SEEMPE 2015

2nd South-Eastern European

Meeting on Physics Education

2015





Book of abstracts


2nd - 3th February, 2015,

Ljubljana, Faculty of Education





Book of abstracts


SEEMPE 2015, 2nd Sout-Eastern European Meeting on Physics Education

Faculty of Education, University of Ljubljana

Ljubljana, February 2015



Editor: Saša Ziherl

Publisher: Faculty of Education, University of Ljubljana

For the publisher: Janez Krek, Dean



Local organizing committee:

Chair: Mojca Čepič

Co-chair: Katarina Susman

Scientific secretary: Saša Ziherl

Maja Pečar

Jerneja Pavlin

Bojan Golli

Ana G. Blagotinšek



International advisory board:

Zalkida Hadzibegović (Bosnia and Herzegovina)

Stevan Jokić (Serbia)

Leopold Mathelitsch (Austria)

Maja Planinić (Croatia)

Gorazd Planinšič (Slovenia)

Robert Repnik (Slovenia)

Dagmara Sokolowska (Poland)

Oliver Zajkov (Macedonia)



Online at: http://www2.pef.uni-lj.si/SEEMPE/index_datoteke/SEEMPE_book_of_abstracts.pdf

CIP - Kataložni zapis o publikaciji

Narodna in univerzitetna knjižnica, Ljubljana



37.091.3:53(082)(0.034.2)



SOUTH-Eastern European Meeting on Physics Education (2 ; 2015 ; Ljubljana)

Book of abstracts [Elektronski vir] / 2nd South-Eastern European Meeting on Physics Education 2015 -

SEEMPE 2015, 2nd-3rd February, 2015, Ljubljana ; [editor Saša Ziherl]. - El. knjiga. - Ljubljana : Faculty of Edu-

cation, 2015



Način dostopa (URL): http://www2.pef.uni-lj.si/SEEMPE/index_datoteke/SEEMPE_book_of_abstracts.pdf



ISBN 978-961-253-168-3 (pdf)

1. Ziherl, Saša

277912320

©2015 Faculty of Education, University of Ljubljana





Book of abstracts





CONTENT



Page

Program

8



Invited speakers

10

1. What is Content Knowledge for Teaching Physics and How Can We Assess it?

11

Eugenia Etkina, Lane Seely, Stamatis Vokos

2. Use your head – in football and physics education

12

Angela Fősel

3. A Design-Based-Research Project on Teaching Colours in Introductory Optics in Year 8

13

Claudia Haagen-Schützenhöfer

4. University students' difficulties with atomic emission spectra

14

Lana Ivanjek, Peter Shaffer, Lillian McDermott, Maja Planinić

5. Developing formal thinking in learning progression research approaches and modern physics propo-

sals

15

Marisa Michelini

6. Assessment opportunities in inquiry-based learning

16

Dagmara Sokolowska, Odilla Finlayson, Deirdre McCabe, Pawel Bernard

7. Comparison of the efficiency of three teaching methods in physics using the cognitive load

17

Maja Stojanović, Branka Radulović

8. Labyrinthine-like wrinkled surfaces in liquid crystalline free standing films

18

Nataša Vaupotič

Oral contributions

19

1. Escaping Bear and Snail: How Ready is Engineering Students For Puzzle-Based Learning?

Bayram Akarsu

20

2. Influence of two different methods for solving free-body diagrams on students' ability to identify

forces and apply Newton's laws

21

Ivica Aviani, Nataša Erceg, V. Mešić

3. Problem solving approach to geometric optics – applying theory to practice through primary school

students' hands-on experience

22

Jaka Banko

4. Introduction of Current Scientific Results into Education: Metastudy and Towards a Theoretical Fra-

mework

23

Mojca Čepič

5. Probing students' conceptual knowledge of satellite motion by use of diagram

24

Nataša Erceg, Ivica Aviani, V. Mešić, Z. Kaliman, D. Kotnik-Karuza

6. The Klein-Gordon string - a versatile system I've never heard of before

25

Sergej Faletič

7. The added value of the interactive whiteboard

26

Bor Gregorčič

8. Engineering freshmen understanding of atmospheric pressure: The 5E learning model effects

27

Zalkida Hadžibegović

9. Student difficulties with electromagnetic induction and analysis of a research instrument

28

Katarina Jeličić, Maja Planinić, Gorazd Planinšič

10. The inquiry skills required for everyday phenomenon investigation

29

Marián Kireš

4



11. Is the equivalence principle to be included in physics instruction for non-physicists?

30

Tomaž Kranjc

12. Building stronger student knowledge – the case of graphs

31

Maja Planinić, Ana Sušac, Lana Ivanjek, Željka Milin-Šipuš

13. Framework for using modern devices in an introductory physics course

32

Gorazd Planinšič, Eugenia Etkina

14. Results of a delayed transfer test of students’ understanding of buoyant force and related pheno-

mena stemming from two different learning experiences

33

Jelena Radovanović, Josip Sliško, Ivana Stepanović Ilić

15. Analysis of children’s sketches

34

Nada Razpet

16. Exploration of students’ ideas on superconductivity

35

Alberto Stefanel, Marisa Michelini

17. Student understanding of physical measurement

36

Ana Susac, Petra Martinjak, Maja Planinic, Andreja Bubic, Marijan Palmovic

18. University Students on Incompatibility of Observables in Quantum Mechanics

37

Giacomo Zuccarini, Marisa Michelini

Workshops

38

1. Simple experiments for enhancement of pupils’ curiosity about science

Dagmara Sokolowska, Daniel Dziob, Justyna Nowak, Aleksandra Wańczyk, Mateusz Wojtaszek, Witold

39

Zawadzki, Grzegorz Brzezinka

2. Hands-on experiments with hydrogels

40

Jerneja Pavlin

Poster presentations

41

1. The pedagogical treatments of weight and weightlessness in physics textbooks for primary school in

Bosnia and Herzegovina: An analysis of coherence between curriculum elements and textbook con-

42

tents

Jasmina Baluković, Josip Sliško

2. Physics and art in education: The two project ideas from Bosanska Krupa High School

43

Amna Dervišagić

3. Respiratory system - at the crossroads of physics and biology

44

Daniel Dziob, Justyna Nowak, Aleksandra Dejko, Bogdan Łabędź, Dagmara Sokolowska

4. An initial study of the transfer of knowledge through two-stage predict-observe-explain sequence:

the case of floating bodies with fixed and changeable volume

45

Matej Forjan, Josip Sliško

5. Student`s findings at solving young physicist tournament`s challenge - Thick lens

46

Lucia Mišianiková, Marián Kireš

6. Students' misconceptions of heat and temperature concepts

47

Maksuda Muratović

7. Firefly – not only a contest in science

Justyna Nowak, Daniel Dziob, Aleksandra Wanczyk, Bogdan Łabędź, Mateusz Wojtaszek, Dagmara

48

Sokolowska

8. High school students' knowledge and understanding of the phenomena associated with atmospher-

ic pressure

49

Džana Salibašić, Zalkida Hadžibegović

9. How to observe electric current and resistance?

50

Katarina Susman, David Rihtaršič

10. ‘Tea with MrBernoulii’, in other words Physics in Inquiry-Based Science Education (IBSE)

Aleksandra Wanczyk, Bogdan Łabędź, Daniel Dziob, Justyna Nowak, Mateusz Wojtaszek, Dagmara

51

Sokolowska

5





WELCOME

Dear participants,



After two years and a half, we meet again at the 2nd South Eastern European Meeting on Physics Ed-

ucation (SEEMPE) 2015. Welcome to Slovenia, Faculty of Education, University of Ljubljana. The in-

tention of SEEMPE is to bring together educators, researchers and scientists from neighbouring coun-

tries in the south Eastern region of Europe working on physics education. However, many researchers

come also from other European countries. We are very happy that they find this meeting interesting

as well. The aim of the meeting is to present the results of the research in physics education, to ex-

change research experiences and to discuss various problems, possible initiatives for projects and to

discuss experiences with on-going or finished projects.

Physics education research and physics education in general is becoming more and more important,

as the authorities are aware, that future needs scientists. Therefore, our mission is to provide an ap-

propriate school environment that encourages students for studying science.

Here we have to repeat few experiences from the first meeting. Education is often considered as an

art and the research in science education is not valued in the same way as other domains from the

majority of physicists. However, results of physics education research have severely influenced teach-

ing and learning processes at different cognitive level and in different institutions of formal and infor-

mal education. The way of teaching, the understanding of the teaching intervention effect on stu-

dents’ knowledge, students’ conceptual understanding, misconceptions, and cognitive abilities of stu-

dents to understand difficult or easy concepts in physics are playing more and more important role in

transfer of knowledge to students.

As the whole "know how" with respect to SEEMPE was already in Ljubljana, we have volunteered to

organize the second meeting in rather short notice. Several people responded to the call and more

than 40 people from Croatia, Serbia, Bosnia and Hercegovina, Slovakia, Poland, Germany, Austria, Ita-

ly, Turkey and Slovenia has come to share the ideas and report on research results. It is an indication

that our part of Europe is very active within this research field. We are looking forward to have a sci-

entifically strong and interesting meeting, which would also result in future collaborations.





Mojca Čepič, chair of the meeting





Program - Monday, 2.2.2015



presenting author

title

chair

8:50 - 9:00

opening

What is Content Knowledge for Teaching Physics

9:00 - 9:30

Eugenia Etkina

and How Can We Assess it?

9:30 - 10:00

Angela Foesel

Use your head – in football and physics education

Engineering freshmen understanding of atmos-

10:00 - 10:20 Zalkida Hadžibegović

Leopold

pheric pressure: The 5E learning model effects

Mathelitsch

Escaping Bear and Snail: How Ready is Engineering

10:20—10:40 Bayram Akarsu

Students For Puzzle-Based Learning

Framework for using modern devices in an intro-

10:40 - 11:00 Gorazd Planinšič

ductory physics course

11:00 - 11:30

coffee break + poster session

Dagmara Sokolowska, Daniel

Dziob, Justyna Nowak, Alek- Simple experiments for enhancement of pupils’

11:30 - 12:30 sandra Wańczyk, Mateusz

Mojca Čepič

curiosity about science

Wojtaszek, Witold Zawadzki,

Grzegorz Brzezinka

12:30 - 13:30

lunch

Labyrinthine-like wrinkled surfaces in liquid crystal-

13:30 - 14:00 Nataša Vaupotič

line free standing film

Introduction of Current Scientific Results into Edu-

14:00 - 14:20 Mojca Čepič

cation: Metastudy and Towards a Theoretical

Framework

Is the equivalence principle to be included in phys-

14:20 - 14:40 Tomaž Kranjc

ics instruction for non-physicists?

