8 chapter 3 lesson 4 2010 Tides are a complex phenomenon that is difficult to understand for many students A role play can be useful to explain the interplay between Sun and Moon in creating tides on Earth When performing the role play students need to review other elements they have learned about Sun and Moon such as The Moon orbits the Earth every 28 days The Earth orbits around the Sun in one year The time for one orbit is equal to the time for one rotation so we always see the same side of the Moon The Moon is much closer to the Earth than the Sun LIKES WHERE THE ANALOG MATCHES THE CONCEPT 3 persons Sun Earth and Moon Persons rotating and moving around each Moon Sun and Earth orbiting and rotating other Persons holding each other Gravity between objects Earth person stretching arms outward in High tide in that part of the Earth two directions Earth person stretching arms more in two Spring tide in that part of the Earth directions Other directions where arms are not Low tide in that part of the Earth stretched UNLIKES WHERE THE ANALOGY BREAKS DOWN The Moon is 400x closer to the Earth than the Sun The Sun is also approx 400x bigger than the Moon Student Centred Approaches for Science Education Part 3 62 D Effective analogies for chemistry Many chemistry concepts lie outside the worl
59. nalogies sssssssssssssseees ener entree 22 List of effective analogies per science sssssssssseeeeneeeeneneenennnen nennen nnne 25 A Effective analogies for physics ssssssseseeee eene eene nennen nnns 25 B Effective analogies for biology sssssseseeeeneeenenen nennen enne nennen nnns 36 C Effective analogies for earth science sssssssssssssseseeeeeeeeen nennen nennen 51 D Effective analogies for chemistry ssssssssesseeeeneenen nennen nnns 63 Chapter 6 Educational Games sse eene nennen enne trnr en thnn etre nann nannan 77 IMTROGUCTION Ss sic EH EE 77 PCUIVITN OS Sis tot A eL ee ha od Raat ss hol aca hs a Il Bat asta ata ha Sa iat Ma ole Batt ase oh 79 Ty Memory Galieni dei e efte de werd Gadde ais 79 2 Science quizzes science jeopardy cceeeeceeeeeceeeeeeeeeceeeeeeeeeeeeeeeeeaaeeeeaeeseeeeetaeeeeaeeeeeeeee 81 3 Science quizzes Last Man Standing sssssssssssseseeeeee eene nnne nnne 83 4 Earth Science Rock Cycle Game earth and environmental science 85 5 Water Cycle Game Biology and Earth and Environmental Science 88 Ga JEOOp galTies it Etui ntt n Et utut code atu t e fiie 91 s Domino Game S ote tasa uen aw addunt m une 93 8 Chemistry Element Bingo ssssssssssssesseseeee ener nnnrnn in
60. nalogy for the Arc of the Sun Link with Curriculum Grade 7 chapter 2 lesson 1 amp 2 2009 This model helps to explain the relative motions of the Earth and the sun It is intuitive to think that we are stationary while the moon sun and other planets move across the sky This model shows how the Sun describes an arc across the sky from east to west The arc varies with the seasons due to the tilt of the Earth s axis This model requires a small plastic dome that you can put on a globe Source Harrison and Coll 2008 LIKES WHERE THE ANALOG MATCHES THE CONCEPT Light source such as a flashlight Sun Transparent dome place on the globe above a town Our view of the sky from any point of Earth is shaped like a dome and has a circular horizon As the globe rotates from W gt E the dome emerges from the dark side and a bright dot is seen at the base of the dome As the Earth rotates from W gt E we move from the darkened hemisphere into the light We see the Sun rise in the East As the globe rotates further the bright dot appears to move across the dome in an arc The curve of this arc depends on the position of the dome on the globe and the tilt of the globe As the Earth rotates the Sun appears to move in an arc across the sky The shape of this arc depends upon the location of the observer on Earth and on the season Student Centred Approaches for Science Education Part 3
61. ne from the list Student Centred Approaches for Science Education Part 3 96 9 Taboo Game 1 Introduction This game helps students to remember and understand key terms of a lesson They learn to formulate the meaning of a term in their own words Other students listen and try to guess the key term It encourages students critical thinking skills Students are supposed to guess the words at the top of the card without saying any of the words that are below the line because those words are taboo 2 Objectives toreview and improve understanding of key terms to stimulate thinking skills 3 Link with curriculum Taboo game can be applied with many topics in all science subjects 4 When to use this technique In stage 4 of the lesson as a review activity Student Centred Approaches for Science Education Part 3 97 5 Material needed Small index cards Colourful markers crayons and or coloured pencils optional 6 Procedure o NT Divide the class into a few teams and explain the rules Assign one student to watch over the student in front of the class His her task is to check if a student uses one of the taboo words Assign a student to play the first taboo game He or she picks a card with a key term written on it The student will try to get the class to guess the key term as soon as possible If the student says one of the taboo words he she needs to return to
62. neblank or free card o 15 cards five with each of the following subscripts 1 2 3 Ba Na 1 GO ww Pb Zn NO3 No2 SO4 SO37 HSO4 CO3 6 Procedure This game is played as a 5 card draw The dealer will pass out 5 cards to each player from the Be Hco3 PO4 HPO4 NH4 1 OH ClO4 j Sr Cu sc Cu 3 C A Fe 2s pr Hg 1 Fe Rb CrO4 8 S gu o M AsO4 p C2H302 N H2P04 Br E P a shuffled deck placing all remaining cards in a central stack Each player may discard as many as 3 cards in one rotation taking as many cards from the central stack as s he discards Play begins with the player to the right of the dealer Players try to make a chemical formula that uses as many of their cards as possible If they cannot play they must pass It is possible to make two chemical formulas in one play Once a player uses a number of cards to make a formula that player should draw from the central stack as many cards as s he used Play then passes to the player on the right Total the score by the number of cards that a player can use to make a chemical formula It is possible for a player to score as many as 5 points per hand Each player has her his own score sheet or you can assign one player to keep the scores Play continues until no more formulas can be made Student Centred Approaches for Science Education Part 3 105 SAMPLE Sco
