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This research work had been a double objective, to help the students achieve the learning outcomes, scientific skills and on the other hand, to develop specific scientific sub-competences, all of these related not only with the conceptual knowledge but also with the knowledge of procedurals and epistemology.

A didactic sequence has been designed and applied with students of the University Catholique of Louvain (Belgium) in collaboration with teachers from the University of Zaragoza (also researchers in the knowledge areas of Electronics, Applied Physics and the Didactics of Experimental Sciences). Several methodologies were applied thorough the teaching-learning sequence as the flipped classroom is. A varied sample of assessment instruments was used.

The results suggest this sequence produces a more significant learning than a more conventional teaching, however there is no increase in the number of students who passed. The students explaining phenomena scientifically, evaluating and designing experiments and making researchable questions and interpreting data and scientific evidence, which are a consequence of the development of scientific knowledge (content, procedural and epistemic). In addition, the students kept motivated by this methodological change and maintained the perception of having achieved the expected learning according to the objectives of the course.

Until a few years ago, research in the didactics of experimental sciences, and the application in the classroom of the results obtained, was limited to education in non-university stages. The opportunity of this work is to expand knowledge in relation to the application of didactic strategies in physics education at a higher level.

Until relatively recently, science teaching was based on conveying theoretical concepts. Nevertheless, in the last few years we have gradually understood the importance of building mental models that represent scientific reality. Model-based science teaching has been used at a school level with satisfactory results. However, only a few studies have been published so far on science modelling in higher education.

The present thematic review analyses the concept of model in science and the works published in recent years on models in physics education.

Throughout these years, special importance has been given to the acquisition of student learning models. These models can either be introduced in the teaching process or acquired by students in their learning process using specific teaching tools. As a conclusion of this review, the authors say that although such strategies are increasingly used in the teaching of science at a school level, few works delve into the importance of acquiring models in higher education. More specifically, there are few research works published in the context of teaching physics in university courses.

This study review and analyses works published on this issue and aims to provide knowledge as a starting point for future research.