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Recently, various policies have been implemented in Saudi Arabia to reform science teaching at K-12 levels in order to focus on critical thinking, inquiry-based learning, and problem solving. Research is needed to explore the adequacy of teacher preparation programs to determine whether these programs sufficiently prepare Saudi science teachers to teach according to these new reforms. This study explores the challenges that Saudi pre-service science teachers face in these higher education programs. Results indicated that graduates of the programs studied were satisfied with their experiences; however, various concerns were expressed by some pre-service teachers regarding the theory-practice gap between their university coursework and field experiences, and the supervision structures and functions in place for the professional experiences component. Modifications to the teacher preparation programs are suggested in order to address these concerns and to successfully enact reforms in science education in Saudi Arabia.

This study aims to investigate how primary teachers, when taking part in digital didactic design (D³) workshops at the Digital Laboratory Centre at the university, develop their insights about how digital tools can be designed and further used in their teaching of science. The research question addresses how D³ can be used to develop primary teachers’ knowledge about teaching science with digital technologies.

During two semesters, 14 primary science teachers from three different schools participated in an in-service course at the university. Five D³ workshops lasting 4 h each were conducted with the aim to analyze, design and implement digital tools based on the needs of teachers and students. This includes discussions about the technological, pedagogical and content knowledge (TPACK) framework and further recommendations about how to choose, design, implement and evaluate digital tools for different teaching and learning situations. In between the workshops, the teachers were told to reflect on their experiences with colleagues and students and share their ideas and reflections to support collegial learning.

The results indicate that D³ has an opportunity to promote deep learning experiences with a framework that encourages teachers and researchers to study, explore and analyze the applied designs-in-practice, where teachers take part in the design process. This study further indicates that having teachers explicitly articulates their reasoning about designing digital applications to engage students’ learning that seems important for exploring the types of knowledge used in these design practices and reflecting on aspects of their teaching with digital technologies likely to influence their TPACK.

This research indicates that the increasing prevalence of information communication technology offers challenges and opportunities to the teaching and learning of science and to the scientific practice teachers might encounter. It offers solutions by investigating how primary teachers can design their own digital technology to meet students’ science learning needs. One limitation might be that the group of 14 teachers cannot be generalized to represent all teachers. However, this study gives implications for how to work with and for teachers to develop their knowledge of digital technologies in teaching.

As this project shows teachers can take an active part in the digital school development and as such become producer of knowledge and ideas and not only become consumers in the jungle of technical applications that are implemented on a school level. Therefore, it might well be argued that in science teaching, paying more careful attention to how teachers and researchers work together in collaborative settings, offers one way of better valuing science teachers’ professional knowledge of practice. As such, an implication is that digital applications are not made “for” teachers but instead “with” and “by” teachers.

The society puts high demands om teachers’ knowledge and competencies to integrate digital technologies into their daily practices. Building on teachers’ own needs and concerns, this project addresses the challenge for teachers as a community to be better prepared for and meet the societal challenge that digitalization means for schools.

Across the field of science education, knowledge about the relation between teachers’ use of digital technology and how it might (or might not) promote students’ learning offers access to ideas of how to design and implement teacher professional development programs. This offers enhanced communication opportunities between schools and universities regarding school facilities and expectations of technology to improve teachers’ experiences with integrating technology into their learning and teaching. This pragmatic approach to research creates theory and interventions that serve school practice but also produces challenges for design-based researchers.

Research has shown that pre-service and in-service teachers who exhibit science anxiety are less likely to teach it effectively. It is therefore critical to gauge the science anxiety levels of student teachers early while there are still possibilities, perhaps, to prevent serious issues occurring later on as a result. This study takes place in the United Arab Emirates, where Emirati science teachers are already in the vast minority. Since this is the case and teacher attrition rates are high, it is important to offer as much support to student teachers as possible. We surveyed 113 student elementary school teachers to explore their science anxiety levels. Whilst some studies have shown that science anxiety can decrease as students take science content courses, thereby theoretically gaining confidence in science knowledge, this effect was not observed in our study except for a few aspects and only in those who had studied in the ‘science track’ at school. We also found that students educated in arts tracks in high schools had significantly higher science anxiety levels compared with those who followed science tracks.