63. nen nnn snis en nennen 95 9 Taboo Galme ia teet eee ese de bete dee Ee eee edet ederet 97 10 Game of the Goose ioten aata e eee io e ade o sec aie Geel 100 11 Chemistry POKET aeneae aata e eec t o E e rds uo ee ae bete het 104 Fleferernces ooo ich oou DEC E oet Teu dt arsine one ee a et ee ite ata nee 107 Student Centred Approaches for Science Education Part 3 7 Chapter 5 Analogies and Models Student Centred Approaches for Science Education Part 3 8 Chapter 5 Analogies and Models Introduction An analogy can be described as a linguistic link between one subject and another seemingly unrelated item In education analogies are often used to relate a new concept for the student to one that he she is already familiar with This is particularly relevant in science education because many concepts are outside the students experiences such as genes energy and atoms Apart from their power to explain difficult concepts in a clear way analogies also stimulate higher order thinking skills such as problem solving and lateral thinking out of the box thinking Moreover analogies bring fun and variety into the classroom improving student motivation Analogies have the highest effect on student learning when students are challenged to discuss or even better to create their own analogies Analogies should not be regarded as superficial comparisons between two items but as opportunities to discuss concepts in depth
64. o light bulb student Electrical energy making the light bulb glow Students eating one candy Energy used to make electrons move Light bulb student eating second candy or Light bulb glows converting electrical energy putting it in a box to heat and light UNLIKES WHERE THE ANALOGY BREAKS DOWN Circuit wires rarely consume as much energy as a light bulb but both representatives receive one candy Candies are not really energy although they release a lot of energy but electricity is energy Electricity is represented as moving objects whereas electricity is not a substance B Effective analogies for biology Analogies are a popular way to explain biology concepts like cells DNA and classification 1 Thecity analogy for a cell Link with Curriculum Structure of the Cell Grade 7 chapter 3 lesson 1 2009 Comparing a cell to a city helps students understand that cells have activity sites that perform city functions For this analogy there are many possible analogs You can let students find their own relations between cell organelles and city structures You can also let students develop their own analogy student generated analogies A cell can be compared with a factory with a school with a market LIKES WHERE THE ANALOG MATCHES THE CONCEPT City council governs and controls the city Nucleus controls all the cell s activities A power station provides el
65. of ATP will release all the energy in a single instant A phosphate molecule breaks away from ATP but nothing breaks away from the battery Usually only one or a few batteries are needed for an electronic device whereas there are many ATP molecules in one cell 4 Thelock and key analogy for enzyme action Link with Curriculum Grade 12 chapter 4 lesson 3 2010 Enzymes are very important chemicals that are used to speed up catalysing cellular reactions to rates that allow the cell to function properly They are very specific which means that they can only be used for the particular reaction to which they belong notion of active sites that react only with certain substrates Source Opharat 2003 Student Centred Approaches for Science Education Part 3 It is an abstract concept in particular the LIKES WHERE THE ANALOG MATCHES THE CONCEPT Key Enzyme molecule Lock padlock Substrate molecule Notched part of key has unique shape Active site has unique chemical makeup Keys unlock only specific locks Enzymes react only with specific substrates Key unlocks a padlock Enzyme action breaks apart substrate molecules The key comes out of the lock unchanged The enzyme comes out of the reaction and can be reused unchanged and can be reused UNLIKES WHERE THE ANALOGY BREAKS DOWN Locks are usually bigger than keys whereas substrate molecules are usually smal
66. on For biology you may develop a game on the respiratory system For earth science the solar system is a good topic for a loop game 8 Important tips The game can also be played in small groups The annex contains a set of cards in the correct order Mix the cards and distribute them to the students They have to group questions with their correct answers and create a frame In the meantime you can walk around and quickly see if the puzzle is correct Student Centred Approaches for Science Education Part 3 92 7 Domino games 1 Introduction gt A domino game challenges students to place a set of domino cards in the right order based on questions and answers or corresponding words Played in small groups it generates discussion and forms an active review activity Groups can compete with each other 2 Objectives To review keywords and concepts from an unit of instruction To challenge students to think and discuss about the content To provide feedback to the teacher whether the unit is well understood 3 Linkto curriculum This game can be played with many topics in all science subjects 4 When to use this technique During or at the end of instruction on a topic stage 3 or stage 4 5 Material needed E Domino cards can be made from a white sheet of paper or a piece of thin cardboard Laminated cards can be reused many times You need one set of domino cards per group of students
67. ons of the role play Student Centred Approaches for Science Education Part 3 58 LIKES WHERE THE ANALOG MATCHES THE CONCEPT Students Planets moons Sun Sequence of students from the Sun Sequence of planets from the Sun Relative speeds at which the students orbit Relative orbiting speed of the planets around the Sun the Sun Students use a stick to simulate the orbit axis Planets orbit around their axis much more of the planet slowly UNLIKES WHERE THE ANALOGY BREAKS DOWN Sizes of the planets are very different Students orbit the sun more rapidly than the planets orbit the sun Relative distances of the planets are difficult to reproduce by the students In reality planetary orbits are not circular but elliptical 7 The Scale of the solar system Link with curriculum Grade 7 chapter 1 lesson 4 2009 Two dimensional pictures or models often introduce a wrong understanding of distances in the solar system A role play activity which includes objects on real scale and correct relative distances between the planets will help students to create a correct conceptual understanding of the scale of the solar system They will appreciate the large distances and realize that most of the solar system is empty space Prior to the role play you can organize a group work activity in which students discuss which objects to use and calculate the distances An example is included in th
