One of the challenging concepts that many primary school pupils deal with is adding fractions. However, the problem of adding fractions in the classroom might be resolved by employing virtual manipulatives. This study aimed to compare the use of virtual manipulatives and conventional lecture-based methods in two groups of Year 4 pupils to examine the effects of understanding the addition of fractions. Sixty-four pupils participated in this study. This study occurred throughout a six-week time frame in a primary school in Temerloh, Malaysia. A quasi-experimental non-equivalent pre-post test was implemented to compare the effects of the control and experimental groups. The first finding showed that the experimental group's conceptual understanding of adding fractions was significantly better after using virtual manipulatives during the intervention, t (62) = 11.682, p<0.005. Cohen's D demonstrated the effect size for comparison (d=2.06), showing a significant effect. The second finding revealed that the conceptual understanding of adding fractions was significantly better after the intervention with virtual manipulatives when controlling the pre-test score, F (1, 61) = 9.475, p < .001, η2 = 0.134. This study showed that pupils in the experimental group improved their conceptual understanding of adding fractions.

The purpose of this study was to develop a valid and theoretically sound 21st century skills-based mathematics learning model. Plomp's research and development theory and Nieveen's criteria were used to ensure the quality and reliability of the model. The model development process includes Initial Investigation, Design, and Realization/Construction. Data were collected from six schools through various instruments such as observation sheets, documents, 21st century skills tests, and interview guides. Model validation involved the participation of five experts. A blended data analysis approach was used to ensure a comprehensive understanding of the findings. The result of this study is a 21st century skills-based mathematics learning model named Model 21-BML. The model consists of five interconnected core components: Learning Syntax, Social System, Reaction Principles, Support System, and Instructional and Accompanying Impacts. The uniqueness of this model lies in the seven integrated learning trajectories: Object translation, decomposition, cognitive construction, cognitive development, communication, reflection, and extension. After going through a rigorous validation process, the five experts confirmed the high validity of the 21-BML Model. This model not only enhances innovative mathematics learning theory, but also provides practical alternatives for mathematics teachers to encourage the development of 21st century skills in students. The model is expected to make a significant contribution in bridging the gap between traditional mathematics education and the competency demands of the modern era, as well.

Recently, in Indonesia, project-based learning (PjBL) has been used as an alternative approach in the teaching and learning process. Research on PjBL has been widely conducted in many countries at various levels. In most previous studies, PjBL was used to improve students' competence in certain math subjects. This study uses a case study research method to determine the effectiveness of PjBL at university in improving pre-service teachers' PCK. The research was carried out in 2022 involving fourteen mathematics education study program students selected by purposive sampling. The instruments used consisted of observation sheets, tests, and questionnaires. During the PjBL activity, participants were given a project to develop teaching materials for geometric transformation using certain teaching-learning strategies. The results of the study show that PjBL can improve students' PCK ability, although participants face several obstacles related to commitment to completing projects on time. Therefore, PjBL can be applied in the teaching-learning process to support professional mathematics teachers.

This research based on community service aims to evaluate the effectiveness of the science, technology, engineering, and mathematics (STEM) approach in strengthening the literacy and numeracy learning profile of students at Eakkapapsasanawich Islamic School Thailand. The research employs a quantitative research approach with a single-group pre-test and post-test control design. The research sample consists of two groups: an experimental group receiving STEM-based instruction and a control group receiving conventional instruction. The total number of students involved in this study is 60, with each group comprising 30 students. Data collection techniques include pre-test and post-test assessments involving literacy and numeracy-related questions relevant to the school curriculum. Data analysis is conducted using descriptive statistical methods and independent t-test to compare test results between the experimental and control groups. The results indicate that students who received instruction with the STEM approach experienced a significant improvement in numeracy literacy compared to those who received conventional instruction. The average scores of the final test in the experimental group were significantly higher than those in the control group. Statistical analysis also reveals a significant difference between the two groups in terms of improvement in numeracy literacy scores. This suggests that the STEM approach is effective in enhancing the literacy and numeracy learning profile of students.

As skills-gap between available skills and in-demand skills in the Solar Energy Technology Sector (SETS) continues to expand due to rapid growth of the sector, the need for Higher Education Institutions (HEIs) to design and run critical Solar Energy Technology Training (SETechTra) modules has become imperative. Informed by the findings from SETechTra project – which includes extensive literature reviews, stakeholder interviews, observations, feedback from pilot model involving circa 1500 students from schools/colleges across four European countries, this article reports on a developed strategic undergraduate (UG) 30-credit module. The module is designed to embed in-demand skills in SETS within students enrolled upon wider Science, Technology, Engineering, and Mathematics (STEM) courses. The contents of the module comprise learning and teaching activities engineered to embed key identified academic, industrial, and entrepreneurial in-demand skills in SETS in STEM UG students. Formative and summative assessments are the implemented assessment strategy used to evaluate the effectiveness and impact of the module in the pilot model. Analysis of feedback from the pilot model demonstrations indicates significant positive impact, giving a promising indication of wider applicability to HEIs across Europe interested in fast-tracking production of more SETS industry-ready graduates.

Multimedia instructional strategies (MIS) have been shown to significantly enhance learners’ academic performance in mastering challenging chemistry concepts. However, few studies have specifically investigated using MIS to enhance students’ conceptual understanding of molecular hybridisation. This study employed a nonequivalent two-group pre-test/post-test quasi-experimental design to determine the impact of MIS on students’ conceptual understanding of hybridisation. Data were collected from 60 second-year senior high school students using a diagnostic test and an interview guide. Pre-tests and post-tests were administered to two intact classes of 30 students each: one served as the experimental group and the other, the control group,  purposively sampled from two different schools. The results revealed that students in the experimental group (taught using MIS) achieved significantly higher post-test scores than those in the control group (taught using conventional methods). Additionally, the experimental group exhibited a significant improvement from pre-test to post-test scores, whereas the control group’s pre-test and post-test scores did not differ significantly. Moreover, MIS was highly interactive, promoted student interest, and enhanced students’ understanding of hybridisation. Therefore, the study recommends that science educators incorporate MIS into their instruction to improve students’ conceptual understanding of other abstract chemistry concepts. The implications of these findings are discussed in detail, highlighting the potential of MIS in chemistry education.