This study aimed to develop the sma

This study aimed to develop the small-scale experiments involving electrochemistry and the galvanic
cell model kit featuring the sub-microscopic level. The small-scale experiments in conjunction with the
model kit were implemented based on the 5E inquiry learning approach to enhance students’
conceptual understanding of electrochemistry. The research tools consisted of (1) four small-scale
experiments involving electrochemistry, which were oxidation and reduction reactions, galvanic cells,
cathodic protection of iron nails, and connecting batteries in series, and (2) the galvanic cell model kit
with the ability to generate various galvanic cells. The data collecting tools included (1) a conceptual test
of electrochemistry and (2) the mental model drawing of a galvanic cell. Thirty-four grade 12 students
participated in the series of four 5E learning activities for a total of 10 hours. Paired samples T-test
analysis revealed that the mean scores of the post-conceptual test (mean 36.63, SD 7.69) was
statistically higher than that of the pre-conceptual test (mean 21.51, SD 6.83) at the significance level
of 0.05. In addition, the mean scores of the post-mental models in both the macroscopic (mean 3.56,
SD 1.30) and sub-microscopic features (mean 5.98, SD 2.93) were statistically higher than those of the
pre-mental models (mean 1.85, SD 1.11 and mean 2.20, SD 2.45) at the significance level of 0.05. Prior
to intervention, most students were in the categories of less correct conceptions, Partial Understanding
with Specific Misunderstanding (PMU) to No Understanding (NU). However, after the intervention, they moved
to the categories of more correct conceptions, Partial Understanding (PU) to Sound Understanding (SU).
This indicated that this intervention can enhance students’ conceptual understanding of electrochemistry
and mental models of galvanic cells.