و ةمدخلا لبق ام يملعم نأ ثوحبلا ترهظأ دق نورهظي نيذلا و ةمدخلا يف نيملعملا نم ً اقلق مولعلا ةدام مه ميلعتل ًﻻامتحإ لقأ قلقلا تايوتسم سايق ةيمهﻷا نمف كلذلو .ةيلاعفب مولعلا ةدام نم مولعلا ةدام ﻻ نيح يف ركبم تقو يف ةمدخلا لبق ام يملعمل ي مبر لامتحا كانه لاز ةيبرعلا تارامﻹا ةلود يف ةساردلا هذه يرجتو .كلذل ةجيتن قحﻻ تقو يف لكاشم يأ ثودح عنمل ا ميدقت مهملا نمف ،ةعفترم نيملعملا صقانت تﻻدعمو لاحلا وه اذه نأ امبو .ةيلقأ مه نييتارامﻹا مولعلا يملعم ثيح ،ةدحتملا مب انمق .ةمدخلا لبق ام يملعمل معدلا نم نكمم ردق ربكأ ﺢس 113 نم مهقلق تايوتسم فاشكتسﻻ ةمدخلا لبق ام يملعم نم مولعلا ةدام قلقلا نأ تاساردلا ضعب ترهظأ نيح يف . نم مولعلا ةدام ضفخني نأ نكمي ىوتحملا تاقاسم ةبلطلاا لامكتسا عم ُي مل ،ةيملعلا ةفرعملا يف ةقثلا باستكا يلاتلابو ،يملعلا َحﻼ ساب انتسارد يف ريثأتلا اذه ظ نيذلا كئلوﻷ طقفو بناوجلا ضعب ءانثت يف ةيبدﻷا و ةينفلا تاراسملا اوذختا نيذلا ةمدخلا لبق ام يملعم نأ اضيأ اندجوو .ةسردملا يف ةيملعلا تاراسملا اوذختا قلقلا تايوتسم مهيدل ناك ةيوناثلا سرادملا نم مولعلا ةدام .ةيملعلا تاراسملا اوعبتا نيذلا كئلوأ نم ريثكب ىلعأ

The state of science education is similar to that of other disciplines: research shows a clear need for new instructional strategies based on a constructivist model of learning emphasizing conceptual growth, conceptual change and the conditions that support conceptual change. Practice, however, remains anchored in behaviorist theory and rote methods of learning. “Serious constructivist approaches usually set out to reorganize traditional teaching by including changes of aims, setup of content structures, media, and teaching/learning strategies” (Treagust et al, 1996, p7). Maher and Alston (1990) discuss constructivist reform efforts and the implications for classroom teaching focusing on three issues that arise repeatedly: how to learn to listen to students’ thinking; how to organize classroom activities to support “listening and questioning”; and how to implement forms of assessment that document students’ questions.

This paper describes some constructivist teaching methodology and practices, and highlights their effectiveness as an aid to teaching and understanding in the classroom.

The lecture method has been compared with teaching methods such as flip learning, cooperative learning and simulations to establish which holds the key to students' understanding of concepts. What is bereft in the education literature is its comparative efficiency with the culturo-techno contextual approach (CTCA) in the teaching of computer science education.

This study adopted the quasi-experimental design to determine the efficacy of the CTCA in breaking difficulties related to the study of spreadsheets as a difficult concept in the Nigerian computer science education curriculum. Junior high school students studying computer science education participated in the study. The control group had 30 students, with 35 students in the experimental group. The experimental group was taught using CTCA, while the control group used the lecture method. The spread sheet achievement test, which had 40 items on spreadsheet, was used to collect data.

The results showed that the experimental group significantly outperformed the control group [F (1,60) = 41.89; p < 0.05]. The findings showed the potential of CTCA in improving students' performance in spreadsheets in the computer science education curriculum.

The originality of this study is hinged on its ground-breaking test of the CTCA to the study of the spreadsheet. The findings of this study indicate its efficacy in improving students' understanding of spreadsheet and computer science education.

Understanding students’ preferences for teaching and course design is important for educators in higher education when planning courses and teaching activities. The purpose of this study was to explore changes in occupational therapy students’ preferences for teaching and courses across the three-year study program.

A total of 263 students participated in a longitudinal study, where preferences were measured with the Approaches and Study Skills Inventory for Students. The data were analyzed with linear mixed effect models for repeated measures.

The results indicated no significant changes in preferences for courses and teaching over the three-year period. Also, there were no significant differences between the six involved study programs. Preferences for the courses and teaching type “supporting understanding” were associated with higher age and higher study effort. Preferences for the courses and teaching type “transmitting information” were associated with lower age and female gender.