Maja Planinić

14:40 - 15:00 Bor Gregorčič

The added value of the interactive whiteboard

Problem solving approach to geometric optics –

15:00 - 15:20 Jaka Banko

applying theory to practice through primary school

students' hands-on experience

15:20 - 15:40 Nada Razpet

Analysis of children's sketches

15:40 - 16:10

coffee break + poster session

University students' difficulties with atomic emissi-

16:10 - 16:40 Lana Ivanjek

on spectra

Building stronger student knowledge – the case of

16:40 - 17:00 Maja Planinić

graphs

17:00 - 17:20 Ana Sušac

Student understanding of physical measurement Zalkida

Student difficulties with electromagnetic induction

17:20 - 17:40 Katarina Jeličić

Hadžibegović

and analysis of a research instrument

Results of a delayed transfer test of students’ un-

derstanding of buoyant force and related phenom-

17:40 - 18:00 Jelena Radovanović

ena stemming from two different learning experi-

ences

19:30-

Dinner

8



Program - Tuesday, 3.2.2015



presenting author

title

chair

A Design-Based-Research Project on Teaching Colours in

9:00 - 9:30

Claudia Haagen

Introductory Optics in Year 8

The inquiry skills required for everyday phenomenon

9:30 - 9:50

Marian Kireš

investigation

Gorazd

Developing formal thinking in learning progression re-

9:50 - 10:20

Marisa Michellini

search approaches and modern physics proposals

Planinšič

University Students on Incompatibility of Observables in

10:20 - 10:40 Zuccarni Giacomo

Quantum Mechanics

10:40 - 11:00 Alberto Stefanel

Exploration of students’ ideas on superconductivity

11:00 - 11:30

coffee break + poster session

11:30 - 12:30 Jerneja Pavlin

Hands-on experiments with hydrogels

Mojca Čepič

12:30 - 13:30

lunch

13:30 - 14:00 Dagmara Sokolowska

Assessment opportunities in inquiry-based learning

Comparison of the efficiency of three teaching methods

14:00 - 14:30 Maja Stojanović

in physics using the cognitive load

Influence of two different methods for solving free-body Eugenia

14:30 - 14:50 Ivica Aviani

diagrams on students' ability to identify forces and ap-

ply Newton's laws

Etkina

Probing students' conceptual knowledge of satellite

14:50 - 15:10 Nataša Erceg

motion by use of diagram

The Klein-Gordon string - a versatile system I've never

15:10 - 15:30 Sergej Faletič

heard of before

15:10 - 15:40

coffee break + discussion of future perspectives

15:40 -

closing

9





INVITED SPEAKERS

1. What is Content Knowledge for Teaching Physics and How Can We Assess it?

Eugenia Etkina, Lane Seely, Stamatis Vokos

2. Use your head – in football and physics education

Angela Fősel

3. A Design-Based-Research Project on Teaching Colours in Introductory Optics in Year 8

Claudia Haagen-Schützenhöfer

4. University students' difficulties with atomic emission spectra

Lana Ivanjek, Peter Shaffer, Lillian McDermott, Maja Planinić

5. Developing formal thinking in learning progression research approaches and modern physics pro-

posals

Marisa Michelini

6. Assessment opportunities in inquiry-based learning

Dagmara Sokolowska, Odilla Finlayson, Deirdre McCabe, Pawel Bernard

7. Comparison of the efficiency of three teaching methods in physics using the cognitive load

Maja Stojanović, Branka Radulović

8. Labyrinthine-like wrinkled surfaces in liquid crystalline free standing films

Nataša Vaupotič



10





1. What is Content Knowledge for Teaching Physics and How Can We Assess it?

Eugenia Etkina1, Lane Seely2, and Stamatis Vokos2

1Graduate School of Education, Rutgers University, USA

2 Seattle Pacific University, USA

E-mail: eugenia.etkina@gse.rutgers.edu

This talk will share our work on the development of a theoretical framework for Content Knowledge

for Teaching Energy (CKT-E) in high school physics. Specifically, it will describe how the new construct

of Content Knowledge for Teaching of specific content is different from the construct of PCK - Peda-

gogical Content Knowledge and how we can assess this knowledge when observing teachers In the

classroom and through using paper-and-pencil instruments. Three universities (Rutgers, Seattle Paci-

fic and University of Maine) and Educational Testing Service join their efforts together in this collabo-

rative project.

11





2. Use your head – in football and physics education

Angela Fösel

Physics Institutes, University of Erlangen-Nürnberg, Germany

E-mail: angela.foesel@physik.uni-erlangen.de

Including sports issues in physics education offers an opportunity to increase students’ interest and

motivation. Furthermore, it allows for taking into account the methodical and didactic ideas of ′active

learning′, which here means learning by and in motion. Students can perform athletic activities, they

can measure physical parameters of their own movements, and they can analyse the resulting data.

However there are a wide variety of possibilities to measure parameters and analyse data concerning

the athletic activities of real sportspersons. In any case, there is a definite necessity to develop and

apply models in order to interpret and understand the complex human limb movements. This active

modelling helps students attain knowledge regarding problem solving. Lastly, by measuring and ex-

plaining sports activities, fundamental concepts of physics can be taught.

Football is the one of the most popular sports in many countries, which means that a football-themed

physical discussion usually arouses great interest. This presumably accounts for the fact that a wide

range of (popular) science literature, as well as technical and subject-didactic articles have been pub-

lished on this subject. Apart from extensive works on football in its entirety, some partial aspects

have been singled out for closer scrutiny, such as unexpected trajectories of balls (curling crosses)

which impressively show the Magnus effect, the high ratio of coincidence in football results which

lends itself to statistical evaluation and the goalie’s (and the penalty-taker’s) anxiety at the penalty

kick, which can be convincingly explained with kinematics. Another important component of the

game, namely headers, have not yet been analysed as diligently, even though the question of how

dangerous a header really is relates directly to the determination of the forces and acceleration in-

volved. In this talk, we will show that headers may enrich physics education experimentally as well as

theoretically. Especially, we would like to focus on and present the examination of the interaction of

football and head from various different viewpoints. On the one hand, we introduce a wide array of

experimental approaches, from simple experiments to video analysis and data acquisition with accel-

eration sensors. We show the good agreement between data from video-camera and from sensor-

based data logging. We also point out that data logging and analysis concerning real situations within

a football match are much more difficult than experimental set-ups in laboratory.

We attempt to explain the data by using theoretical models of varying complexity. For instance, sim-

ple models may assume certain parameters like maximum force. When applying dynamical models

even time-based sequence of action could be simulated.

Finally, health aspects with regards to headers are discussed, as especially young players are at a par-

ticular risk in this respect and should be fully aware of this fact.

12





3. A Design-Based-Research Project on Teaching Colours in Introductory Optics in

Year 8

Claudia Haagen-Schützenhöfer

Regional Centre for Didactics of Physics , University of Graz, Austria

E-mail: claudia.haagen@uni-graz.at

We perceive our environment mainly through visual stimuli. Seeing colours is one eminent part of

visual perception. Understanding the phenomenon of coloured bodies based on adequate physical

concepts poses a big challenge for students in initial optic courses (Martinez-Borreguero et al., 2013).

A number of students' alternative conceptions about colour, which hinder the understanding of col-

our phenomena, are known from physics education research. One prerequisite for understanding

(geometrical) optics on a basic level is the idea that light emitted from or reflected by an object needs

to enter the eye of the observer in order to produce a visible sensation (deHosson et al., 2007; Gues-

ne, 1985). Feher and Meyer (Feher et al., 1992) summarize the following ideas as the most frequent

categories of students’ conceptions on the colour of illuminated objects: (1) the coloured light mixes

with the colour of the object, (2) coloured light is dark and makes objects appear darker, (3) coloured

light gives its colour to the object, (4) coloured light has no effect on the appearance of objects.

What makes the situation of instruction even more difficult in initial physics instruction in Austria is

that the physics curriculum of year 8 contains colour phenomena as part of geometrical optics. The

wave nature of light is, however, not part of year 8, but is first brought up in year 10. Consequently,

the teaching of colour phenomena is restricted to reconstructions of body colours not including the

wave aspect of light. Usually, Austrian students learn about two phenomena relevant for colour phe-

nomena, namely additive and subtractive colour mixing. What students mostly retain and use in any

situation if appropriate or not – are the mixing rules they know from their water colour boxes.

This contribution presents research based teaching materials developed and evaluated in a Design

Based Research Project. In order to support learning processes we based the teaching materials

about body colour on real phenomena and reconstructed the explanation with the processes of selec-

tive absorption and emission of light. Several easy experiments, which are supposed to help students

to relate body colour to processes of selective absorption and emission, were developed. In the

course of these easy experiments, students are instructed to observe and determine the paths of

light from a light source via the body to the observer.

References

Feher, E. & Meyer, K.R. (1992). Children's conceptions of color. Journal of research in Science Teaching, 29(5), 505–520.

Guesne, E. (1985): Light. In: R. Driver, E. Guesne und A. Tiberghien (Hg.): Children's ideas in science: Open University Press, S. 10–32.

Hosson C. de, Kaminski W. (2007): Historical Controversy as an Educational Tool: Evaluating elements of a teaching–

learning sequence conducted with the text “Dialogue on the Ways that Vision Operates”. International Journal of Science

Education;29(5):617–642.

Martinez-Borreguero, G., Pérez-Rodríguez, Á.L., Suero-López, M.I. & Pardo-Fernández, P.J. (2013). Detection of Misconceptions about Colour and an Experimentally Tested Proposal to Combat them. International Journal of Science Educa-

tion, 35(8), 1299–1324.

13





4. University students' difficulties with atomic emission spectra

Lana Ivanjek1, Peter Shaffer2, Lillian McDermott2, Maja Planinić1

1University of Zagreb, Croatia

2University of Washington, USA

E-mail: lana@phy.hr

Physics education research is still mostly focused on student understanding of basic topics from clas-

sical physics, with less emphasis on topics from modern physics. Examples of such a topic are line

spectra. It is important that students develop good understanding of spectra as a prerequisite for un-

derstanding of quantum mechanics, as well as astrophysics. The structure and formation of spectra

are a part of university and secondary school curricula both in Croatia and in the United States. Syste-

matic investigation of student understanding of atomic spectra was conducted among 1000 science

majors in introductory physics courses at University of Zagreb, Croatia and University of Washington,

USA. The research had two focuses: 1) to probe the extent to which university students are able to

relate the wavelength of spectral lines to the transitions of electrons between energy levels in an

atom, and 2) to probe the extent to which students recognize the conditions under which discrete

line spectra are (or are not) formed.

The results indicate low student understanding of the process of line spectrum formation. When

asked about the connection between energy levels and spectral lines, many students did not seem to

recognize that each spectral line is a result of a transition of an electron between two energy levels.