68. ow pollutants are transported through the water cycle i _ 8 Explanation a In the textbooks the water cycle is often shown as a simple circular diagram This depiction oversimplifies the actual movement of the water The actual path of a water molecule within the cycle can be quite complex and varied The cycle doesn t say anything about how long water molecules stay at a place in the water cycle For example it may take hundreds of years for a water molecule at the bottom of the ocean to resurface and evaporate Water also changes states along its path Water in its liquid form is the most visible but an important part of the water cycle the water is in gas or solid state Fog and clouds give some indication of the water present in the atmosphere 90 of the water supply is in the oceans Ice caps and glaciers take up only 1 796 of the total water supply but they contain 7096 of the total amount of fresh water Student Centred Approaches for Science Education Part 3 90 Living organisms also move water about Water either directly consumed as liquid or extracted from food is carried within bodies Plants are important in the water cycle Roots collect water of which most travels to the leaves and evaporates back into the atmosphere 9 Important Tips Discuss the game afterwards with your students Did they increase their understanding about the water cycle Would they change the game when playing with their students
69. ower level emits energy but shifting a book to a lower shelf also costs energy A bookshelf is much larger than an atom and books are much larger than electrons All shelves usually look the same but not all energy levels have the same shape Electrons are moving rapidly whereas books are stationary Books can come in different sizes whereas all electrons have an identical shape Student Centred Approaches for Science Education Part 3 738 10 The students in school analogy for the kinetic theory Link with Curriculum States of Matter Grade 8 chapter 2 lesson 5 2009 An analogy is useful to focus on some aspects of kinetic theory that are susceptible to misconceptions For example many students think that there is more empty space between liquid matter particles than between solid matter particles Also the low energy of matter in the solid state compared to matter in the gaseous state is not always clear An analogy between energy and student activities is familiar to all students Each state of matter is related to a classroom practice First students are sitting at their desks solid state then students during a practical activity in the classroom liquid state and finally students running around on the schoolyard during a break gaseous state The energy level of each state can be compared to the enthusiasm of the students Adapted from Harrison and Coll 2008 LIKES WHERE THE ANALOG MA
70. partment Mr Eng Kimly Director Department of Curriculum Development Mr Eung Ngor Hok Director General Secondary Education Department Committee of Authors Mr Stefaan Vande Walle SEAL Programme Coordinator RTTC Kandal Ms Veerle Cnudde SEAL Programme Coordinator RTTC Kandal Mr Uon Virak Technical Advisor Facilitator Science amp life skills RTTC Ms Nget Sokhany M amp E Officer Facilitator SEAL Programme Teacher Trainers RTTC Kandal Mr Mam Pha OI Mr Meng Phirun Mr Thak Sophea Mr Be Bra Mr Sok Saroeun Mrs Long Punthiny Ms Hou Chansara Mrs Som Dany Mr Oeur Sokmeng Mrs Srey Chansophea Ms Veng Sreymon Mr Seang Bunthoeun Teachers Hun Sen Sereypheap High school Kandal Province Mrs Kong Sovannra Mr Pang Sienghay Mrs Sun Chanmoly Mrs Pen Raksmey Teachers Anuwat Lower Secondary School Kandal Province Mrs Loch Sotheany Mrs Mam Metboran Mrs Morn Sokha Mr Phan Ny Teachers Hun Sen Takhmao High school Kandal Province Mr Prum Vannara Mrs Tuon Vannak Mrs Phon Socheat Teachers Hun Sen Kampong Kantuot High school Kandal Province Mr Men Nimol Mrs Ek Amara Ms Tim Bunthen Mrs Chea Yeth Student Centred Approaches for Science Education Part 3 Editorial Committee Mr Men Vannary Mr Sok Saroeun Mr Sin Vath Mr Chan Sopheap Mrs Ean Sarin Technical Advisors Mr Chea Phon Translators Mr Keo Mono Officer Teacher Training Department Officer Teacher Tra
71. r arms two of whom are holding books the CO ion and the books are on the shoulder of a 5 student the Cu ion When dissolution occurs the group of four separates from the fifth and retains the books the electrons showing that the CO ion is charged In the second phase the formation of copper sulphate CuSO is simulated Six students are needed five representing the sulphate ion and one representing the copper ion and two books representing electrons In the reaction dilute sulphuric acid H2SO reacts with the copper carbonate to form copper sulphate carbonic dioxide and water Student Centred Approaches for Science Education Part 3 68 Finally for the electrolysis three more students are needed to represent water and two chairs represent the electrodes The copper ion students go to one chair and accept the two books electrons and go and sit on the chair showing that they are attached to one electrode metallic copper The other electrode is made of carbon graphite The water students go to the other chair and give the chair two books Two students then link both arms to represent a double bonded oxygen molecule and wander off gas disappearing from the system The sulphate students walk around freely being spectator ions This kind of role play can also be done for other chemical reactions The teacher can present different chemical reactions and students can then work out their own role play in small groups and do
72. r explaining the analogy you can let students brainstorm to develop their own analogy 6 Examples from curriculum The list of analogies in annex contains many ideas for student generated analogies Student Centred Approaches for Science Education Part 3 23 7 Variation C7 Sometimes students may bring up new analogies spontaneously during class discussion or in response to an analogy used by the teacher Stimulate the student to develop the analogy and let other students comment on it For example the teacher explains the concept of dynamic equilibrium A student asks if you can compare dynamic equilibrium to a pot of food on the fire with a lid on At the same time some water is evaporating and some is condensing The teacher takes the question from the student to analyse how a pot with food on the fire is similar and different to a dynamic equilibrium 8 Important tips The uncritical use of analogies may use to students developing misconceptions The teacher needs to monitor the developed student analogies closely and point out where the analogy breaks down Student Centred Approaches for Science Education Part 3 24 List of effective analogies per science Each of the analogies listed below has been tried and tested Study the analogy thoroughly before using it A Effective analogies for physics The abstract and difficult nature of physics concepts means that analogies and models are often useful in teac
