This study integrates two instructional designs—“project-based inquiry” and “modeling-based inquiry”—into the “Science Inquiry and Practice” curriculum. The two sets of curricula are divided into two stages. In the first stage, teachers spend three weeks scaffloding students the inquiry or modeling process. In the second stage, students use another three weeks to conduct research for investigating open-ended questions. With the “Science Inquiry and Practice” curriculum listed as a required course stipulated by the Ministry of Education in Taiwan, the College Entrance Examination Center has planned to apply literacy-oriented test questions, which are regarded as a context-focused and scientific methodology, to designing test items for national examnination for university admissions. Another focus is the practical works produced by students in their hands-on courses which will serve as an important portfolio used for their future university application. This research has designed scientifically literacy-oriented tests adapted from the PISA assesement and students’ works of the annual national science exhibitions. It will also explore the differences of students’ scientific literacy before and after the course and analyze students’ learning performance in light of their practical works produced in the course. In addition, this study will compare the extent to which students understand the essence of models and how teachers cultivate students’ modeling capability under the two modes of inquiry, given an increasing emphasis on models and modeling in the field of science education. The results of this study illustrated that the performances of the project-based inquiry group in posttests were far superior to those in pretests with significant differences in these performances. These performances included “overall scores,” “abilities to give a verifiable perspective,” “the search for variables or conditions,” “analysis of data and presentation of evidence,” “ability to draw conclusions or provide solutions,” and “expression and communication.” Applying the Johnson-Neyman procedure to comparing the two groups of inquiry models in the scientific literacy test, this study discovered that in terms of overall scores, argumentation and modeling, as well as expression and sharing items, the project-based inquiry pedagogy were suitable for students with higher levels of achievement in the scientific literacy test. In addition, this study also found that modeling-based inquiry pedagogy were suitable for students with higher levels of achievement in the scientific literacy test. However, after identifying problems and planning and research were analyzed by covariates, this study found that there was no significant distinction between the two groups. In the nature of model questionnaire, the t-test of the modeling-based inquiry group showed that its posttests were better than pretests in terms of the model ontology, cognition and methodology with significant differences among these tests. Based on the questionnaires of the project-based inquiry group carried out by the pre-and-post t-tests, the results showed that the posttests were better than the pretests only in terms of the model ontology, and they reached a significant difference level. However, there is no significant difference in cognitive perspective and methodological perspective. A further analysis of the pre-and-post-test covariates of the two groups revealed that the modeling-based inquiry group outperformed the topic-based inquiry group on model ontological perspective, cognitive perspective, and methodological perspective with significant differences in these three aspects. In the performance of the modeling ability test, Fisher’s accurate test results showed that the two groups of students produced different performances in model selection and model validity, but there was no significant difference in model construction, model use and deployment. Furthermore, students in the modeling-based inquiry group at the higher level (Level 4 and Level 5) outnumbered those in the project-based inquiry group. Therefore, it was apparent that modeling instruction facilitated the modeling ability associated with model selection and model validity. In terms of students’ practical works, students in the modeling-based inquiry group were divided into 8 groups. Among these 8 groups, 2 groups could be able to examine models using scientific theories and apply them to other scenarios. Four groups could be able to build an extended relationship of the model while another 2 groups could be able to form the component relationship of the model. As far as the open-ended questions were concerned, students could select the correct variables ; besides, through hands-on courses, they could find the qualitative relationship among the variables. Nevertheless, there was a large discrepancy between students’ practical works and the models constructed by scientific communities. In addition, students were divided into 8 groups in the project-based inquiry group. 7 groups completed the inquiry works and submitted reports, but 1 group failed to complete the experimental verification. In general, students perform better in “raising questions suitable for scientific inquiry” and “being able to come up with designs that meet research questions,” whereas there is room for growth in “being capable of analyzing data” and “being able to produce and apply charts.”As far as the open-ended questions were concerned, students in the project-based inquiry group could conduct experiments with selecting the correct variables but experience these questions’ complexity and uncertainty. Students feel that this curriculum helps a lot when they design an experiment. Overall, the students had an abundance of learning outcomes and produced practical works under the “project-based inquiry” and “modeling-based inquiry” teaching strategies integrated in the “Science Inquiry and Practice” curriculum. “Project-based inquiry” designs achieved better results when applied to cultivating students’ scientific literacy, while “modeling-based inquiry” was more effective in cultivating students’ concepts of the essence of models and developing their modeling ability. Dealing with the inquiry of open-ended questions, the two groups of students experienced these questions’ complexity and uncertainty. Teachers need to assist students in scaffolding the skills of investigation and prior knowledge of science wherever necessary so that they can instruct students how to overcome the challenge of investigating authentic problems.