This systematic literature review investigates the integration of scientific creativity in science education, focusing on pedagogical strategies, psychological and cognitive dimensions, and assessment approaches. Scientific creativity, defined as the ability to generate novel and valuable ideas in scientific contexts, is essential for developing problem-solving and critical thinking, yet its application in educational settings remains limited. Guided by the PRISMA framework, a systematic search of major academic databases identified 24 relevant studies. The findings are organized into three main themes: first, structured pedagogical approaches such as Science, Technology, Engineering, and Mathematics (STEM) frameworks, problem-based learning, and Cognitive Research Trust methods that stimulate students’ creative capacities; second, psychological factors including metacognition, emotional engagement, and intrinsic motivation, which play a critical role in supporting creative performance; and third, assessment practices employing standardized instruments and digital tools such as creativity scales and mind mapping to evaluate outcomes effectively. This review concludes that fostering scientific creativity requires a multifaceted approach integrating innovative pedagogy, psychological support, and valid assessment methods, offering practical implications for educators and policymakers committed to embedding creativity in science education.

Scientific creativity STEM education Systematic review Psychological factors Assessment methods

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