73. r soccer player bad passer Weak acid Good receiver of ball Strong base Poor receiver of ball Weak base Receiving the ball Accepting a proton passing the ball Donating a proton UNLIKES WHERE THE ANALOGY BREAKS DOWN Soccer players are very large whereas acid or base particles are very small A soccer player after passing the ball is not charged whereas an acid after donating a proton is negatively charged Even fast soccer players move much slower than the acid or base particles There are many more acid and base particles than there are soccer players on a field Student Centred Approaches for Science Education Part 3 71 8 The fan analogy for electron clouds Link with Curriculum atomic models electron density Grade 10 chapter 1 lesson 2 2008 Advanced atomic models that use electron density clouds to describe the orbit of electrons around the nucleus are difficult concepts for students The notion that electrons seem to be at different places at the same time is a counterintuitive concept The concept can be clarified using an analogy of a fan LIKES WHERE THE ANALOG MATCHES THE CONCEPT Centre of fan Nucleus Fan blades Electrons Fan rotation Electrons orbiting the nucleus Fan blurring Electron cloud Tip of fan Outermost part of electron cloud UNLIKES WHERE THE ANALOGY BREAKS DOWN Electrons move faster than blades can rotate Electrons are muc
74. r to make the analogy relevant and useful for as many students as possible It presents teachers with a guideline to successfully apply analogies in class The technique comprises teacher and student activities before and during the lesson and reflection after the lesson 2 Objectives Tomaximize the benefits and minimize the problems when using analogies in class To increase students understanding of difficult and abstract concepts To capture students interest and involve them in challenging concepts 3 How to use this technique The FAR guide consists of three questions for the teacher before the lesson Two questions for the students during the lesson and finally two questions for the teacher after the lesson The table below summarizes the main steps in the FAR guide Student Centred Approaches for Science Education Part 3 10 1 Focus part of the preparation of the lesson Concept What difficult concept do you want to teach the students Students What prior knowledge do students already have about the concept Analog Is the analog something students are familiar with 2 Action part of lesson activities Likes What are the similarities between the analog and the concept Unlikes What are the differences between the analog and the concept 3 Reflection to do at the end or after the lesson Conclusion Was the analogy clear and effective or rather confusing
75. ractive ctestexm html Concept Tests for many earth science topics Student Centred Approaches for Science Education Part 3 108 V O D LC M be education for development With the support of Ao the government of Flanders S
76. re Card TOTAL ECE Example of a score card 7 Examples The game is designed to help students use chemical formulas It is not directly applicable for other topics 8 Important Tips e You may change the ions on the playing cards according with the chemical formulas you want students to learn After playing the game you may discuss the game with your students Let them think about how to improve the game Student Centred Approaches for Science Education Part 3 106 References Books Angelo T A amp Cross K P 1993 Classroom Assessment Techniques Jossey Bass Wiley amp Sons San Francisco California USA Churchill E R et al 1997 365 Simple Science Experiments with Everyday Materials Black Dog amp Leventhal Publishers New York Driver R et al 1994 Making Sense of Secondary Science Research into Children s Ideas Routledge Harrison A G and Coll R K 2007 Using analogies in middle and secondary science classrooms The FAR Guide Sage Harrison A G and Treagust D F 1993 Teaching with Analogies A Case Study in Grade 10 Optics Journal Of Research In Science Teaching Vol 30 No 10 pp 1291 1307 Herr N 2008 The Sourcebook for Teaching Science Jossey Bass Wiley amp Sons San Francisco California USA Keeley P 2008 Science Formative Assessment NSTA Press Corwin Press Thousand Oaks California USA Keeley P et al 2005 Uncovering Student Ideas in Scienc
77. re and function Student Centred Approaches for Science Education Part 3 49 10 The analogy of Homeostasis Being like a Student Walking up the down Escalator Link with Curriculum Homeostasis Grade 11 chapter 6 lesson 2 2009 Homeostasis is a key biology concept that explains how many animals and plants maintain a constant internal environment by regulating input and output of heat water CO nutrients and minerals However many students misunderstand homeostasis as organisms sealing off their interior to the environment Seeing homeostasis as a dynamic process helps them understand how organisms respond to changing conditions in their environment Homeostasis can be compared with a student walking up and down an escalator However make sure that students are familiar with escalators before using this analogy The analogy can be used to explain the dynamic balance of heat production and heat loss Afterwards students can work in groups on an explanation Overheating Student walking up js like metabolic heat production Constant level is like constant body temperature 37 C Temperature Escalator moving down is like heat loss from skin and lungs Source Harrison and Coll 2008 LIKES WHERE THE ANALOG MATCHES THE CONCEPT The escalator is constantly descending Heat is constantly lost through lungs and skin Student is walking upward Human body generates heat by exercise A student walks up
78. reat variety of living things in a short time period Student Centred Approaches for Science Education Part 3 53 UNLIKES WHERE THE ANALOGY BREAKS DOWN Markers give the impression of clear start and end dates However boundaries between geological periods are approximate and geographical changes are often very gradual Life forms don t appear or disappear at certain times but are the result of continuous evolution Some practical tips Make groups responsible for indicating certain events Tell each group to divide tasks one student counts another writes another makes a drawing etc Examples of key events First atmosphere First unicellular organisms First multicellular organisms Origin of Himalaya Last Pangaea situation First mammals Appearance and Extinction dinosaurs Appearance Homo Erectus Homo Sapiens etc Student Centred Approaches for Science Education Part 3 54 3 Convection currents and movement of tectonic plates Link with Curriculum Grade 9 chapter 2 lesson 1 2011 Grade 11 chapter 1 lesson 4 2011 Students are often unaware of the mechanism that drives plate tectonics The model shows how convection currents in the earth s mantle cause the crust to move apart The model consists of a transparent tank with water with potassium permanganate crystals at the bottom and chalk powder on the surface of the water Place a candle directly below the