In summary, the findings of this study suggest that preferences for teaching and courses are stable and may be challenging to alter during a three-year undergraduate study program.

The purpose of the current study is to assess Omani teachers’ performance on tasks related to the stages of engineering design. To achieve this, data from an engineering design test was used, and demographic variables that are correlated with this performance were identified.

This descriptive study employed a cross-sectional design and the collection of quantitative data. A sample of preservice science teachers from Sultan Qaboos University (SQU) (n = 70) participated in this study.

Findings showed low and moderate levels of proficiency related to the stages of engineering design. Differences between males and females in terms of performance on engineering design tasks were found, with females scoring higher overall on the assessment. Biology preservice teachers scored higher than teachers from the other two majors (physics and chemistry) in two subscales. There were also differences between teachers studying in the Bachelor of Science (BSc) program and the teacher qualification diploma (TQD) program.

This study provides an overview, in an Arab setting, of preservice science teachers’ proficiency with engineering design process (EDP) tasks. It is hoped that the results may lead to improved instruction in science teacher training programs in similar contexts. Additionally, this research demonstrates how EDP competency relates to preservice teacher gender, major and preparation program. Findings from this study will contribute to the growing body of research investigating the strengths and shortcomings of teacher education programs in relation to science, technology, engineering and mathematics (STEM) education.

The authors are developing a model for rural science teacher professional development, building teacher expertise and collaboration and creating high-quality science lessons: technology-mediated lesson study (TMLS).

TMLS provided the means for geographically distributed teachers to collaborate, develop, implement and improve lessons. TMLS uses technology to capture lesson implementation and collaborate on lesson iterations.

This paper describes the seven steps of the TMLS process with examples, showing how teachers develop their content and pedagogical knowledge while building relationships.

The TMLS approach provides an innovative option for teachers to collaborate across distances and form strong, lasting relationships with others.

This paper aims to examine the actions lecturers, universities and their administrators can take in improving and making political science undergraduate degrees more relevant in the twenty-first century. This paper will reflect on specific measures undertaken by institutions globally to equip students with unique skills to enhance the value and relevance of their programmes in the context of an increased technologically driven environment.

This paper uses a qualitative approach to the review of the literature with implications for practice in examining how universities globally are applying strategies in raising students’ skill levels to enhance future workplace value. A review of select institutions obtained from the Times Higher Ranked (2019) universities was used in identifying best practices to prepare a political science student for better employability.

Contrary to prevailing opinions, a huge skills gap exists for filling the demand for twenty-first century political science-related careers in the public and private sector. The attainment of twenty-first century skill sets and the deployment of technology-driven teaching and learning methods are vital elements in unlocking the value of political science education and providing students with opportunities to advance their professional and career objectives.

Higher education institutions need to reconsider their strategies in the delivery of political science degrees, bearing in mind the increased use of technology and innovative teaching practices. This paper offers insight into how to tailor an exciting and relevant political science programme for the future of work.

The purpose of this paper is to report the design and evaluation of an inter-university collaborative project entitled “Blended learning for building student-teachers’ capacity to learn and teach science-related interdisciplinary subjects.” The project is a response of the science education faculty of three Hong Kong tertiary institutes to the challenge of catering to the diversity of academic backgrounds among student-teachers.

E-learning modules have been produced covering four content domains of science. These modules are designed based on the 5E learning model and are delivered to students using the learning management system provided by Moodle. The design of the modules is iterative, based on the evaluation of three consecutive rounds of trials through student surveys, and focus group interviews with students and course lecturers.

The evaluation findings indicate positive outcomes for certain attributes such as conceptual understanding, eagerness and confidence in learning science, and metacognitive reflection on students’ own learning. There are challenges to be met in relation to instructional design to cater for the diversity of student abilities, and enhance motivation in self-directed learning.

The project indicates the ways to develop students’ basic science knowledge in a mixed-ability setting through the design of self-directed e-learning modules blended with their major courses and possible measures to address the limitations of such design.

The study represents a conscious effort for the science teacher education faculty of different universities to pull together to tackle a perennial teaching and learning problem. The findings provide important insights into possible ways to blend e-learning with face-to-face learning approaches to better cater to the needs of science learners with mixed abilities to prepare them for interdisciplinary teaching.