Difficulties with the understanding of the role of the experimental setup in formation of a line

spectrum were also encountered. A question that probed that aspect of student understanding was

constructed and administered to students. Only between 20 % and 30 % of the students recognized

that the type of the light source is critical for the formation of a line spectrum. Students were often

treating a prism as if it always yielded a continuous spectrum, treating spectral lines as if they were

always visible, and most of them were confusing discrete line spectra with diffraction patterns. Identi-

fication and analysis of student difficulties guided the design of a set of new instructional materials,

tutorials, to supplement instruction in a standard calculus-based physics course. An online spectra

application for homework use was also designed. The posttest results showed that some of the stu-

dent difficulties persisted even after instruction, and that there is more space for the further impro-

vement of instruction materials.

Findings from the research questions will be presented, and students’ most frequent reasoning diffi-

culties will be discussed. Students’ posttest results and the examples from the tutorial will also be

presented and discussed.

14





5. Developing formal thinking in learning progression research approaches and mo-

dern physics proposals

Marisa Michelini

University of Udine, Italy

e-mail: marisa.michelini@uniud.it

In the framework of the Model of Educational Reconstruction we study the development of formal

thinking starting from phenomena exploration. Research is focus on contributing to practice develo-

ping vertical coherent content related learning proposals by means of Design Based Research to pro-

duce learning progression and finding ways to offer opportunities for understanding and experience

what physics is, what it deals with and how it works in operative way. The research is not only limited

to those that function in practice, but integrate learning processes analysis. Empirical data analysis is

carried out on three main research problems: 1) individual common sense perspective with which

different phenomena are viewed and idea organization, in order to activate modeling perspective in

phenomena interpretation, 2) the exploration of spontaneous reasoning and its evolution in relation

to a series of problematic stimuli in specific situations, in order to formulate activity proposals, 3)

recognizing the modalities for overcoming conceptual knots in the learning environment in order to

reproduce these conditions. We study three main aspects: 1) object-models role in favoring the stu-

dent's first interpretative steps, 2) ICT role in overcoming conceptual knots, 3) developing theoretical

thought in an educational path concerning quantum mechanics.

Modern physics in secondary school is a challenge, which involve our research work since from 2006

in finding reasoning trajectory able to suggest learning path proposals based on experimented propo-

sals of active learning. After a presentation of our research approach and the learning progression

perspective into the research with some examples, the modern physics proposals developed will pre-

sented, focusing on the characteristics of quantum mechanics teaching/learning path.

15





6. Assessment opportunities in inquiry-based learning

Dagmara Sokolowska1, Odilla Finlayson2, Deirdre McCabe2, Pawel Bernard3

1Smoluchowski Institute of Physics, Jagiellonian University, Krakow, Poland

2Dublin City University, Ireland

3Faculty of Chemistry, Jagiellonian University, Krakow, Poland

e-mail: ufdsokol@cyf-kr.edu.pl

One of the most sought-after skills, naturally developed through inquiry, are the reasoning skills

(formulation of research questions, formulation of hypotheses, planning investigation, presenting and

explaining ideas, overcoming difficulties) and performance abilities (conducting the experiments, co-

operating). Moreover, during the inquiry lessons the engagement in brain storming and discussions,

as well as the competences in use of different representations can be developed. All of them give a

teacher many opportunities to assess the students individually or in groups, providing them with an

immediate feedback during the activities or with a written assessment after the classes.

SAILS project has been founded by EU under the 7th Framework Programme to support teachers in

adopting inquiry-based science education (IBSE) at the second level of schooling (students aged 12-18

years) across Europe by providing them with inquiry-base didactic material supplemented with the

assessment instruments.

During the talk an assessment strategy developed in SAILS project will be presented together with the

examples of its implementation.



Acknowledgment

This work is supported by the SAILS research project (SIS.2011.2.2.1-1, grant agreement 289085), which re-

ceived funding from the European Union under the Seventh Framework Program.

16





7. Comparison of the efficiency of three teaching methods in physics using the cogni-

tive load

Maja Stojanović, Branka Radulović

Department of Physics, Faculty of Sciences, University of Novi Sad, Serbia

e-mail: maja.stojanovic@df.uns.ac.rs

Modern didactic trends have the tendency to shift the focus from traditional learning to new teaching

methods, which show the greater efficiency in the students’ understanding of the content. We exam-

ined how a particular form of learning affects the mental effort of students while learning the new

concepts. Three methods were studied: the multimedia, the method of using experiments and the

traditional method. Testing of the cognitive load determines the changes of teaching methods, and

thus the direction of their development.

This study included 187 second grade students in high school (gymnasium – science and mathematics

direction) in Novi Sad. Data were collected using a cognitive test designed for this study. Data pro-

cessing was done using the descriptive methods, test, Wilcoxon t-test and ANOVA.

The main conclusions of this study are that there is a causal link between the choice of teaching

methods and the achievements, i.e., the cognitive load of students. The results suggest that the stu-

dents who received instructions using experiments have obtained greater achievement and subjec-

tively showed less cognitive load, than the students who received instructions using other two meth-

ods. Therefore, the results obtained indicate that the teaching method using experiments is more

efficient than other two methods, because it causes less cognitive load, which increases the likelihood

that the resulting information is processed into long-term memory.

17





8. Labyrinthine-like wrinkled surfaces in liquid crystalline free standing films

Nataša Vaupotič1,2

1Faculty of Natural Sciences and Mathematics, University of Maribor, Slovenia

2Jozef Stefan Institute, Jamova 39, 1000 Ljubljana, Slovenia

e-mail: natasa.vaupotic@uni-mb.si

Liquid crystals are materials which, next to the crystalline, isotropic liquid and gaseous phase, also

have a liquid phase which possess some orientational order of the constituent molecules. This phase

flows like liquids, but its physical properties are direction dependent (anisotropic), which is character-

istic for crystals. Because of that such materials are called liquid crystals and the phase a liquid crys-

talline phase. Liquid crystals present a new polygon for experiments in the secondary school and at

the undergraduate university level and a set of liquid crystals experiments can present a file rouge

through several topics in physics education [1,2].

Although liquid crystals were discovered at the end of the 19th century, they are still a topic of a cur-

rent research. In the talk I will present a recent study of thin free standing films (like the one we make

when we want to blow a bubble) made of liquid crystalline material in which, upon lowering the tem-

perature, the surface wrinkles, which means that the surface is not the minimal possible [3]. A period-

ic modulation of the film thickness is obtained and a labyrinthine structure of crests and valleys is

formed. The thickness instability occurs spontaneously at a threshold temperature within the liquid

crystalline phase. Labyrinths were observed both in thin and thick films. The width of the labyrinthine

path depends on the temperature and the thickness of the film.

Comparing the textures observed in the reflected light (see figure, right) and the light transmitted be-

tween crossed polarisers (see figure, left) it is found

that the film thickness is coupled to the spatial vari-

ation of the molecular orientation. In the regions

with thickness gradient the molecular orientation is

uniform and on the top of the hills or bottom of the

valleys it rotates by 180 degrees. The observed phe-

nomenon is associated to the difference in the mass

density at the surface and in the bulk. Theoretical

estimates show that at a certain temperature the system reduces the free energy by enlarging the

sloped regions more than it pays for the formation or the defects associated with increasing the

sloped areas.

In the talk I will explain how simple, but ingenious experiments enable determination the structure of

the film and how simple theoretical considerations can help in confirming or discarding the possible

models of the structure.

References

[1] J. Pavlin, N. Vaupotič and M. Čepič, Eur. J. Phys. 34, 745 (2013).

[2] J. Pavlin, N. Vaupotič and M. Čepič, Eur. J. Phys. 34, 331 (2013).

[3] D. Pociecha, E. Gorecka, N. Vaupotič, M. Čepič and J. Mieczkowski, Phys. Rev. Lett. 95, 207801 (2005).

18





ORAL CONTRIBUTIONS

1. Escaping Bear and Snail: How Ready is Engineering Students For Puzzle-Based Learning?

Bayram Akarsu

2. Influence of two different methods for solving free-body diagrams on students' ability to identify

forces and apply Newton's laws

Ivica Aviani, Nataša Erceg, V. Mešić

3. Problem solving approach to geometric optics – applying theory to practice through primary

school students' hands-on experience

Jaka Banko

4. Introduction of Current Scientific Results into Education: Metastudy and Towards a Theoretical

Framework

Mojca Čepič

5. Probing students' conceptual knowledge of satellite motion by use of diagram

Nataša Erceg, Ivica Aviani, V. Mešić, Z. Kaliman, D. Kotnik-Karuza

6. The Klein-Gordon string - a versatile system I've never heard of before

Sergej Faletič

7. The added value of the interactive whiteboard

Bor Gregorčič

8. Engineering freshmen understanding of atmospheric pressure: The 5E learning model effects

Zalkida Hadžibegović

9. Student difficulties with electromagnetic induction and analysis of a research instrument

Katarina Jeličić, Maja Planinić, Gorazd Planinšič

10. The inquiry skills required for everyday phenomenon investigation

Marián Kireš

11. Is the equivalence principle to be included in physics instruction for non-physicists?

Tomaž Kranjc

12. Building stronger student knowledge – the case of graphs

Maja Planinić, Ana Sušac, Lana Ivanjek, Željka Milin-Šipuš

13. Framework for using modern devices in an introductory physics course

Gorazd Planinšič, Eugenia Etkina

14. Results of a delayed transfer test of students’ understanding of buoyant force and related

phenomena stemming from two different learning experiences

Jelena Radovanović, Josip Sliško, Ivana Stepanović Ilić

15. Analysis of children’s sketches

Nada Razpet

16. Exploration of students’ ideas on superconductivity

Alberto Stefanel, Marisa Michelini

17. Student understanding of physical measurement

Ana Sušac, Petra Martinjak, Maja Planinić, Andreja Bubić, Marijan Palmović

18. University Students on Incompatibility of Observables in Quantum Mechanics

Giacomo Zuccarini, Marisa Michelini

19





1. Escaping Bear and Snail: How Ready is Engineering Students For Puzzle-Based

Learning?

Bayram Akarsu

Erciyes University, Kayseri, Turkey

e-mail: bakarsu@erciyes.edu.tr

Critical thinking and problem solving abilities are accepted as one of the most important abilities in

science education. This study explores engineering students’ problem solving skills in college. In ad-

dition, their critical thinking and puzzle-based learning abilities were explored. Data were collected

from 139 freshman students enrolled in Mechatronic, Civil, Electrical and Electronics, Biomedical, In-

dustrial, Computer and Metallurgical and Materials engineering departments during Spring 2013 se-

mester. Participants were in the second semester of their first year in college. 67 % (N= 94) of them

were male and 33 % (N=46) were female. Findings revealed that most of the students are lack of criti-

cal thinking and problem solving skills and are not ready for puzzle-based learning activities.

References

Alexander, W.A. (2004). Workplace skills and the skills gaps related to employee critical thinking ability and science education curriculum. Doctoral dissertation, The Ohio State University, UMI No. 3144834.

Bailin, S. (2002). Critical Thinking and Science Education. Science & Education, 11, 361–375.