79. reating a scheme of the rock cycle on which they indicate how their journey fitted into the rock cycle scheme For each station they also write down what type of rock they are Students could even be given a particular starting type of rock such as clay sandstone or limestone With arrows they indicate their journey through the rock cycle This can be done in small groups as students can help each other Part IV Class Discussion The teacher discusses the activity with following questions Did you go through the whole rock cycle or only part of it As what type of rock did you spend the most stages Do you think your journey also occurs in reality How much time do you think the complete journey would take in reality 7 Variation Usually the activity is done individually but you can let students play in pairs as well Then one student throws the dice and the other records the results 8 Important Tips Students should be familiar with the rock cycle before the activity If necessary organize a short lecture before the game Student Centred Approaches for Science Education Part 3 87 5 Water Cycle Game Biology and Earth and Environmental Science 1 Introduction S Water is constantly in motion Sometimes quickly as in a fast moving river and sometimes slowly like in underground aquifers Understanding the water cycle is important for understanding ecosystems and how contaminants and pesticides are transport
80. red Approaches for Science Education Part 3 28 4 The Pair of wheels analogy for light refraction Link with curriculum Grade 9 chapter 5 lessons 2 amp 3 2011 Refraction can easily be demonstrated with the bending of light as it passes from air to water or from air to glass The phenomenon itself however is more difficult to explain Some students may confuse refraction with reflection of light Use a set of wheels and two surfaces of different smoothness Let students experience the change in direction that happens when the wheels cross from one surface to the other Let them find out that the change in direction happens because the wheel on the hard surface rolls easily while the one on the soft surface slows down The wheels could be coated with paint to visualize the change in direction Afterwards let them investigate what happens when you roll in the opposite direction Let them think through the reverse process using the analogy AIR GLASS AIR IS LIKE Source Harrison and Coll 2008 LIKES WHERE THE ANALOG MATCHES THE CONCEPT Wheel tracks Rays of light Perpendicular path shows no deviation Vertical ray doesn t change direction Oblique path bends towards the vertical Oblique ray bends toward the normal Tracks change direction as one wheel slows Ray bends because it slows Wheels slow because the carpet increases Light slows because the glass is optically friction denser than the air
81. ree electrons speeding up when heat is absorbed and moving around bumping others Books falling over slowly one after another in a line Atoms vibrating faster when heat is absorbed and jostling atoms next to them Fast falling dominoes compared to slow falling books Good heat conductors compared to poor ones Slow falling books Non conductors having only vibrating atoms or molecules UNLIKES WHERE THE ANALOGY BREAKS DOWN There are many more electrons and atoms than there are dominoes and books Dominoes and books fall once one way and in a straight line Atoms and molecules vibrate continuously in all directions all the time The difference in size between electrons and atoms is much greater than the difference in size between dominoes and books 2 The Matches Analogy for Nuclear Fission Link with curriculum Grade 12 chapter 4 lesson 3 2011 Nuclear fission and chain reactions are non observable concepts Students are often surprised how fast an atomic reaction can spread The reaction s speed and extent can explain the enormous amount of energy that is released You can use this analogy to explain how nuclear reactors and atomic bombs work The speed with which matches ignite is like an exponential chain reaction To demonstrate the analogy stick 100 matches in a block of clay Keep the match heads approx 5 mm apart Ignite the match on the corner and watch the whole
82. rical shape Student Centred Approaches for Science Education Part 3 46 1 Fold 2 Fold e Continue to fold pinching these folds together in the middle as you go a Q When you are finished with folding your model should look like the picture above 9 Release the model You should be able to see the shape of a double helix below left Straighten out the sides of the DNA model the DNA backbone to make them perpendicular to the creases in the middle as in step 2 see below right The DNA backbone Student Centred Approaches for Science Education Part 3 47 n VN AA i X AN Adapted from Yen T 1995 Make your own DNA Trends in Biochemical Sciences 20 94 48 Student Centred Approaches for Science Education Part 3 9 An Earth analogy for Cell Components Link with Curriculum structure of the cell Grade 7 chapter 3 lesson 1 2009 An analogy can help to give students an idea of the relative sizes of the cell components The analogy compares a cell to the Earth Students work together to extend the analogy to other cellular components mitochondria ER LIKES WHERE THE ANALOG MATCHES THE CONCEPT Earth Cell A continent Cell nucleus A country e g Cambodia Chromosome A city DNA fragment on chromosome A street address Codon 3 base pairs UNLIKES WHERE THE ANALOGY BREAKS DOWN Only relative sizes are compared and not structu
