Pedagogical Models to Implement Effective STEM Research Experience Programs in High School Students

Ahmad, Zubair; Ammar, Mohammad; Al‐Thani, Noora

doi:10.3390/educsci11110743

Cited by 2 publications

(2 citation statements)

References 42 publications

(48 reference statements)

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“…The importance of active learning in enhancing students’ self-efficacy, self-concept, and conceptual understanding cannot be overstated. Building on the groundwork of Bandura’s motivational theory, numerous studies have robustly demonstrated the profound impact of inquiry-based learning and authentic hands-on experiments on boosting students’ self-efficacy, science identity, and retention across STEM fields and diverse demographic groups (e.g., Swan et al, 2018, Ahmad et al, 2021, Jeskova et al, 2022, Wilczek et al 2022, Sperling et al, 2024, Broder et al, 2019, Indorf et al, 2019). These studies lend robust support to our empirical observations, highlighting the critical importance of integrating real-world experimentation and inquiry-driven methods to significantly enhance students’ conceptual comprehension and sense of confidence in their ability to perform experiments and apply these concepts.…”

Section: Discussionmentioning

confidence: 99%

Building Brains for Robots: A Hands-On Approach to Learning Neuroscience in the Classroom

Kannan,

Gendreau,

Hatch

et al. 2024

Preprint

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As the relevance of neuroscience in education grows, effective methods for teaching this complex subject in high school classrooms remain elusive. Integrating classroom experiments with brain-based robots offers a promising solution. This paper presents a structured curriculum designed around the use of camera-equipped mobile robots which enables students to construct and explore artificial neural networks. Through this hands-on approach, students engage directly with core concepts in neuroscience, learning to model spiking neural networks, decision-making processes in the basal ganglia, and principles of learning and memory. The curriculum not only makes challenging neuroscience concepts accessible and engaging but also demonstrates significant improvements in students' understanding and self-efficacy. By detailing the curriculum's development, implementation, and educational outcomes, this study outlines a scalable model for incorporating advanced scientific topics into secondary education, paving the way for a deeper student understanding of both theoretical neuroscience and its practical applications.

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Section: Discussionmentioning

confidence: 99%

Building Brains for Robots: A Hands-On Approach to Learning Neuroscience in the Classroom

Kannan,

Gendreau,

Hatch

et al. 2024

Preprint

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“…Research studies in both Qatar and worldwide have thus focused on the challenges that educational systems face in their efforts to raise the number of students who successfully enter and leave the STEM education system (Seymour, 2002;Singer et al, 2012;Ahmad et al, 2021;Sellami et al, 2022Sellami et al, , 2023. Much of the attention is drawn to the reasons that contribute to students dropping out of STEM careers, including but not limited to students' interests, the nature of educational environments, and the teaching-learning practices employed (National Academies of Sciences and Medicine, 2016).…”

Section: Introductionmentioning

confidence: 99%

Investigating the individual interests of undergraduate students in STEM disciplines

Ammar,

Siby,

Khalili

et al. 2024

Front. Educ.

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Despite massive investments in the education sector to empower youth in Qatar, a vital concern remains to retain students in science, technology, engineering, and mathematics (STEM) disciplines at the undergraduate level. Even though the country is committed to fostering a knowledge-based society, the low interest of undergraduates in STEM disciplines remains a vital challenge. To investigate this, the current study uses a survey methodology to investigate the perspectives of 172 undergraduate students to understand quantitatively the factors that influence their individual interests in STEM disciplines. Non-parametric significance tests and binary logistic regressions were employed to quantitatively measure the direct factors and predictors that affect students’ individual interests. Findings indicated that aspects like students’ reason/motivation to join STEM, their interaction with faculty, the habit of skipping classes, the difficulty faced in the curriculum, and their parents’ highest educational qualification have an association with individual interests. Also, it was found that demographics such as age group, ethnicity, undergraduate discipline, undergraduate year, parent’s employment status, and mother’s highest educational qualification do not contribute to significant differences in students’ individual interests. These conclusions provide important implications for educationists and policymakers to devise constructive reforms to enhance undergraduate students’ individual interests, thereby improving their persistence in STEM.

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Pedagogical Models to Implement Effective STEM Research Experience Programs in High School Students

Cited by 2 publications

References 42 publications

Building Brains for Robots: A Hands-On Approach to Learning Neuroscience in the Classroom

Building Brains for Robots: A Hands-On Approach to Learning Neuroscience in the Classroom

Investigating the individual interests of undergraduate students in STEM disciplines

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