Patterns of physics problem-solving among secondary school students – a metacognitive perspective
Recent work suggests that metacognitive skills play a vital role in problem-sol ving. Yet, there are only a few studies looking specifically into the role of metaco gnitive skills in Physics problem-solving, especially among the secondary school students....
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| Main Author: | |
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| Format: | Book Section |
| Language: | English |
| Published: |
The International Centre for Innovation in Education (ICIE)
2009
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| Subjects: | |
| Online Access: | http://eprints.utm.my/id/eprint/14759/1/FatinAliahPhang2009_PatternsofPhysicsProblem-SolvingAmongSecondary.pdf http://eprints.utm.my/id/eprint/14759/ |
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| Institution: | Universiti Teknologi Malaysia |
| Language: | English |
| Summary: | Recent work suggests
that metacognitive skills play
a vital role in problem-sol
ving. Yet, there are only a
few studies looking specifically into the role of metaco
gnitive skills in Physics problem-solving, especially
among the secondary school students. The research discusse
d here is an attempt to investigate the patterns of
Physics problem-solving among Key Stage 4 (14-16 years old) students in Cambridge through the lens of
metacognition using Grounded Theory. In order to match the
students with “real” problems (i.e. that are difficult
for them but solvable), 148 students from 5 schools were given a Physics Problems Test (PhyPT) consists of 6-8
Physics “problems” and followed by 2 questions to measur
e the level of difficulty of each problem. Later, 22
students were selected as theoretical
sample (at different stages of the research) to undergo a session of
individual problem-solving using thinking-aloud and observation by the researcher, followed by retrospective
semi-structured interviews. In order to reach the theoretical saturation point, a few more problems were
constructed to match the level of difficulty and concep
tual understanding of thes
e selected students. The
thinking-aloud was being recorded, transcribed and coded using the constant comparative method of Grounded
Theory. The analysis of the thinking-aloud protocols was supported by the analyses of data from the interviews,
observations using video and analysis of answer sheets. The data analyses further suggested a few hypotheses to
look in detail in order to generate more concrete pattern of Physics problem-solving. The repetition of the
research in different format of prob
lems and cycles of data collection-
analysis produced two problem-solving
patterns among the students. The saturated patterns suggest that students show different approaches when facing
easy questions and difficult problems. The easy-question pattern is quite consistent and “expert-like” while more
metacognitive skills are shown in the difficult-problem patte
rns. Students resort to means-end, trial-and-error and
guessing strategies when facing with difficult problems. While in the easy-questions, the students are more likely
to tell the concept involved and search for equation that is relevant to the questions due to the familiarity of the
students with the questions. This suggests that training in doing particular types of exercise can help students in
answering the questions easily, however, this doesn’t mean that students have good problem-solving skills. In
solving difficult problems, metacognitive skills help studen
ts to understand the proble
ms and check the error by
making sense of the answers obtained. Hence, it is a good practice for students to self-talk while solving a
difficult Physics problem to improve the problem-solving. |
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