83. s However many students find it difficult to visualize the dynamic nature of equilibrium They assume that reactions stop when equilibrium is reached The analog is a dance party for example at a marriage There is a maximum number of people that can dance simultaneously on the dance floor but people are entering and leaving the dance floor continuously LIKES WHERE THE ANALOG MATCHES THE CONCEPT Dancing people in the hall Moving and colliding particles People starting to dance Formation of a chemical bond and products Number of people in the hall Effect of concentration on reaction rate Changing size of the hall Effect of concentration on reaction rate Speed of dancing people Temperature effect on reaction rate Couples starting and stopping to dance Simultaneous forward and reverse reactions Dance hall doors closed Reaction system closed UNLIKES WHERE THE ANALOGY BREAKS DOWN There are much more particles involved in chemical reactions than there are dancers The particles move much faster than the dancers Particles are much smaller than the dancers There are big gaps between gaseous particles compared with the space between dancers Student Centred Approaches for Science Education Part 3 75 Chapter 6 Educational Games Student Centred Approaches for Science Education Part 3 76 Chapter 6 Educational Games Introduction Educational games are a powerful teac
84. s mass and mass mole mole mass calculations Let students develop their own analogies and have them write down their stoichiometry problems using their analogy LIKES WHERE THE ANALOG MATCHES THE CONCEPT Symbols H and B for ham and bread and Symbols for reactants and products in a HB2 for sandwich chemical reaction Sandwich equation H 2B gt HB2 Chemical equation Ham and bread make a sandwich in a ratio of H2 and O2 react in a ratio of 2 1 1 2 Slices moles Mass per slice of bread or ham Molar mass of compounds Slice slice calculations Mole mole calculations UNLIKES WHERE THE ANALOGY BREAKS DOWN Ham and bread don t react Making a sandwich is easily reversible whereas chemical reactions are not always reversible In a chemical equation often molecules consisting of more than one atom are involved Student Centred Approaches for Science Education Part 3 70 7 The soccer analogy for weak and strong acids and bases Link with Curriculum Properties of acids and bases Grade 12 chapter 3 lesson 1 2010 Strong acids are often confused with concentrated acids and the link with ionization rate is not always made Depending on the class you may use another ball game such as volleyball Source Globalteer org LIKES WHERE THE ANALOG MATCHES THE CONCEPT Soccer ball Proton Good soccer player accurate passer Strong acid Poo
85. scussing the concept with their peers After the group activity collect the similarities and dissimilarities from the students Correct if necessary synthesize the analogy and ask review questions You may ask students whether they think the analogy is useful Maybe they can come up with a better analogy Student Centred Approaches for Science Education Part 3 11 1 Divide the class in small groups of 3 to 5 students 2 Students discuss how the analogy works and where it breaks using a table as the one below You can draw the table structure on the whiteboard Provide enough time for this activity 3 Make one student per group responsible for completing the table during the discussion Let students present their findings and organize a class discussion Use students ideas when synthesizing the analogy Write the main similarities and dissimilarities on the whiteboard using the table structure Tip Students will feel more motivated when they feel that their ideas and views have been incorporated into the analogy construction Concept Analog Likes Unlikes Table for group discussion on analogy during lesson After the lesson analyse whether using the analogy was useful for enhancing the students understanding Do you need to make some adjustments Maybe another analogy could prove more useful 4 Material You can use pictures or drawings to explain better the analogy to the students Stu
86. sion process 2 Explain the general idea but don t go into much detail 3 Student groups work together to distribute roles and develop a scenario They take notes of their scenario 4 Groups of students present their role play to the others Student Centred Approaches for Science Education Part 3 19 5 The teacher organizes a class discussion Students discuss correct and incorrect elements during the play and how they can be improved Sometimes extra elements can be added to the play to strengthen the relation between the concept and the analog This last step is important to avoid that students still have misconceptions or gaps in their understanding Questions that can be used during the class discussion are This depends on the role play Often paper and pen is sufficient What are the likes and dislikes of this analogy Where does the analogy break down Stimulate students to expand the analogy This means that they try to fit more elements of the concept into the analog For example students develop a role play on the greenhouse effect You can ask them how they could integrate global warming in the role play Material When to use this technique as a consolidation activity to strengthen students understanding of the topic stage 3 as a review activity at the end of a series of lessons stage 4 Examples Examples of analogies that are suitable for a role play activity are listed in the annex Some examples
87. stract from the lesson Evaluate the game after the lesson Did you reach the game s objectives Were students engaged Think about how you can improve the game design You can let students give or write down their comments and suggestions on the game Student Centred Approaches for Science Education Part 3 77 There is a wide range of games Some games are adapted versions from popular TV games while others have their origin in traditional culture Some types of games are Board games Card games Quizzes Role plays Puzzles In this manual we present some examples of different types of games for science lessons Each example illustrates a game type that can also be applied in other topics A very powerful learning activity is to let students design their own game as a project for example for a science fair This requires them not only to understand the topic in depth but also to think about how to transfer the knowledge to others and work together in a team Role plays are discussed in the module Analogies amp Models Student Centred Approaches for Science Education Part 3 78 Activities 1 Memory Game 1 Introduction i k Memory is an easy to construct game that is ideal for letting students practice their knowledge of scientific vocabulary formulas units or concepts It is best played in small groups The game consists of a set of cards where two cards are identical or related to each other