Becker, D.E. (2007). The effect of patient simulation on the critical thinking of advanced practice nursing students. Doctoral dissertation, Drexel University, UMI No. 3259372.

Bricker, L.A. & Bell, P. (2008). Conceptualizations of argumentation from science studies and the learning sciences and their implications for the practices of science education. Retrieved from http://www.interscience.wiley.com, doi: 10.1002/sce.20278.

Burns, E. (2009). The use of science inquiry and its effect on critical thinking skills and dispositions in third grade students. Doctoral dissertation, Loyola University Chicago, UMI No. 3367974.

Byrne, M.S. & Johnstone, A.H. (1987). Critical thinking and science education. Studies in Higher Education, 12(3), 325-339.

Cho, K. & Jonassen, D.H. (2002). The effects of argumentation scaffolds on argumentation and problem solving. Educational Technology Research and Development, 50(3), 5–22.

Clarke, K. C. (2010). A science, engineering and technology (SET) approach improves science process skills in 4-H animal science participants.

Journal of Extension, 48(1), 1-4.

Derwin, E.B. (2008). Critical thinking in online vs. face-to-face higher education. Doctoral dissertation, Fielding Graduate University, UMI No.

3343844.

Duschl, R. (2008). Science education in three-part harmony: Balancing conceptual, epistemic, and social learning goals. Review of research in education, 32(1), 268-291.

Duschl, R. A., & Osborne, J. (2002). Supporting and promoting argumentation discourse in science education. Studies in Science Education, 38, 39-72.

Erduran, S., & Jiménez-Aleixandre, M. P. (Eds.). (2008). Argumentation in science education: Perspectives from classroom-based research (Vol.

35). Springer.

Erduran, S., Simon, S. & Osborne, J. (2004). Tapping into argumentation: Developments in the application of Toulmin's argument pattern for studying science discourse. Science Education, 88(6), 915–933.

Driver, R., Newton, P. & Osborne, J. (2000). Establishing the norms of scientific argumentation in classrooms. Science Education, 84, 287-312.

German, N.A. (2008). Assessment of critical thinking skills among undergraduate athletic training students. Doctoral dissertation, North Dakota State University, UMI No. 3335160.

Goh, W.W.L. (2008). Dialogic argumentation as a path to enhancing individual argumentive reasoning in academically disadvantaged 8th-graders. Doctoral dissertation, Columbia University, UMI No. 3305223.

Halpern, D.F. (1999). Teaching for critical thinking: Helping college students develop the skills and dispositions of a critical thinker. New Direc-tions for Teaching and Learning, 80, 69–74.

Harlow, D.B. & Otero, V.K. (2004). An examination of children’s scientific argumentation. Physics Education Research Conference Proceedings, 720, 145-148.

Hewson, M.G. & Ogunniyi, M.B. (2011). Argumentation-teaching as a method to introduce indigenous knowledge into science classrooms: opportunities and challenges. Cultural Studies of Science Education, 6, 679–692, doi: 10.1007/s11422-010-9303-5.

Ingram, M. (2008). Critical thinking in nursing: experience vs. education. Doctoral dissertation, University of Phoenix, UMI No. 3304800.

Jiménez-Aleixandre, M. P., & Erduran, S. (2007). Argumentation in science education: An overview. In Argumentation in science education (pp.

3-27). Springer Netherlands.

Kanik, F. (2010). In partial fulfillment of the requirements for the degree of Doctor of Philosophy in the Department of Educational Sciences.

Doctoral dissertation, Middle East Technical University, Ankara.

Kıngır, S., Geban, Ö. & Günel, M. (2011). Students’ ideas about the implementation of the argumentation based science inquiry approach in their chemistry course. Selçuk University Journal of Ahmet Kelesoglu Education Faculty (AKEF), 32, 15-28.

Kim, K., Sharma, P., Land, S.M. & Furlong, K.P. (2012). Effects of active learning on enhancing student critical thinking in an undergraduate general science course. Innovative Higher Education, 38, 223–235.

Kuhn, D. (1991). The Skills of Argument. Cambridge University Press.

Kuhn, D. (2010). Teaching and learning science as argument. Science Education, 94(5), 810-824.

20





2. Influence of two different methods for solving free-body diagrams on students'

ability to identify forces and apply Newton's laws

Ivica Aviani1, N. Erceg2 and V. Mešić3

1 Institute of Physics, Zagreb and Faculty of Science, University of Split, Croatia

2 Department of Physics, University of Rijeka, Croatia

3 Faculty of Science, University of Sarajevo, Bosnia and Herzegovina

e-mail: aviani@ifs.hr

In most physics courses vector calculus is carried out by resolving the forces into components and

then summing up the components of the same direction. Although this procedure facilitates the cal-

culation, it potentially leads to the misconception that the components are also some real forces. In

addition, the procedure is not entirely in accord with the concepts of the Newton’s laws which state

that the motion of the body is determined by the vector sum of the forces. The question arises: is the

direct vector method or application of the polygon rule for vector addition more successful in teach-

ing mechanics?

In this study, we have developed an instrument to measure students’ ability to identify real forces in

different diagrams. Using this instrument we made an initial study of the effectiveness of the two

different problem solving methods. Our test, consisting of 12 items, was administered to two groups

of first-year physics students at Rijeka (RG) (n = 27) and Split (SG) (n = 25) university, after the

“concept of force” had been covered in class. Afterwards, both groups exercised additional force dia-

grams tasks for a period of two class hours. The only difference was that RG used the polygon rule

and SG the vector components method. Post test showed a shift in the average rate of correct re-

sponses which was significantly larger for RG. Based on these initial results we formulate the working

hypothesis for the future investigation: If we apply the teaching method where the force diagrams

are solved by using the polygon rule, we foster the students' ability to identify real forces and we im-

prove their understanding of Newton's laws.

21





3. Problem solving approach to geometric optics – applying theory to practice thro-

ugh primary school students' hands-on experience

Jaka Banko

The National Education Institute, Slovenia

E-mail: jaka.banko@zrss.si

Wax lenses are an inexpensive way for students to explore the basics of geometrical optics through

individual experimental work or group work. Making lenses is suitable for school project days, science

days, fairs or other similar events. Home-made lenses allow teacher to use problem solving approach

to teaching. Students can design their own experiments, make lenses, construct optical instruments

and test their hypotheses which would explain the phenomenon or solve the problem. The flexibility

of the material from which lenses are made allows students to change the radius of the lens and

hence adjust the focal length. Lenses also have a motivational value (different colours, sizes).

22





4. Introduction of Current Scientific Results into Education: Metastudy and Towards

a Theoretical Framework

Mojca Čepič

Faculty of Education, University of Ljubljana, Slovenia

e-mail: mojca.cepic@pef.uni-lj.si

Students consider physics as boring, abstract and detached from everyday life, and they are not aware of on-

going research. However, our society and almost all of its welfare is based on research results, where applica-

tive potentials were recognized. The society being thoroughly familiar with current research is rather specific.

Researchers are usually not involved in education except at graduate levels, and usually they do not feel a de-

sire or an obligation to transfer the new knowledge to younger students or to the lay public. Nevertheless, this

step toward non trained researchers is crucial in order to get a support for a research from a general citizen

and a taxpayer and to increase a motivation of best students to pursue scientific careers.

We have recently developed a module that has introduced current research results on liquid crystals into edu-

cation [1]. The module consists of lectures and laboratory work in chemistry and physics. Several problems

have arisen during the development of the module, for example: goals and an expected conceptual level of

understanding had to be defined; a necessary preliminary knowledge of students had to be determined; most

appropriate methods for teaching novel concepts had to be chosen; the research topic had to “translate” from

professional language of researchers to semi - several experiments for illustrations and support for conceptual

understanding; tests for assessment had to be developed and several other smaller problems had to be solved.

Introduction of new research results into education is an interesting and a difficult research problem by itself.

Inspired by our experiences during an introduction of current research results into education for a case of liq-

uid crystals, we tried to find similarities or differences in existing approaches to a transfer of new scientific

knowledge into education. There were not many reports on introductions of new topics. Reports mainly con-

sidered designs of new laboratory experiment (in advanced optics and similar), only few modules were found

(on tribology, semiconductors), sometimes topics aimed for teachers are presented (nanotechnology, super-

conductors) and only one example on semiconductors was found where a module was developed and evaluat-

ed [2].

This contribution reports on results of this metastudy and we will share detailed results on

(a) Considerations and steps that were used at introduction of a topic »liquid crystals« to education at al levels

[1].

(b) Metastudy of reports on introduction of other topics: superconductivity, tribology, semiconductors, ad-

vanced optics and other modern topics.

Based on this data, we shall suggest a pilot theoretical framework for introduction of current research results

into education with an emphasis on physics. The theoretical framework will consists of criteria for the choice of

a modern topic, for determination of teaching goals, of prerequisites required from students and from teach-

ers, a suggested procedure of module construction and implementation and finally, a suggestion for assess-

ments of goals.

References

[1] J. Pavlin, N. Vaupotič, M. Čepič, Liquid crystals: a new topic in physics for undergraduates, Eur. J. Phys. 34, 745-761

(2013).

[2] A. Garcia-Carmona, A. M. Criado, Introduction to Semiconductor Physics in Secondary Education: Evaluation of a

teaching sequence Int. J. Sc. Ed. 31, 2205–45 (2009).

23





5. Probing students' conceptual knowledge of satellite motion by use of diagram

Nataša Erceg1, Ivica Aviani2, V. Mešić3, Z. Kaliman1, D. Kotnik-Karuza1

1 Department of Physics, University of Rijeka, Croatia

2 Institute of Physics, Zagreb and Faculty of Science, University of Split, Croatia

3 Faculty of Science, University of Sarajevo, Bosnia and Herzegovina

E-mail: nerceg@phy.uniri.hr

Regardless of wide use of satellites they are still often considered as “mysterious” objects, mostly be-

cause they travel in space where most of us have never been. So that developing an intuitive under-

standing of satellite motion remains out of our scope. That's probably why the dynamics of orbital

motion proved to be conceptually difficult for students.

Being aware of these conceptual difficulties, many years after he published Principia, Newton wrote a

popular text to explain the orbital motion of the Moon. In this paper he demonstrated the signifi-

cance of the velocity of the satellite as equally responsible for the orbital motion as the attractive

gravitational force of the Earth [1]. He discussed the trajectory of a cannon ball which was launched

horizontally from the top of a high mountain and, which was attracted by the Earth gravity. If the

launch speed was increased enough, the ball would start orbiting the Earth. Besides, the gravitational

force is directed toward the center of the Earth so that the center of the circular satellite orbit and

the center of Earth should match.

Two and half centuries later, students enter and leave the physics instruction with a wide variety of

misconcepts about satellite motion. Many physics education researchers were aware of the im-

portance of studying this topic which resulted in identification of many students’ misconceptions.

