High School Students’ Proficiency and Confidence Levels in Displaying Their Understanding of Basic Electrolysis Concepts

Sia, Ding Teng; Treagust, David F.; Chandrasegaran, A. L.

doi:10.1007/s10763-012-9338-z

Cited by 23 publications

(26 citation statements)

References 32 publications

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“…In terms of the reasoning element, Table 1 shows that the element is mainly used at the macro-level (58.52% in individual argumentation and 40% in group argumentation). This shows that students could only construct simple arguments and lacked the ability to provide explanations at the sub-micro and symbolic levels, which is in line with the conclusions made by Dawson and Venville (2009), Heng et al (2012) and Sia, Treagust and Chandrasegaran (2012). This may be due to the low exposure to different levels of representations in science classes, causing students to learn chemistry concepts at the three levels separately and in a discrete manner (Treagust, Chittleborough & Mamiala, 2003).…”

Section: Scientifi C Argumentation Elements Constructed By Students Esupporting

confidence: 77%

Mastery of Scientific Argumentation on the Concept of Neutralization in Chemistry: A Malaysian Perspective

Heng

Surif

Seng

et al. 2015

MJLI

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Purpose-Argumentative practices are central to science education, and have recently been emphasised to promote students' reasoning skills and to develop student's understanding of scientifi c concepts. This study examines the mastery of scientifi c argumentation, based on the concept of neutralisation, among secondary level science students, when engaged in individual and group argumentations. Methodology-356 form four science students were fi rst randomly assigned to an argumentative condition, after their lesson on acids and bases, presented using the developed instructional materials. Each individual or group was then asked to answer an Open-ended Scientifi c Argumentation Test (OSAT). Discussions during group argumentations were observed and recorded. All the answers provided in the OSAT were then analysed based on their accuracy, the triplet relationship in chemistry and for the presence of argumentation elements. Observations from the group argumentations were transcribed and assessed. Findings-The results show that in both argumentative conditions, most of the arguments constructed tend to consist of the elements of claim and evidence. The results also show that students who work in groups outperform students who work individually. As individuals, most of the arguments presented tend to be simple with reasoning Signifi cance-The study implies that group argumentation enhances students' argumentation and reasoning skills and improves their mastery of scientifi c concepts. In addition, this study also investigates students' performance from the Malaysian perspective.

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Section: Scientifi C Argumentation Elements Constructed By Students Esupporting

confidence: 77%

Mastery of Scientific Argumentation on the Concept of Neutralization in Chemistry: A Malaysian Perspective

Heng

Surif

Seng

et al. 2015

MJLI

View full text Add to dashboard Cite

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“…2011 Rahayu et al [19] Indonesian and Japanese senior high-school students' understanding of: (a) reactions occurring during electrolysis; (b) differences between electrolytic and voltaic (galvanic) cells; (c) movement of ions in electrolytic cells; (d) poles in electrolytic cells; (e) electrolytic cell reactions. 2012 Sia, Treagust and Chandrasegaran [20] Students' understanding of 19 major principles of electrolysis.…”

Section: Introductionmentioning

confidence: 99%

“…Using a two-tier multiple-choice diagnostic instrument, Sia, Treagust and Chandrasegaran conducted a study with 10 thgrade students, with the focus on student understanding of 19 major principles of electrolysis. [20] It was reported that the students displayed limited understanding of the electrolytic processes involving molten compounds and aqueous solutions of compounds. Although the students were found to possess relevant content knowledge, they could not provide suitable explanations for the changes that had occurred.…”

Section: Introductionmentioning

confidence: 99%

Teaching and Learning Electrochemistry

Tsaparlis

2018

Israel Journal of Chemistry

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Numerous conceptual difficulties and misconceptions have been reported in the science and chemistry education literature about electrochemistry concepts such as electrolytes, redox equations, and about electrochemical (galvanic and electrolytic) cells. Other studies have considered teaching approaches aimed at improving learning and at overcoming misconceptions. This paper reviews these studies and considers strategies and approaches for the effective teaching of electrochemistry. Then, the review focuses on problem solving in equilibrium electrochemistry, especially problems involving the Nernst equation. The main findings of four studies with Greek university chemistry students, dealing with: (i) algorithmic problem-solving ability; (ii) practice on problem solving; (iii) the effect of the format of a problem; and (iv) the construction and evaluation of a website devoted to electrochemistry problem solving, are reported.

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“…To overcome the limitations of multiple-choice tests, and the challenges of using tools such as interviews and open-ended questions, science educators have developed a new model of assessment called two-tier tests (Haslam & Treagust, 1987;Hudson & Treagust, 2013;Odom & Barrow, 1995;Sia, Treagust, & Chandrasegaran, 2012;Tamir, 1989;Tan et al, 2002;Treagust, 1986;Voska & Heikkinen, 2000;Wandersee, 1983). These types of assessments are advantageous because they ensure the reliability and efficiency of multiple-choice assessments, as well as the capability to diagnose student understanding and reasoning at a deeper level.…”

Section: Introductionmentioning

confidence: 99%

Exploring Pre-Service Elementary Science Teachers’ Conceptual Understanding of Particulate Nature of Matter through Three-Tier Diagnostic Test

Aydeniz¹,

Bilican²,

Kırbulut³

2017

International Journal of Education in Mathematics, Science and Technology

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The purpose of this study was to explore Pre-service Elementary Science Teachers" (PSTs) conceptual understanding of Particulate Nature of Matter (PNM) through a three-tier diagnostic test. Participants were 215 PSTs from Turkey. Data consisted of participants" responses to the Particulate Nature of Matter Test (PNMT). The PNMT consists of three-tier items. Students were asked to choose the correct choice in the first tier, and then to justify their choice of the answer provided in the second tier. Finally, they were asked to indicate the confidence level of their responses in the third tier. Results showed that the PSTs were not competent in their understanding of the PNM concepts. Moreover, some had strongly held misconceptions. Finally, the PSTs struggled to provide coherent answers to the items on the PNMT across three tiers.

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High School Students’ Proficiency and Confidence Levels in Displaying Their Understanding of Basic Electrolysis Concepts

Cited by 23 publications

References 32 publications

Mastery of Scientific Argumentation on the Concept of Neutralization in Chemistry: A Malaysian Perspective

Mastery of Scientific Argumentation on the Concept of Neutralization in Chemistry: A Malaysian Perspective

Teaching and Learning Electrochemistry

Exploring Pre-Service Elementary Science Teachers’ Conceptual Understanding of Particulate Nature of Matter through Three-Tier Diagnostic Test

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