88. t in annex for every student or let them copy the worksheet in their notebooks Dice Cut out the dice for the stations and fold them into dice You may also stick them on wooden cubes Student Centred Approaches for Science Education Part 3 85 An alternative for dice is to use ordinary dice and provide dice codes on a sheet of paper for each station that explain what each number means See the nitrogen cycle game material for an example 6 Procedure ey Nn d Part I Preparing the game Set up your classroom with 7 areas or stations These represent places where a change in the rock cycle occurs Place a station card and two dice at each area Divide the students over the stations Part II Playing the game Each student starts at one area in the rock cycle Every student takes turns to throw the die at the station card to determine the geological process that occurs to them Depending on the outcome they go to another station or stay at the same station A student may remain at the same station for several turns For every throw of the die they record what happens on their worksheet During the activity the teacher walks around to guide students in their journey through the rock cycle Student Centred Approaches for Science Education Part 3 86 Part IIl Making the rock cycle scheme When they have completed all lines in their worksheet their journey is finished Afterwards students process their journey by c
89. t the techniques discarded some and changed others and provided suitable examples from the local curriculum This manual consists of 6 chapters Chapter 1 Developing Active Reading and Writing Skills presents techniques to stimulate strategic reading and writing skills with students in science lessons Chapter 2 Developing Science Reasoning Skills presents discussion and argumentation techniques for science topics Chapter 3 Teaching the Scientific Method introduces ways to make students familiar with the various stages in the scientific method Chapter 4 Conceptual Science Teaching focuses on techniques to stimulate conceptual thinking with students Chapter 5 Models and Analogies introduces techniques and examples of models and analogies in Science lessons Chapter 6 Educational Games explains how to integrate educational games in science lessons and gives a range of examples We encourage teacher trainers to try out the methods in this manual We are looking forward to receiving your comments We wish you an inspiring experience and many satisfying science lessons Editorial Committee July 2011 Student Centred Approaches for Science Education Part 3 4 Manual Development Committee Management Committee H E Im Sethy Minister Ministry of Education Youth and Sport H E Nath Bunroeun Secretary of state Ministry of Education Youth and Sport Approval Committee Mr Leang Seng Hak Director Teacher Training De
90. that are not in the annex are Biology Function and structure of a cell membrane Student Centred Approaches for Science Education Part 3 20 Cell division mitosis and meiosis Digestive system Chemistry Chemical reactions involved in electrolysis Radioactivity and half life time Earth and environmental science Solar and lunar eclipse Tides Greenhouse effect Why is Venus so much hotter than the Earth The function of the ozone layer The hole in the ozone layer Physics Nuclear fission and nuclear fusion Electric circuits Student Centred Approaches for Science Education Part 3 5 Student Generated analogies 1 Introduction gt Students sometimes spontaneously generate analogies that are close to their daily life Letting students develop their own analogies provokes rich scientific discussion during the generation process and creates student enthusiasm Also student generated analogies are much more likely to be relevant and accessible to all of your students since it comes from themselves On the other hand unlike teacher generated analogies they are more difficult for the teacher He cannot think through the analogy before the lesson but has to react immediately This requires a thorough understanding of the science concepts involved The distinction between teacher generated and student generated analogies is not always so clear An analogy can be initiated by the teacher but developed by
91. the seat and another student takes his her place For each word that is guessed correctly you can give 1 point to the team that guessed the world Game rules No form or part of any word printed on the card may be given as a clue No gestures can be made Descriptions like sounds like or rhymes with are not allowed No initials or abbreviations can be given if the words they represent are included on the card 7 Examples Biology Inheritance Explain the term Without using the words Genes Nucleus Chromosomes Chromosomes Cell Nucleus Genes Selective breeding Choosing characteristics Cloning Identical Asexual Parent Student Centred Approaches for Science Education Part 3 98 Biology Structure of the Cell Explain the term Without using the words Cell wall e Plants e Structure e shape Cell membrane e Plants e Animal e control Cell nucleus e Control e Chromosomes e DNA Earth and environmental science Telescope e Stars e Observatory e Astronomer e Planet Physics Convection e Heat e Rise e Cold e Dense e Sink Stars Observatory E Astronomer Planet 8 Important tips You can also play the game in small groups For groups of 2 4 students they can take turns giving clues The person with the correct answer keeps the card Then the next player tries to describe the ter
92. them the scenario through to allowing them to discuss circuit concepts and design the analogy Put desks on the side or go outside Mark a large circle on the floor using coloured rope Place one student on one side of the circle and another student on the other side Let the other students position themselves in a circle ready to move One student holds the battery card and one person holds the light bulb card The circle moves in a direction determined by the students When a student passes the light bulb student he she receives two candies They eat one and the other they give to the battery student when they pass him her Two revolutions are enough for the students to understand the idea Organize a discussion in small groups or with whole class after the role play using questions such as What do the two students outside the circle represent What do the two candies represent What do the students represent Why did we draw a circle Can the role play continue forever How can we improve the role play Source Harrison and Coll 2008 LIKES WHERE THE ANALOG MATCHES THE CONCEPT Students in a circle Electrons in a wire Students moving Electrons moving around a simple circuit Candies Energy Student Centred Approaches for Science Education Part 3 35 Student outside circle receiving candies Light bulb Student outside circle giving out candies Battery Giving the candy t