In our study [2], we investigated students’ ideas about possible satellite orbits. And we have conclud-

ed following: 1) Students tend to use the p-prim [3] "closer is stronger" instead of applying physics

knowledge; 2) Regardless of their educational level and curricula, students in Croatia lack deep under-

standing of circular motion, gravitational force and first cosmic velocity. 3) The teachers considerably

overestimate students’ abilities.



References

[1] I. Newton, A treatise of the system of the world (printed for F. Fayram, London, 1731).

[2] N. Erceg, I.Aviani, V.Mešić, Z. Kaliman and D. Kotnik-Karuza, Rev. Mex. Fis. E 60 (2014) 75.

[3] A. A. DiSessa, Cogn. Instr. 10 (1993) 105.

24





6. The Klein-Gordon string - a versatile system I've never heard of before

Sergej Faletič

Faculty of mathematics and physics, University of Ljubljana, Slovenia

e-mail: sergej_faletic@yahoo.com

I will introduce the so called Klein-Gordon string or braced string. In the discrete case, it consists of a

system of many coupled oscillators. The wave equation for it is the Klein-Gordon equation, hence the

name. The system displays dispersion and anisotropy. These properties are very valuable in a simple

mechanical system which students can have concrete experience with. I will show how the dispersion

property can be used to discuss group velocity, especially in the case of a single pulse. The question I

hear often is, how come that on a medium with dispersion, not even the first crest travels with phase

velocity. This system can answer it. The anisotropy property can be used to display the change in po-

larization from linear to elliptical and back, the feature displayed by light passing through birefringent

materials, but rarely observable in mechanical waves, with which students can have concrete experi-

ences. In the end, I will show that the system can also be used to reproduce the shapes of wave-

functions of quantum mechanical systems in a potential, such as exponential tails and tunnelling.

With this we show that these properties are inherent to waves, and not a quantum phenomenon.

25





7. The added value of the interactive whiteboard

Bor Gregorčič

Faculty of Mathematics and Physics, University of Ljubljana, Slovenia

E-mail: bor.gregorcic@fmf.uni-lj.si

As the interactive whiteboard (IWB) becomes more and more common in classrooms all over the

world, there is an increasing need to use it productively for teaching different subjects, including

physics. The IWB allows more than just projecting computer content onto a screen. Its touch sensi-

tive surface allows manipulation of the on-screen content. If we want to use the IWB productively, we

should engage students in activities where they are actively engaged in collaborative learning through

investigative activities. We will present a qualitative study, where designed instructional materials

were implemented in a high-school context. When developing the materials, we took into account

the kinesthetic and collaborative affordances of the IWB to support student collaborative learning

activities. We will explain how these affordances supported student engagement and communication

among participants and present what we have found to be advantages and drawbacks of different

kinds of IWB use in physics instruction from the students’ and the teachers’ point of view.

26





8. Engineering freshmen understanding of atmospheric pressure: The 5E learning

model effects

Zalkida Hadžibegović

Physics Department, Faculty of Science, University of Sarajevo

E-mail: zalkida@yahoo.com

In this study are presented results based on the data collected in a learning sequence with main aim

to explore students’ understanding of atmospheric pressure. Also, this study investigates the effects

of using 5E learning model and students’ abilities to give their scientific explanations about some ex-

periment outcomes they observed. The study participants were a group of 40 engineering freshmen

at one public university in Bosnia and Herzegovina. The General Physics course syllabus was realized

with them mostly on traditional teaching-learning and instructor-centered approach without any stu-

dents’ activities in active learning environment. The data analysis is based on student worksheet an-

swers and evaluation survey data collected in a section that lasted 90 minutes. In-class students’ ac-

tivities were supported by two experiments; first one as experimental setting consisted of a glass-

water-paper cover and other using a plastic bottle with water. The students showed several miscon-

ceptions regarding to the role of atmospheric and hydrostatic pressure, as well as with pressure force

acting. The students’ difficulties were found in the 5E explanation phase because of lack of students'

correct scientific explanations because they have never been taught to gain such abilities. The use of

the experiments has been very well accepted by students in view of better understanding of some

learning subject matter if is possible to see something real and by doing. 98% pf study participants

found that they explored a new and very helpful variety of physics learning supported by experiments

and instructor’s role to guide them to learn how to explain scientifically the phenomena associated

with atmospheric pressure. All students have considered that they should be more active learners

who do experiments and learn how to explain physics around them by scientific arguments. These

research results show that university physics education should be implemented much more in stu-

dent-centered instead in instructor-centered learning to increase student learning efficiency.

27





9. Student difficulties with electromagnetic induction and analysis of a research in-

strument

Katarina Jeličić1, Maja Planinić2, Gorazd Planinšič1

1Department of Physics, Faculty of Mathematics and Physics, University of Ljubljana, Slovenia

2Department of Physics, Faculty of Science, University of Zagreb, Croatia

E-mail: katarinajelicic@gmail.com

We presented the results of the interviews with nine Croatian high school students concerning their

reasoning about electromagnetism (magnetic fields, Lorentz's force, electromagnetic induction,

Lenz's law) at the first SEEMPE meeting. This time we will show preliminary results of the second part

of the same investigation. Using the results of the interviews, we designed a questionnaire and ad-

ministered it to 537 high school students in Croatia (aged 16-17) after they had learned about electro-

magnetic induction in their physics class. The questionnaire consisted of 15 multiple-choice questions

and 7 open-ended questions. In the first step of the analysis, we used Rasch modelling to analyse the

functioning of the multiple-choice part of the questionnaire. Our analysis shows that the question-

naire is well centred on students’ abilities. Item reliability indicates well defined difficulties of test

items. However, person reliability warns us about some inconsistencies in the questionnaire. We plan

to discuss the functioning of the multiple choice part of the research instrument to verify whether

this questionnaire was an appropriate tool for determining students’ difficulties with electromagnetic

induction. We will also discuss student difficulties with electromagnetic induction that were identified

using the questionnaire and compare them with the difficulties identified through preliminary inter-

views.

28





10. The inquiry skills required for everyday phenomenon investigation

Marián Kireš

Division of Didactics of Physics, Institute of Physics Faculty of Science P.J. Šafárik University in Košice,

Slovakia

E-mail: marian.kires@upjs.sk

There are many different phenomena that students come across every day. Depending on their inter-

est, previous knowledge, they may observe them in detail or may not. There are a lot of phenomenon

that everybody has already seen and watched. Mostly common but rather complex phenomenon that

involves a set of processes can be used as a good opportunity to develop skills to observe, formulate

a problem, develop a hypothesis and plan investigations and hence can be built up to an inquiry activ-

ity to be carried out by students. What is the power of candle, we selected as an exemplary problem.

Students before starting investigation can begin with observation of the phenomenon and formu-

lating problems connected with candle burning. Raising questions can be supported by teacher-

student dialogue when teacher help students to ask additional, more sophisticated questions. Based

on students´ formulated questions there can be the investigation plan designed. Taking into account

the time limitation and the current state curriculum in physics and availability of tools needed for ex-

perimentation we have developed three school inquiry activities. Computer based measurements are

carry out by the help of VinciLab and Coach6 software, thermocouple and digital balance. Finally, for

the different candle materials heat of combustion is measured.

29





11. Is the equivalence principle to be included in physics instruction for non-

physicists?

Tomaž Kranjc

University of Ljubljana, Faculty of Education, Ljubljana, Slovenia

e-mail: tomaz.kranjc@pef.uni-lj.si

Problems in the physics instruction are often connected with the lack of interest among students and

the feeling that the school-acquired knowledge of physics is boring and uninteresting. New methods,

among other approaches, try to introduce active teaching/learning (e.g. in the form of inquiry-based

instruction) which makes the instruction more interesting and, at the same time, enable students to

be better primed for coping with new problems and to get used to think and make hypotheses and

conclusions about their observations.

On the other hand, a good way to motivate students seems to be the inclusion of topics which have

the potential to stir curiosity, stimulate “sense-making” about the acquired knowledge, to discover

new connections among different phenomena and quantities, and to link/relate/bring together vari-

ous seemingly disconnected pieces of knowledge that they have learnt previously.

In the contribution, we describe the experience of including the equivalence principle as a kind of dis-

traction/“entertainment” into the university introductory physics course for non-physicists. The prin-

ciple of equivalence was presented to students and they were invited to think, in the form of class

activities, about some of its consequences. In particular, the free-floating (inertial) systems were con-

sidered and the state of “weightlessness” revisited; the local character of the free-floating frames and

the tidal effects were investigated. Students were confronted with some of the unexpected conse-

quences: deflection of light in the gravitational field, red shift, the flow of time in a gravitational field,

and the question of the (non-)radiation of an electron in a gravitational field. Some aspects of the

quantum mechanical equivalence principle were shown.

The response of students to the “equivalence interlude” was tested through a questionnaire and con-

versations.

30





12. Building stronger student knowledge – the case of graphs

Maja Planinić1, Ana Sušac1, Lana Ivanjek1, Željka Milin-Šipuš2

1Department of Physics, Faculty of Science, University of Zagreb, Croatia

2Department of Mathematics, Faculty of Science, University of Zagreb, Croatia

e-mail: maja@phy.hr

Building deeper and more robust student knowledge in physics is one of the main goals of physics

education on all levels. A large-scale study on university students’ graph interpretation strategies and

difficulties in physics (kinematics), mathematics and other contexts conducted in Croatia revealed

many weaknesses in student knowledge and reasoning about graphs. In the study, eight sets of paral-

lel mathematics, physics and other context questions about graphs, which were developed by the

authors, were administered to 385 first-year students at the Faculty of Science, University of Zagreb.

Students were required to provide explanations and/or mathematical procedures with their answers.

Students’ main strategies and difficulties identified through the analysis of those explanations and

procedures will be described and discussed. Student strategies of graph interpretation were found to

be largely context dependent and domain specific. Only a small fraction of students have used the

same strategy in all three domains (mathematics, physics and other contexts) on most sets of parallel

questions. Students also displayed many reasoning difficulties which were not equally frequent in

different domains. The study revealed that students’ knowledge about graphs is rather compartmen-

talized, and suggests that building stronger student knowledge requires building stronger links betwe-

en different domains. The use of other context problems in physics and mathematics teaching may

be a step in that direction, since they seem to have a potential to expose and develop student rea-

soning more than the standard, domain - specific mathematics and physics questions. This one and

other implications for teaching about graphs will be discussed.

31





13. Framework for using modern devices in an introductory physics course

Gorazd Planinšič1, Eugenia Etkina2

1Faculty of Mathematics and Physics, University of Ljubljana, Slovenia

2Graduate School of Education, Rutgers University, USA

E-mail: gorazd.planinsic@fmf.uni-lj.si

Introductory physics courses are typically employing experiments that originate from 16th to 19th

century and rarely from 20th or 21st century. On the other hand, our students are every day sur-

rounded by many devices and materials that are the result of scientific and technological achieve-

ments of the last decades. In this talk we will present a framework for analyzing possibilities for using

modern devices in an introductory physics course. We will discuss how the framework can be used to

introduce into physics curriculum such complex physics systems as light emitting diodes (LEDs).

