Ex) Article Title, Author, Keywords
Ex) Article Title, Author, Keywords
Abstract : In recent years, generative AI technology, especially large language models (LLMs), has garnered significant attention for its potential to transform education. This paper provides an overview of generative AI's development and examines its impact on education, focusing on the issue of `hallucinations' in LLMs. It explores the causes and proposes solutions such as finetuning, reasoning, iterative querying, and Retrieval-Augmented Generation (RAG). These methods aim to enhance the accuracy and reliability of AI responses. Examples of AI applications in education include real-time student query responses, personalized learning pathways, and assessment feedback. While these technologies promise to improve educational quality, they also raise concerns about biases and data privacy. This paper discusses strategies to effectively utilize generative AI in education, aiming to improve quality while minimizing negative impacts.
Abstract : This study analyzed the understanding of interval voltage in electric circuits among elementary, middle, and high school students and pre-service physics teachers. As a result only 14.7% of elementary, middle, and high school students responded scientifically to the definition of voltage before the lesson, and 81.8% of pre-service physics teachers did. Second, less than 10% of students and pre-service physics teachers correctly predicted interval voltages in electric circuits and provided scientific explanations. Third, students and pre-service physics teachers almost accurately measured interval voltages, closely matching theoretical values, using both experimental methods using experimental tools and simulation. Fourth, survey results after the lesson indicated that both students and pre-service physics teachers considered the combination of measurement activities and simulation activities the most effective teaching method for learning interval voltage in electric circuits. Based on these results, implications for the science education and curriculum, as well as teaching and learning were discussed.
Abstract : Superconductor is a substance of zero-resistance below critical temperature and it has been attracted lots of attention from many researchers due to the possibility of applications in various field such as quantum computing which is the hottest topic on recent science community. However, for these applications, it is necessary to prepare high quality superconductor films and understand the physical characteristics of films. In this study, we grew YBa2Cu3O7(YBCO) thin films and established concrete conditions to synthesize highly qualified thin films with a high critical temperature and narrow transition width. Then, we analyzed samples showing different critical temperature using X-ray Diffraction (XRD), X-ray Photoelectron Spectroscopy (XPS), and Transmission Electron Microscope (TEM). Through the analysis, it is identified that there is ab twinning on YBCO film with a high critical temperature (∼93 K), which are strong evidences of tetragonal-orthorhombic phase transition.
Abstract : This study explores the use of symbolic regression (SR) in physics education, aiming to gauge its effectiveness and educational value. SR involves deriving mathematical models from empirical data by finding symbolic representations that fit the data. We evaluate two SR algorithms, AI-Feynman and Φ-SO, using position data from objects in parabolic motion and damped oscillations. Our analysis demonstrates that SR algorithms can produce concise formulas to describe object motion. Integrating SR into physics education allows students to build on their prior knowledge of physics to formulate hypothetical symbolic terms and enhance their explanations of physical phenomena. Subsequently, students iteratively derive mathematical expressions from data, thereby nurturing a process of data-driven discovery. Furthermore, students can recognize the impact of technological advancements on scientific problem-solving. However, effective pedagogical strategies are necessary to guide students beyond mere derivation of mathematical expressions, encouraging them to interpret and elucidate models in meaningful scientific inquiries.
Abstract : In the 2015 revised curriculum, students have the autonomy to choose their desired subjects through a choice-based curriculum. However, there is a continuing trend among students to avoid physics, opting for subjects where they can achieve relatively higher grades without considering their future career paths. In this study, we surveyed the motivations and tendencies of students who took integrated science courses to select Physics I and analyzed the results. The results showed that students’ preferred science subjects in the second year are Biology I, Chemistry I, Earth Science I, and Physics I, in that order. Male students cited the allure of physics content, while female students emphasized the necessity for university entrance as the reason for their interest in Physics I. Both male and female students mentioned relevance to career paths and personal interest and aptitude as reasons for selecting Physics I. Additionally, students tended to find the physics component of integrated science more challenging than other areas. Based on these results, discussions were held on strategies to enable more students to choose Physics I.
Aekyung Shin, Donggeul Hyun, Jeongwoo Park
New Phys.: Sae Mulli 2023; 73(1): 37-43
https://doi.org/10.3938/NPSM.73.37
Geon Park, Inseo Kim, Hojung Sun, Yongjei Lee, Kimoon Lee, JungYup Yang
New Phys.: Sae Mulli 2023; 73(1): 23-28
https://doi.org/10.3938/NPSM.73.23
Bongwoo Lee*
New Phys.: Sae Mulli 2022; 72(10): 795-805
https://doi.org/10.3938/NPSM.72.795