Ex) Article Title, Author, Keywords
Ex) Article Title, Author, Keywords
Abstract : As an essential feature of doing science or physics, inquiry and laboratory work have been emphasized as both pedagogical goals and strategies. The discussion on what constitutes physics inquiry and laboratory work has philosophical, cultural and historical aspects and also reflects the relatively recent development of science curriculum. In this paper, I have reviewed how the notion of science inquiry and laboratory work has changed and elaborated on the recent emphasis on scientific practices in doing physics. The review has shown that students’ doing science or physics entails their epistemic agency while participating in scientific practices and sensemaking. Following the review, I have presented an empirical analysis of middle school science teachers’ facilitation, or lack thereof, of students’ sensemaking during scientific practices. The analysis revealed several strategies that facilitated students' sensemaking during scientific practices and underscored the critical role of teacher noticing in supporting students’ sensemaking. Further research topics are suggested in the conclusion.
Abstract : We present a quantitative three-dimensional (3D) measurement technique with an extended axial range using a partial coherence digital holography microscope (DHM). This method enables the extraction of 3D information from specimens by analyzing the reconstructed amplitude images, which inherently contain optical path difference (OPD) data modulated by the degree of coherence in the hologram plane. By utilizing partial coherence illumination, the proposed DHM approach effectively mitigates coherence noise, allowing for precise 3D measurements even for samples with step heights exceeding the wavelength of the light source used. As a proof of concept, we conducted 3D measurements on a stepwise sample, demonstrating the capability of our method to resolve fine structural details and measure significant height variations. This technique offers significant advantages for applications requiring accurate 3D profiling in the presence of coherence noise and large step heights.
Abstract : Ion trap is emerging as one of the key techniques in the field of quantum computing due to its high precision and long coherence time. This review covers recent research trends in quantum computing technologies based on ion trap, discussing the technological advancements in the control and operation of quantum bits (qubits). We deal with quantum state preparation, Rabi oscillations, and decoherence suppression methods within ion trap systems. Additionally, the potential and commercialization prospects of ion trap for realizing next-generation quantum computers are examined, along with its contributions to enhancing the performance of quantum computers. Compared to other quantum computing implementations, ion trap offers remarkable accuracy and scalability, and it is expected to play a crucial role in the development of next-generation high-performance quantum computers.
Abstract : In high-energy experiments, photo detectors using photomultiplier tubes require detection materials that absorb the energy of incident particles and convert it into an optical signal. These materials must exhibit high geometric efficiency, scintillation efficiency, and light output. The most common detection materials that satisfy these characteristics are utilized in the form of liquid scintillators where certain organic scintillation solutes are dissolved in a solvent. In order to achieve a high signal-to-noise ratio, this paper is focusing efforts on the development of next-generation liquid scintillators as detection materials and the saturation response of photomultiplier tubes to high-energy gamma rays as photo detector response characteristics. As a preliminary step towards achieving a high signal-to-noise ratio, to date, basic several research that has not been reported was performed on the recognition of detector output signal patterns and predictive maintenance of triggered detectors through signal preprocessing studies.
Abstract : Recently, researches on the various types of neuromorphic synaptic devices are attracting attention. In this paper, a synaptic device was fabricated and its characteristics were analyzed using a mesh-type platinum floating gate that mimics nanoparticles. Compared with single floating gates, mesh-type floating gates have a wider memory window and excellent electrical characteristics with improved operation speed and retention. Appropriate thickness conditions were set by checking the EOT (equivalent oxide thickness) and breakdown voltage of the tunnel oxide and control oxide using capacitance-voltage curves and a current-voltage curve. Excellent program and erase operation, synaptic weight, repeatability, reproducibility and memory window width were confirmed using the capacitance-voltage curves. It was compared whether the same performance was achieved even if part of the floating gate was damaged, suggesting the possibility of a synaptic device.
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
Sangwoo Ha
New Phys.: Sae Mulli 2023; 73(9): 734-749
https://doi.org/10.3938/NPSM.73.734