32





14. Results of a delayed transfer test of students’ understanding of buoyant force

and related phenomena stemming from two different learning experiences

Jelena Radovanović1, Josip Sliško2, Ivana Stepanović Ilić3

1Primary school “Slobodan Sekulić”, Užice, Serbia

2Facultad de Ciencias Fisico Matemáticas Benemérita, Universidad Autónoma de Puebla, Puebla, México

3Institute of Psychology, Belgrade, Serbia

e-mail: lena.radovanovic@gmail.com

This contribution describes delayed transfer test aimed at determining the degree of long-term adop-

tion of the conceptual understanding of buoyancy and related phenomena. The transfer of knowled-

ge, a process of activating previously learned skills and concepts and applying them to novel situati-

ons, is very important, not only for real-world application of knowledge, but also as a foundation for

learning and understanding of new topics.

The test was conducted 3 months after the learning sequence, as a part of the first author’s research

doctoral project “Changes in students’ alternative conceptions during physics learning - Effects of tra-

ditional teaching and active learning methods”. The research was conducted with a sample of 153

seventh-grade elementary school students (13 years old) in Uzice (Serbia) as a pedagogical experi-

ment with two parallel natural groups. The control group had traditional lectures, characterized by

teacher’s verbal presentation of knowledge and passive role of students. At the same time, teaching

and learning in the experimental group were implemented through those methods that require the

use of more complex mental processes, creativity and ability to apply knowledge in different situati-

ons, freedom of choice and expression, as well as peer-to-peer collaboration.

The delayed transfer test consists of five questions with varying degree of complexity, designed to

test students’ knowledge on buoyant force, conditions leading to floating and sinking, as well as the

presence of certain alternative conceptions on these phenomena.

The contribution reports students’ achievements on delayed transfer test as functions of teaching

and learning methods they were exposed to (traditional vs. active learning), their cognitive deve-

lopment and general achievement levels. The results clearly point out the need for application of acti-

ve learning methods with the goal of obtaining longer-lasting knowledge on buoyancy and related

phenomena, and overcoming alternative conceptions on floating and sinking.

33





15. Analysis of children’s sketches

Nada Razpet

Faculty of Education, University of Primorska, Koper, Slovenia

e-mail: nada.razpet@pef.uni-lj.si

The quickest way to find out what children already know about some natural phenomenon is to let

them make sketches. Giving children such a task, one has to be careful to give appropriate instruc-

tions of how to do sketches: the instructions should not be too long, but nevertheless precise enough

so that children know what to draw and in what way. Then the children’s sketches have to be ana-

lyzed—this is the only way to find out which concepts have not yet been mastered by children, what

experiments are still to be performed (or which phenomena are to be observed once again and what

has to be repeated in order that a topic is mastered by the pupils).

The students of Primary Teacher Program wanted to perform, within their seminar work, a more de-

tailed analysis of the pupils’ sketches. In the course of the field work in one of the primary schools, a

questionnaire was administered among pupils of the second grade (26 children), of the fourth grade

(32 children) and of the fifth grade year (58 children). The pupils sketched themselves and their shad-

ow in the morning, in the afternoon and at noon. Their sketches were handed over to the students in

order to be analyzed. We found out that the students had a lot of problems in doing the analysis. We

therefore decided to dedicate more time to this activity. We discussed with students how to prepare

the questionnaire, how to prepare the analysis, we discussed the analysis itself and the problems en-

countered by both the pupils and the students.

34





16. Exploration of students’ ideas on superconductivity

Alberto Stefanel, Marisa Michelini

Research Unit in Physics Education, University of Udine, Italy

e-mail: alberto.stefanel@uniud.it

Superconductivity is an important context to be integrated in secondary school currcula because it is

a significant part of the physics of the '900, has important applications (Aubrecht 1989; Gil, Solbes

1993; Hake 2000), can be addressed at different levels (Osterman et al 1998, 2000; Guarner 1992). An

educational approach to superconductivity was designed, based on the exploration of the electrical

conducting properties and the magnetic properties of superconductors (Viola et al. 2008; Michelini,

Santi, Stefanel 2014). Research experimentations, carried out in Italian High Schools was performed,

in 10 hours of inquiry based activities, conducted using Stimuli Worksheets and a pre-post test

(Stefanel, Michelini, Santi 2014; Michelini, Stefanel, Vanacore 2014). The results of the experimentati-

ons evidenced that the ways in which students give account the phenomenon of levitation of a mag-

net on a superconductor are related to how they describe, by the field lines and the magnetization

vectors, the magnetic fields in the material and magnetic interactions in general.

References

Aubrecht G. (1989) Redesigning courses for the 21stcentury. AJP, 57, p. 352-359.

Gil D. P., Solbes. J. (19939 The introduction of modern physics. IJSE, 15, p.255-260.

Guarner E., Sánchez A.M. (1992) The SC bird. The Phys. Teach.,30, p. 176-179.

Hake R.R. (2000) Is it Finally Time to Implement Curriculums? AAPT Announcer 30(4) p. 103.

Michelini M, Santi L, Stefanel A (2014) Basic concept of superconductivity, in FFFP12, Burra G. S., Michelini M,

Santi L, eds, Springer, NY, Dordrecht, London, pp. 453-46

Michelini M., Stefanel A., Vanacore A. (2014) Exploration of students’ ideas about superconductivity, in Active

learning – in a changing world of new technologies, Leoš Dvořák L. and Věra Koudelková V., eds, Charles Univ.

Prague, pp. 541-551

Ostermann F., Ferreira L.M., Cavalcanti C.J.H. (1998) Tópicos de física contemporânea no ensino médio. Revista

Brasileira de Ensino de Física, 20, p. 270-288.

Ostermann F., Moreira M.A. (2000) Física Contemporânea em la escuela secundaria. Revista de Enseñanza de

las Ciencias, 3 (2), 18. p. 391-404.

Stefanel A, Michelini M, Santi L (2014) High school students analyzing the phenomenology of superconducti-

vity, in Tasar F.ed., WCPE 2012, Pegem Akademiel, pp..1253-1266.

Viola R., Michelini M., Santi L., Corni F. (2008) The secondary school experimentation of SC, In Frontiers of

Phys. Educ.. Ed. R. J-Sepic et al., p.190-196. Girep-Epec, Zlatni. Rijeka

35





17. Student understanding of physical measurement

Ana Sušac1, Petra Martinjak1, Maja Planinić1, Andreja Bubić2, Marijan Palmović3

1 Department of Physics, Faculty of Science, University of Zagreb, Croatia

2 Chair for Psychology, Faculty of Humanities and Social Sciences, University of Split, Croatia

3 Laboratory for Psycholinguistic Research, Department of Speech and Language Pathology, University

of Zagreb, Croatia

e-mail: ana@phy.hr

Physics is an experimental science and measurements are central to evaluation and formulation of

ideas about the physical world. Assessing the reliability and validity of the measurements is essential

part of measurement. However, physics education researchers have identified a number of student

difficulties in understanding measurements and related uncertainty. Previous research has indicated

that the graphical representations of data might help students in data processing and data compari-

son but this was not systematically explored. In this study, a paper and pencil test consisting of eight

questions and six corresponding explanations was administered to 48 first year students without la-

boratory experience and 53 senior years students at University of Zagreb who were all prospective

physics teachers. In half of the tests, graphical representation of data was also provided. In addition,

eye movements of 30 senior years students were recorded while they were solving the same test.

Overall, many students were unable to appropriately use the idea of measurement uncertainty. They

exhibited the most difficulties while solving the test item that involved recognition of an outlier and

its exclusion in calculation of the mean value. Comparison of measurement results was also very diffi-

cult for many students. In contrast to these items, most students were able to write down the results

of measurements including measurement uncertainty with the correct number of significant figures.

As it was expected, older students generally performed better than first year students indicating that

laboratory experience had a positive effect on student understanding of measurement uncertainty.

Furthermore, graphical representation of measurement data helped students to perform better on

test. Eye tracking data confirmed this finding and provided further insight into student strategies in

data processing.

36





18. University Students on Incompatibility of Observables in Quantum Mechanics

Giacomo Zuccarini, Marisa Michelini

Physics Education Research Unit, University of Udine, Italy

e-mail: giacomo.zuccarini@gmail.com

Conceptual change from a classical to a quantum perspective is a challenging task for university phys-

ics students. The interpretation of the physical behavior of micro-systems requires the adoption of



new basic concepts such as incompatibility of observables, whose construction is non-intuitive, and

implies the re-definition of familiar notions such as the state of a system. In turn, the structure of

these new features is encoded in a highly mathematical formalism, which requires as well making



physical meaning of new entities (e.g. the operator structure of observables) and the re-

interpretation of familiar ones. Research evidences that students have difficulty both with concepts

and with the use of formalism in qualitative tasks, but incompatibility in its many facets received little

attention in literature. We administered a 15-item questionnaire focused on this topic and related

formal structures to 40 physics students of three Italian universities. Semi-structured interviews were

scheduled on a subset of students. Results concerning translation processes between math and physi-

cal meaning show that most students only look at the square modulus in order to reason on physical

information encoded in quantum state, thus neglecting phase relations and their connection with in-

compatibility.

37





WORKSHOPS

1. Simple experiments for enhancement of pupils’ curiosity about science

Dagmara Sokolowska, Daniel Dziob, Justyna Nowak, Aleksandra Wańczyk, Mateusz Wojtaszek, Witold

Zawadzki, Grzegorz Brzezinka



2. Hands-on experiments with hydrogels

Jerneja Pavlin

38





1. Simple experiments for enhancement of pupils’ curiosity about science

Dagmara Sokolowska1,2, Daniel Dziob1, Justyna Nowak1, Aleksandra Wańczyk1, Mateusz Wojtaszek1,2,

Witold Zawadzki1,2, Grzegorz Brzezinka1,2

1Smoluchowski Institute of Physics, Jagiellonian University, Krakow, Poland

2Foundation the Academy of Young Explorers, Krakow, Poland

e-mail: ufdsokol@cyf-kr.edu.pl

The research results show that positive attitude towards mathematics, science and technology school

subjects decreases with age and recently it has been indicated that the biggest drop takes place

between ages 8 and 11 (Sokolowska et al., 2014). At the same time the evidences have been collected

to conclude that more effort is needed at early stages of schooling for implementation of group

work, more practical activities and tasks enhancing the analytical thinking (e.g. de Meyere et al.,

2014). On the other hand our experience from a bunch of open events, reveals an enormous increa-

se of children’s interest in all kinds of popular science for the last few years.

This strong children’s motivation towards experimentation and interest in scientific knowledge gat-

hered from different resources encouraged us eight years ago to start a new national competition in

science for primary school (Sokolowska, 2009). The idea was to engage children aged 6-13, together

with their parents and/or teachers in guided science hands-on and minds-on activities at school or at

home. The key role in the competition is played by simple experiments, based on everyday materials.

