Misconception of sound and conceptual change: A cross‐sectional study on students' materialistic thinking of sound

Eshach, Haim; Lin, Tzu-Chiang; Tsai, Chin Chung

doi:10.1002/tea.21435

Cited by 36 publications

(41 citation statements)

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“…To cope with the limitations of multiple-choice tests, a multiple-tiers test was developed in various recent studies. Energy and momentums (Dalaklioğlu & Sekercioğlu, 2015) Fluid static (Kusairi et al, 2017) Impulse and momentums (Soeharto, 2016;Samsudin et al, 2015) Temperature and heat (Madu & Orji, 2015;Asri et al, 2017) Sport physics (Kartiko, 2018) Energy and force (Nwafor et al, 2015) Newtons' Law (Ergin, 2016) Electric circuits (Sadler & Sonnert, 2016) Gases (Çetin et al, 2009) Physical concept (Wind & Gale,2015) Heat transfer (Wibowo et al, 2016) Thermal physics (Malik et al, 2019) Moon phase (Saenpuk & Ruangsuwan, 2019) Energy material (Wijayanti et al, 2018) Light (Wartono & Putirulan, 2018) Heat concept (Haryono, 2018) Solid matter and pressure liquid substances (Handhika et al, 2018) Sound (Eshach et al, 2018) Hydrostatic pressure and Archimedes law (Berek et al, 2016) Chemistry Municipal chemistry (Milenković et al, 2016b) Chemical bonding (Vrabec & Proksǎ, 2016;Enawaty & Sartika, 2015) Enzyme Interacts (Linenberger & Bretz, 2015) Chemical bonding and spontaneity (Ikenna, 2015) Electrochemistry (Önder, 2017) Acid-base (Sadhu et al, 2017;Sadhu, 2019) Acid-base and solubility equilibrium. (Masykuri & Rahardjo, 2018) Biology Photosynthesis (Orbanić et al, 2016) Evolution of biology (Putri et al, 2017;Helmi et al, 2019) Natural science (Subayani, 2016;Murti & Aminah, 2019) Global warming (Fajarini et al, 2018) Ecology…”

Section: Simple Multiple-choice Testmentioning

confidence: 99%

“…Because of that matter, some researches had been held to provide information about student understanding, especially in learning science concepts. The different insight of student concepts had been defined by a number of terms like "alternative conceptions" (Wandersee et al, 1994), "conceptual difficulties" (Stefanidou et al, 2019), "misconceptions " (Eshach et al, 2018), "mental models" (Wuellner et al, 2017), and others.…”

Section: Introductionmentioning

confidence: 99%

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A Review of Students’ Common Misconceptions in Science and Their Diagnostic Assessment Tools

Soeharto

CsapÃ

Sarimanah

et al. 2019

JPII

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Section: Simple Multiple-choice Testmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A Review of Students’ Common Misconceptions in Science and Their Diagnostic Assessment Tools

Soeharto

CsapÃ

Sarimanah

et al. 2019

JPII

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“…Thus, even if students start viewing a certain phenomenon as a process, it is the wrong process mechanism that they have in mind. For instance, in a series of studies on sound [6,21,22], Eshach showed that students attribute materialistic characteristics to sound, and even if they view sound as a process of propagation from one place to another, they still view this process as a direct one (e.g., as a kind of substance that is being pushed and moved from a sound source to a listener). They do not see sound as an emergent process resulting from random collisions between a medium's particles.…”

Section: The Ontological Shift Approachmentioning

confidence: 99%

“…Indeed, many researchers show that learners "…face obstacles in mapping abstract, theoretical understanding of thermodynamic principles" [26] (p. 704). One of the barriers students may face stem from their materialistic thinking, which is defined by Eshach et al [22] as their tendency to associate materialistic properties to scientific concepts. Indeed, Reiner et al [12] and Chi [1,3] argue that naïve students tend to assign heat to the entities category, and thus explain phenomena related to heat in terms of matter and the characteristics they attribute to matter.…”

Section: Pedagogical Example Of Teaching About the Heat Transfer Pmentioning

confidence: 99%

Introducing the idea of entropy to the ontological category shift theory for conceptual change: The case of heat and sound

Volfson

Eshach

Ben-Abu

2019

Phys. Rev. Phys. Educ. Res.

Self Cite

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In the present theoretical study, we introduce the entropy concept into Chi's ontological shift theory. Chi distinguishes between two categories of process phenomena, direct and emergent, and claims that incorrectly considering emergent processes as direct ones is one of the sources of students' robust scientific misconceptions. The present study aims to address the needs of high school and undergraduate physics, chemistry, and engineering students being already familiar with the basics of mechanics and the kinetic molecular theory. Acknowledging the contribution of the ontological shift category theory to improving the learning of science, the present paper aims at taking this theory one step further. We argue that more information about scientific phenomena could be gained if we view direct and emergent phenomena as edges of the same scale level of emergency. We show that entropy can be used to evaluate the level of emergency of physical processes. We believe that interpreting scientific phenomena in terms of level of emergency and entropy might promote students' understanding about the underlying mechanisms explaining these phenomena, as well as about the concept of entropy itself. We provide two pedagogical examples of teaching heat and sound using the level of emergency scale and the entropy concept. We demonstrate analytically in these terms: (a) the development of the heat flow rate equation; and (b) the adiabatic nature of the sound propagation process.

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“…There are multifaceted reasons behind this phenomenon, and one of which is the difficulty of forming a conceptual change from learners' prior understanding. Similar to learning scientific concepts such as sound, pressure, balance and so on (Eshach, Lin, & Tsai, 2018;Ozkan & Selcuk, 2016), learners need to move from an everyday concept to a scientific one. In many cases, the intended conceptual change happens, but others form a misconception (alternative concept), and some maintain their intact preconception.…”

Section: Concept Formation Of Scientific Modelsmentioning

confidence: 99%

Students’and Teachers’ Perception of Scientific Models: Transition From Daily to Scientific Language

Lee¹,

Lien

2019

JBSE

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The use of scientific models has been regarded as an important skill for scientific enquiry. However, although many national curricula and major international science education reform movements have stressed the use of scientific models in science teaching and learning, students and teachers generally do not know how to perceive models properly. This research explores these perceptions about scientific models using the Perception of Models in Science (PMS), a self-developed instrument designed to collect participants’ model perceptions, among 218 grade 4, 6 and 8 students, as including 57 of the science teachers in their respective schools, and treated these statistically with analysis of variance, post hoc analysis and cluster analysis. Results showed that the groups of students and teachers agreed that the most acceptable model representation is reality but remained uncertain on whether a model can be presented through nonreality representations (i.e., diagram, graph, symbol, writing and speech). Participants did not significantly differ in perception intensity of seeing each model representation and held three kinds of model perceptions: daily language, transitional and scientific language. This research thus proposes action plans in managing this transitional perspective in learning the concepts of scientific models. Keywords: model representations, scientific model, students’ view, teachers’ view

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Misconception of sound and conceptual change: A cross‐sectional study on students' materialistic thinking of sound

Cited by 36 publications

References 50 publications

A Review of Students’ Common Misconceptions in Science and Their Diagnostic Assessment Tools

A Review of Students’ Common Misconceptions in Science and Their Diagnostic Assessment Tools

Introducing the idea of entropy to the ontological category shift theory for conceptual change: The case of heat and sound

Students’and Teachers’ Perception of Scientific Models: Transition From Daily to Scientific Language

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