93. troduce the analogy LIKES WHERE THE ANALOG MATCHES THE CONCEPT Products in a supermarket are organized into regions to help customers and staff find items Classification brings order to the study and identification of organisms A supermarket has many levels fruit A classification system is hierarchical from vegetables preserved foods non food large groups with high diversity to small items groups with little diversity Each product has its own characteristics for Each species has specific characteristics that Student Centred Approaches for Science Education Part 3 37 finding or placing it in the shop place it in levels of increasing specificity Some products are difficult to put into specific places Some organisms don t fit easily into groups For example some organisms can photosynthesize like a plant and ingest food like an animal Different shops arrange their products in different ways but they always use a system Scientists use different classification systems but they always use a system UNLIKES WHERE THE ANALOGY BREAKS DOWN There are more living species than there are items in the biggest supermarket Classification systems include all known species but shops don t sell every available item Scientists use other criteria for classification than shop owners 3 Therechargeable battery analogy for ATP Link with
94. ur students understanding of the topic stage 3 You can use a model to explain a difficult or abstract concept stage 3 You can use it as a review activity at the end of a series of lessons or at the end of the semester stage 4 6 Examples from curriculum Examples for all sciences can be found in the annex and the activity guides for each subject Student Centred Approaches for Science Education Part 3 18 4 Role Plays 1 Introduction Role plays are special analogies that can help students to imagine and understand difficult concepts The more students are involved in the elaboration and acting out of analogies the more likely they are to accept the ideas you have in mind Also the fun character of role plays enhances their memorability 2 Objectives A Students learn to examine abstractly what they know about a concept Students learn to link prior knowledge with new concepts in a creative way Students learn to work together Students involvement and motivation are increased 3 How to use this technique e RS US The sequence of steps in this technique varies from topic to topic The list of analogies at the end of this manual contains many ideas for role plays In general you can follow these steps 1 Divide the students in groups depending on the scenario Sometimes every group will prepare the same role play sometimes every group will play a different part for example in a cell divi
95. uts the cards back at the same position Students try to collect as many cards as possible 7 Examples Chemistry organic chemistry structural formulas This memory game helps students to learn about structural formulas and their names A set of cards is included in annex For earth and environmental science you can make a memory game with pictures of the planets and their games For biology the different organelles of the cell are a good topic For physics you can make a set with terms and their units voltage current resistance Student Centred Approaches for Science Education Part 3 80 8 Variation d A You can let students develop their own memory game Next groups exchange their set of cards and play the game 2 Science quizzes science jeopardy 1 Introduction Jeopardy provides an active way to revise a chapter or unit before a test or an exam In jeopardy students play in teams to answer gradually more difficult questions on a series of topics 2 Objectives Toreview a chapter in an active way To assess students understanding of the topic To stimulate team work 3 Link with curriculum This game can be applied with many topics from all sciences 4 When to play the game 5 Material needed Prepare the jeopardy board on a flipchart with colours as in the figure below You can make a reusable game template on which you stick cards with the names of the topics Next t
96. ward as fast as escalator Heat loss and heat production are balanced goes downward so the body temperature remains constant The escalator descends faster Heat loss is higher than heat production the person gets cold The student walks up faster Heat generation is faster than heat loss the person gets hot UNLIKES WHERE THE ANALOGY BREAKS DOWN Student Centred Approaches for Science Education Part 3 50 The escalator moves at a constant rate but the heat loss rate depends on the environmental temperature Heat loss and production can only be balanced at 37 C This would correspond to one position on the escalator C Effective analogies for earth science The vast scale of events in the Earth and space requires models and analogies to bring events down to a size that students can see and understand 1 The heating of a car analogy for the greenhouse effect Link with Curriculum Greenhouse effect Grade 12 chapter 4 lesson 4 The increasing concentration of certain gases in the atmosphere is helping to trap heat and this is gradually raising the Earth s temperature The greenhouse effect is often confused with the hole in the ozone layer You can link this analogy with practical activities Let students determine the greenhouse effect using bottles and thermometers see experiment guide You can use science reasoning techniques to discuss the political and sociological implications of t
97. y different for larger atoms but the concept is identical The atom is filled with empty space whereas the stadium is filled with air another common misconception Student Centred Approaches for Science Education Part 3 63 2 The Solar System Analogy for Atomic Structure Link with Curriculum Grade 8 chapter 3 lesson 4 2010 Students have difficulty visualizing tiny microscopic particles like electrons and protons They are familiar with planets and the solar system as a result of having seen pictures and videos about it Our solar system provides a simple analogy to understand the Bohr atomic model Illustrate the model with pictures from the solar system or by using a model This will make the model more impressive and it will more likely be remembered Planets Dwarf Planets Image courtesy http danieldendy blogspot com LIKES WHERE THE ANALOG MATCHES THE CONCEPT Sun Nucleus Planets Electrons Orbits of planets around the sun Orbits of electrons around nucleus Rotation of planets Spin of electrons Spherical shape of sun and planets Spherical shape of nucleus and electrons Planets at fixed distances from sun Electrons at fixed distances from nucleus Sun composed of hydrogen and helium Nucleus consists of two elementary particles Gravitational attraction in solar system Electrical attraction between electrons and nucleus UNLIKES WHERE THE ANALOGY B
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