The experimental part is then followed by a multiple-choice test, examining their mathematical and

scientific thinking and knowledge.

This workshop is organized to engage the participants in a collection of simple experiments we have

designed for six grades of primary school for the last seven runs of the contest. The idea of the wor-

kshop is to share good examples of hands-on simple activities and to exchange similar experience

among the audience.

Acknowledgement

This work is partially supported by the Akademickie Centrum Kreatywności research project funded by the Po-

lish Ministry of Science and Higher Education within Innovative Economy Programme, action POIG.01.01.03-00

-001/08, which received funding from the European Union under European Structural Funds (2007-2013).

References:

de Meyere, J., Sokolowska, D., Folmer, E., Rovsek, B. and Peeters, W. (2014). MST curricula for 5, 8, 11 and 13 year olds

researched by SECURE project across the Europe. Proceedings of the Irish Association for Social, Scientific and Enviromen-

tal Education, Annual Conference 2013, Dublin 20-21 June 2013, pp.89-106. Retrieved from: http://www.tara.tcd.ie/

bitstream/handle/2262/69112/IASSEE%20Final%20Report-2.pdf?sequence=1

Sokolowska, D. (2009). Firefly – a new contest in science for primary school, Proceedings of

GIREP-EPEC & PHEC 2009 International Conference, August 17-21, Leicester, UK, pp. 352-357. Retrieved from: http://

physics.le.ac.uk/girep2009/ConferenceProceedings/GIREP2009_ConferenceProceedings_Volume1.pdf

Sokolowska D., de Meyere J., van Graf M., Rovsek B., and Peeters W. (2014). Intended, implemented and attained curricu-

la across Europe: what can research tell us?, Proceedings of the ESERA 2013 Conference, Strand 10. Science curriculum

and educational policy, pp. 150-161. Retrieved from: http://www.esera.org/media/eBook_2013/strand%2010/

Dagmara_Sokolowska_07Feb2014a.pdf

39





2. Hands-on experiments with hydrogels

Jerneja Pavlin

Faculty of Education, University of Ljubljana, Slovenia

e-mail: jerneja.pavlin@pef.uni-lj.si

Hydrogels are superabsorbent polymers which are topic of ongoing researches of modern materials.

They are used in agriculture, construction and horticulture industry as well as in medicine. Hydrogels

are also interesting from the educational point of view since they present the novel smart materials

with special properties. Especially hydrogels in spherical shape are very useful for school experi-

ments. Students can study time dependence of the volume of hydrogels and observe the swelling un-

der the USB microscope (Figure 1), play with their size and determine densities, explore that all trans-

parent object cannot be seen in the transparent liquids, experience that materials can change the

properties of light (Figure 2), measure and record the size of the image seen under the hydrogel

sphere, study the influence of media’s properties on swelling, etc. All these experiments, showing hy-

drogels’ special properties and some physics concepts, will be presented during the workshop. You

will experience that presented experiments can give ideas for more hands-on activities, so there will

be also time to try some of them.



Figure 1. Hydrogel in spherical shape immersed in water and observed under the USB microscope.



Figure 2. Directing the green laser beam to the spherical hydrogel in coloured water.



40





POSTER CONTRIBUTIONS

1. The pedagogical treatments of weight and weightlessness in physics textbooks for primary scho-

ol in Bosnia and Herzegovina: An analysis of coherence between curriculum elements and textbook

contents

Jasmina Baluković, Josip Sliško

2. Physics and art in education: The two project ideas from Bosanska Krupa High School

Amna Dervišagić

3. Respiratory system - at the crossroads of physics and biology

Daniel Dziob, Justyna Nowak, Aleksandra Dejko, Bogdan Łabędź, Dagmara Sokolowska

4. An initial study of the transfer of knowledge through two-stage predict-observe-explain se-

quence: the case of floating bodies with fixed and changable volume

Matej Forjan, Josip Sliško

5. Student`s findings at solving young physicist tournament`s challenge - Thick lens

Lucia Mišianiková, Marián Kireš

6. Students' misconceptions of heat and temperature concepts

Maksuda Muratović

7. Firefly – not only a contest in science

Justyna Nowak, Daniel Dziob, Aleksandra Wanczyk, Bogdan Łabędź, Mateusz Wojtaszek, Dagmara

Sokolowska

8. High school students' knowledge and understanding of the phenomena associated with atmos-

pheric pressure

Džana Salibašić, Zalkida Hadžibegović

9. How to observe electric current and resistance?

Katarina Susman, David Rihtaršič

10. ‘Tea with MrBernoulii’, in other words Physics in Inquiry-Based Science Education (IBSE)

Aleksandra Wanczyk, Bogdan Łabędź, Daniel Dziob, Justyna Nowak, Mateusz Wojtaszek, Dagmara

Sokolowska





41





1. The pedagogical treatments of weight and weightlessness in physics textbooks for pri-

mary school in Bosnia and Herzegovina: An analysis of coherence between curriculum ele-

ments and textbook contents

Jasmina Baluković1, Josip Sliško2

1Faculty of Science, University of Sarajevo, Sarajevo, Bosnia and Herzegovina

2Facultad de Ciencias Físico Matemáticas, Benemérita Universidad Autónoma de Puebla, Puebla, México

E-mail: jasminabalukovic@yahoo.com

Since the first human cosmic flights, more than 50 years ago, unusual physical phenomena related to

“weightlessness” called for a revision of the concept of weight. It was vividly discussed in pedagogical

literature and two main conceptual approaches were proposed and used in physics textbooks.

In one approach, the weight of a body is equal to the gravitational force of the Earth (or other planet)

acting on it. A body inside a satellite behaves as “apparently weightless” because the Earth still

attracts it gravitationally. A body would be “truly weightless” would happen in the absence of any

gravitational force acting on it. In the other approach, the weight of body is equal the force the body

executes on a spring scale. Inside a satellite, a body is “truly weightless” because it is unable to exe-

cute a force on a spring scale due to the fact that both are in free fall toward the Earth.

In all analyzed physics textbooks for primary school, published recently in Bosnia and Herzegovina,

the Earthś gravitational force on a body and its weight are conceptually distinguished. The second is

defined as a pressing force a body executes on the horizontal supporting surface or stretching force it

executes on a spring it is hanged on.

Regarding the coherence between physics curriculum for the eight grade and the contents of the cor-

responding textbooks, we report two facts. In the Serb Republic (Republika Srska), state of weight-

lessness is defined in the curriculum as the state in which gravitational forces are totally absent. Sur-

prisingly, the author of singular analyzed textbook does not mention that type of weightlessness and

exposes only free-fall weightlessness.

In the case of the other political part of Bosnia and Herzegovina (Federacija Bosna i Hercegovina), au-

thors don’t respect the curriculum suggestion that students should “describe and explain the state of

weightlessness”. The treatments of weightlessness are mainly verbal, superficial and, in some cases,

conceptually misleading or explicitly wrong (astronauts in space are weightless because there is no

gravitational force).

It seems that the conceptual treatments of weight and weightlessness in physics textbooks in Bosnia

and Herzegovina follow Soviet pedagogical tradition, a phenomenon that was recently analyzed for

the case of physics textbooks in Croatia.

42





2. Physics and art in education: The two project ideas from Bosanska Krupa High

School

Amna Dervišagić

Bosanska Krupa Highs School, Bosnia and Herzegovina

E-mail: amna3x8@yahoo.com

High school students from Bosanska Krupa, a small town in Bosnia and Herzegovina, were able to

make a connection between physics and art. In this paper are presented the two project ideas,

„Physics on photograph", and "The Nailpolish Art" along with many other activities that helped stu-

dents in various ways to be more interested in learning physics as active learners. As they went on

photographing everyday occurrences in nature, they discovered laws of optics and as such, learned

the basic concepts in that field of science. During this project the talented students were taking the

pictures with simple cameras and showed their logical observation of things around them. As a proof

of their excellent job is a picture that „The Physics Teacher“ has published it in its volume 52(5), 2014.

This incredible shot shows the waterfall freezing from outside with an enormous ice pillar formed

from the cascading waterfall during an exceptionally cold Bosnian winter time. In the second project

the students were introduced to learn about water surface phenomena and the risks that nailpolish

can pose to the human health. They have also learned to view science as art, and art as science

through the accidental painting of a famous painter Jackson Pollock. These implemented projects ac-

cording to the basic idea to connect physics as an exact science and art as a different human disci-

pline show that the two fields should be included in the high school physics' curriculum. It means that

high school students can be oriented into human disciplines and social work fields to promote physics

as more attractive science to be learned by young people. They could discover places and events

around them of parallel significance for both physics and art.

43





3. Respiratory system - at the crossroads of physics and biology

Daniel Dziob, Justyna Nowak, Aleksandra Dejko, Bogdan Łabędź, Dagmara Sokolowska

Smoluchowski Institute of Physics, Jagiellonian University, Krakow, Poland

e-mail: daniel.dziob@uj.edu.pl

In many educational systems the science disciplines, like physics, chemistry and biology, are taught as

one interdisciplinary subject, called science, integrated science or world orientation. The main pur-

poses of such approach are to show the relationships between different science disciplines, and to

promote the idea of science integrity and complementarity.

The main objective of this work was to demonstrate the possibility of taking advantage of the inter-

disciplinary character of biophysics for teaching science at various levels of education. To this end, we

have designed a learning unit, based on some experiments, which enables modelling of the selected

vital functions and learning of some concepts, associated with the respiratory system. The underlying

themes and the difficulty levels of the tasks were adjusted so as to suit a variety of age groups, rang-

ing from preschool to higher education.

The proposed learning unit is divided into three main sections to be utilized in a sequence. In the first

section students are familiarized with the expansion and contraction of lungs and the role of midriff.

They are asked to prepare their own model of lungs and to play with it in order to be able to fill in the

tasks in a worksheet. This part can be implemented at each educational stage. The second section

focuses on the lung volume and experimental determination of the maximum vital capacity of lungs

[1]. In the course of the activities students are asked to find out the capacity of their own lungs. Due

to the necessity of mathematical calculations, this part can be useful for teaching science or physics in

higher grades. Last section is linked to the maximum expiratory pressure and to the calculation of this

quantity done by utilizing the ideal gas law [2].

All experiments can be conducted with common, everyday objects, so the learners do not need any

special equipment. The theoretical and mathematical background is provided in the worksheets,

which contain also instructions for performing experiments. Hit her to respiratory system experi-

ments were conducted on lessons in schools and during the events popularizing science, e.g. Re-

searchers' Night.



Acknowledgment

This work is supported by the Akademickie Centrum Kreatywności research project funded by the Polish Minis-

try of Science and Higher Education within Innovative Economy Programme, action POIG.01.01.03-00-

001/08,which received funding from the European Union under European Structural Funds.



