The purpose of this study was to investigate how a high school chemistry teacher adopting modeling–based instruction for teaching electrochemistry. The teacher with science education background taught electrochemistry to four classes, two modeling groups (one with modeling and simulation, and the other with modeling and hands-on experiment), and two comparative groups without explicit modeling processes (one with modeling and simulation, and the other with modeling and hands-on experiment). The teacher’s modeling pedagogical content knowledge (M-PCK) was investigated and comparisons of the differences of M-PCK among four groups were analyzed. Three instruments were used, namely, questionnaire (pre, mid, and post), "teaching record table", and “questionnaires for students’ confidence and interest in learning”. The design of these instruments was to capture teacher’s concept of modeling-based teaching, interaction between the teacher and the students, and the processes of instruction. The elements for the processes to be analyzed were pedagogical reasoning, comprehension, transformation, instruction, evaluation, reflection and new comprehension. Finally, using SWOT analysis was applied to compare Modeling Teaching and general teaching, combined with the results of the students' affection. The results of this study revealed that the teacher developed her modeling-based teaching knowledge and practice dynamically and gradually. The teacher's teaching model has theoretical basis and herself with teaching experience. The modeling-based instruction provided explicit explanations about the modeling processes, modeling-based text, modeling teaching materials (e.g. PPT), an open-ended Q & A, systematic writing on the blackboard, video clips of sub-microscopic representations, paper and pencil tests, highlighting the characteristics of modeling teaching. In sum, recommendations and implications about implementation of modeling-based instruction in practice are discussed.