References

[1] http://humanphysiology.hubpages.com/hub/Lung-Volumes-and-Capacities

[2] S. Wilson et al, Predicted normal values for maximal respiratory pressures in Caucasian adults and children,

Thorax 1984; 39: p. 535-538

44





4. An initial study of the transfer of knowledge through two-stage predict-observe-

explain sequence: the case of floating bodies with fixed and changable volume

Matej Forjan1, Josip Sliško2

1Šolski center Novo mesto, Novo mesto, Slovenija

2Facultad de Ciencias Físico Matemáticas, Benemérita Universidad Autónoma de Puebla, Puebla,

México

E-mail: matej.forjan@siol.net

One of the key objectives of physics education is that students are able to apply the physics

knowledge in situations that are different from those in which the knowledge was gained. We present

the results of an initial study in which we investigated the transfer of knowledge through the use of

predict-observe-explain method in the case of the floating behaviour of two similar systems: an inflat-

ed balloon with changeable volume and a glass sphere with fixed volume. The balloon is connected

with a metal weight, making possible that it floats in the water, touching the water surface from be-

low. The glass sphere floats the same way.

One group of high-school students (N = 50) had the task to predict what will happen to the balloon

when pushed down a bit by a glass rod. Then they watch a short video clip that shows what actually

happens and finally explain the observed events. The entire process is then repeated, asking students

to predict and describe the behaviour of the glass sphere after being pushed down. Another group of

students (N=50) did the same, only the predict-observe-explain method was first used for the case of

glass sphere, and then for the case of the balloon.

Comparison of the performances of the two groups shows the effect of treatment order of similar

systems on the predictions and the search for the causes of their different behaviour. From the stu-

dents' responses, we conclude that there are two type of students transfer performances. In the first,

more frequent type, students make a superficial transfer of knowledge from the first to the second

situation because of their apparent similarities. That cognitive behaviour might be called a »fast gen-

eralization«. In the second, less frequent type of the knowledge transfer, the students make deeper

physical analysis, that includes taking into account the specificity of the described system.

45





5. Student`s findings at solving young physicist tournament`s challenge - Thick lens

Lucia Mišianiková, Marián Kireš

Division of Didactics of Physics, Institute of Physics Faculty of Science P.J. Šafárik, University of Košice,

Slovakia

e-mail: lucia.misianikova@student.upjs.sk

The Young Physicists Tournament is upper secondary school student`s competition in solving physical

problems that leads talented students to independent and creative scientific activity. Students solve

open-ended problems not only theoretically, but also experimentally. It broadens not only their

knowledge but also a series of scientific skills, like formulate the problem, making predictions, plan

own investigation, collecting data, making conclusions, present and argue own results. In the contri-

bution there is presented an exemplary solution one of selected challenge from year 2015 - Thick

lens. The activity is considered as bounded inquiry. The problem assignment is stated: “A bottle filled

with a liquid can work as a lens. Can one use such a lens to scorch a surface?” By mentoring the team

of high school students we investigate and explain the principles of thick lens and influencing of

appropriate parameters such as thickness, shape, colour and final temperature at the focus point.

46





6. Students' misconceptions of heat and temperature concepts

Maksuda Muratović1,2

1High school Živinice, Bosnia and Herzegovina

2Department of Physics, Faculty of Science, University of Tuzla, Bosnia and Herzegovina

e-mail: maxymuratovic@hotmail.com

Studies focusing on teaching of science concepts show that students are unable to learn the scientific

meaning of the target concepts while they are constructing newly acquired knowledge with their pri-

or experiences during or after teaching and as a result misconceptions emerge. In this paper we used

the concept test Introductory Thermal Concept Evaluation, developed by Shelley Yeo and Marjan

Zadnik of Curtin University in Western Australia. Solving test was approached by 42 students from the

University of Tuzla (Faculty of Science, Department of Physics) and 100 third-grade JU Gimnazija Živi-

nice. The research results show that the understanding of the fundamental concepts of heat and tem-

perature generally low. As for the questions which have proven more difficult, they are most often

been problematic for both groups of which can be seen as well as students have conceptual pro-

blems, but students generally and on each of these tasks are achieved better success. To make the

students gain experience in understanding concepts, conceptual change approach provides a set of

guidelines to help students that provide special learning environment, such as identifying common

misconceptions about heat and temperature, activating students' misconceptions by presenting sim-

ple qualitative examples, presenting descriptive evidence in class that the typical misconceptions are

incorrect, providing a scientifically correct explanation of the situation, and giving students the oppor-

tunity to practise the correct explanation by using questions. Teachers must become more involved in

developing and designing the optimum conceptual change instruction and teachers must be infor-

med about the usage and importance of conceptual change conditions, and they must plan the in-

structional activities according to it.

47





7. Firefly – not only a contest in science

Justyna Nowak, Daniel Dziob, Aleksandra Wanczyk, Bogdan Łabędź,

Mateusz Wojtaszek, Dagmara Sokolowska

Smoluchowski Institute of Physics, Jagiellonian University, Krakow, Poland

e-mail: justynow09@gmail.com

Firefly (Swietlik) is a self-financing competition which is organized in Poland since 2007 by the Aca-

demy of Young Explorers Fundation. This activity is addressed to children aged between 7 and 13 and

is available for all pupils across country. The main goal of Firefly is to show how interesting and fasci-

nating the exact and natural sciences are.

The contest is organized as a multiple choice test, taking place at the same time in the end of March

in all participating schools. A separate test is prepared for each school level. Questions are equally

composed of three categories: (1) biology, chemistry and medicine, (2) ecology, geography and clima-

te, (3) engineering, physics and astronomy. Before the test the pupils are encouraged to perform a

set of simple hands-on experiments selected for the competition each year. Children do them at

school during classes or individually at home at any convenient time before the test.

In first edition of Firefly a number of 4664 pupils from 245 schools took part in the contest. After se-

ven years the number raised to 29 000 pupils from 715 schools.

In our presentation we will show the results from several runs, including analysis of the data derived

from some multiple-choice tasks on physics and the conclusions drawn on their basis.



Acknowledgment

This work is supported by the Akademickie Centrum Kreatywności research project funded by the Polish Mini-

stry of Science and Higher Education within Innovative Economy Programme, action POIG.01.01.03-00-

001/08,which received funding from the European Union under European Structural Funds.

48





8. High school students' knowledge and understanding of the phenomena associated

with atmospheric pressure

Džana Salibašić, Zalkida Hadžibegović

Faculty of Science, University of Sarajevo, Bosnia and Herzegovina

E-mail: sdzana@hotmail.com

This research study was conducted in the spring of 2012, and it was attended by first-year (N=60) and

third-year (N=34) students of prestigious high school in Canton Sarajevo, Bosnia and Herzegovina. The

purpose of this study was to explore students' knowledge and understanding of the phenomena asso-

ciated with atmospheric pressure. Also, this study investigated students' misconceptions, and wheth-

er there has been any positive change in students' understanding. Questionnaire of eight questions,

that was used as a pretest and posttest, was created by researchers to collect data for quantitative-

qualitative analysis. Between pretest and posttest students attended several active learning sessions,

contained of several in-class experiments and discussions. Students showed inferior results than ex-

pected. Misconceptions and misunderstandings of the phenomena associated with atmospheric pres-

sure were confirmed. Students were not good in providing explanations, and scientifically based argu-

ments were almost never used. On the other hand, the students expressed positive attitude towards

active learning. They noted that active learning should be used in teaching more often. Classes would

be more interesting and processed contents would be more understandable and easier to learn. Re-

sults of this research should encourage physics teachers to introduce changes to the traditional way

of teaching, to adapt their teaching to the needs of society and to enable students to actively partici-

pate in the teaching process.

49





9. How to observe electric current and resistance?

Katarina Susman, David Rihtaršič

Faculty of Education, University of Ljubljana, Ljubljana, Slovenia

E-mail: katarina.susman@pef.uni-lj.si

The electricity is known as a topic that is described as an abstract and difficult to visualize. The con-

cepts such as electrical current, electrical circuits, electrical resistance, voltage and others are com-

monly discussed and explained with the help of hydraulic analogy (canal system, water mills, pumps,

etc.). The above analogies helps to better understanding of the electricity, but only if the students

understand it.

The resistivity is a concept that is most commonly introduced through the Ohm’s law. The resistor(s)

is/are connected in electric circuit, where the current and voltage are measured. Although the resis-

tors are one of the most basic electronic components and have a convenient linear dependence of

the current on the voltage, the resistors are still abstract or “black-box” elements. Students are not

able to observe its properties directly. With ambition to bring the concept of resistance closer to stu-

dents an alternative or supplementary device for visualization of the effects of resistance is presented

in this contribution. The electronic device is used as a detector of the resistance, where the frequency

of the blinking diodes gives us the information of the electrical current. With this device the re-

sistance becomes “visually observable quantity”.

The activities connected to resistance were designed on the basis of active learning strategy, where

we try to encourage students to develop ideas, interdisciplinary integration of knowledge, technical

skills training, teamwork and discovering the basic principles of researching. The role of a teacher us-

ing active learning teaching strategy is particularly challenging. A teacher is expected to guide stu-

dents and provide the tips and information for their work. The building and use of the device allows

creativity and innovation for both: teachers and students.

With ambition to use active learning activities starting in elementary school we will stress out ideas

for activities that can be done with the electronic device which perfectly serves for wide resistance

interval.

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10. ‘Tea with MrBernoulii’, in other words Physics in Inquiry-Based Science Education

(IBSE)

Aleksandra Wanczyk, Bogdan Łabędź, Daniel Dziob, Justyna Nowak, Mateusz Wojtaszek, Dagmara

Sokolowska

Smoluchowski Institute of Physics, Jagiellonian University, Krakow, Poland

E-mail: aleksandradejko@gmail.com

Inquiry-Based Physics Learning is a didactic method which makes students become researchers – they

are encouraged to ask questions, hypothesize, plan investigation, conduct experiments, draw the

conclusions on their own, explore and find the answers to the research questions. Such a method is

particularly effective for engaging and motivating students, including those who do not really like

physics.

We have organized the inquiry-based physics workshops on pressure and the principles of Bernoulli’s

law. Target group consisted of (1) the first- and second-year students studying subjects other than

exact or natural sciences and (2) lower secondary school learners undergoing reclamation due to the

problems with the law violation. During an one-hour workshop the entire cycle of IBSE has been im-

plemented. At the end of the session the group used their new knowledge to solve a new task, name-

ly to prepare the tea utilizing the Bernoulli’s law.

The activity was particularly successful with engagement of lower secondary learners who started the

workshop with deep reservation and finished it with elevated self-confidence and being enthusiastic

about physics.



Acknowledgment

This work is supported by the Akademickie Centrum Kreatywności research project funded by the Polish Minis-

try of Science and Higher Education within Innovative Economy Programme, action POIG.01.01.03-00-

001/08,which received funding from the European Union under European Structural Funds.

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NOTES





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