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All Journal Al-Hijr: Journal of Adulearn World Journal International of Lingua and Technology International Journal of Educational Narratives Journal Neosantara Hybrid Learning Journal Emerging Technologies in Education Journal of World Future Medicine, Health and Nursing Journal of Computer Science Advancements Journal of Moeslim Research Technik Journal of Tecnologia Quantica
Xavier, Embrechts
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Aerospace Engineering Automotive Engineering Computer Science & IT Control & Systems Engineering Education Electrical & Electronics Engineering Engineering Health Professions Languange, Linguistic, Communication & Media Medicine & Pharmacology Nursing Physics Public Health Social Sciences Veterinary Other

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Quantum Optics Innovation in Photonics-Based Technology Development Xavier, Embrechts; Guilin, Xie; Jiao, Deng
Journal of Tecnologia Quantica Vol. 1 No. 2 (2024)
Publisher : Yayasan Adra Karima Hubbi

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.70177/quantica.v1i2.901

Abstract

The interaction between light and matter is a fundamental topic in physics that has broad implications for developing new technologies. With the development of nanotechnology and photonics, a deeper understanding of how light can be affected by and affect matter at the micro and nano scales has become important. This research aims to explore and characterize the interaction of light with matter under various experimental and theoretical conditions to reveal new phenomena that can be exploited in future technologies, such as in the development of quantum computers, advanced sensors, and optical communication systems. This research uses a combination of experimental methods and computer simulation. The experiments were carried out using advanced spectroscopy and microscopy techniques to observe interactions at the atomic and molecular levels. Computer simulations are used to model interactions and predict the behavior of materials under the influence of different light. The results show that by manipulating the structure of materials at the nanoscale, we can significantly change the way materials interact with light. This includes creating meta-material effects not found in nature, which allow the control of light in a highly efficient and selective manner. This study's conclusions confirm that the potential for controlling and exploiting light in technological applications has been substantially expanded through high-precision manipulation of materials at the nanoscale. These findings pave the way for the development of various advanced technological applications that are more efficient and effective, providing a strong foundation for future technological innovations that rely on the interaction of light and matter.
Sustainability Research in Quantum Optics: Defining the Role of Compressed Matter Physics Oscar, Schersclight; Xavier, Embrechts; Mark, Elladdadi
Journal of Tecnologia Quantica Vol. 1 No. 3 (2024)
Publisher : Yayasan Adra Karima Hubbi

Show Abstract | Download Original | Original Source | Check in Google Scholar | DOI: 10.70177/quantica.v1i3.933

Abstract

Quantum Optics, as a field that studies the interaction between light and matter at the quantum level, has the potential to reveal new phenomena in the physics of compressed matter. Compressed matter, often encountered in extreme conditions like stellar or planetary cores, is key to understanding fundamental physical processes and advanced technological applications. This research aims to explore and define the role of compressed matter physics in the context of sustainability. By examining how materials behave under extreme pressure and temperature, we seek to identify ways Quantum Optics can facilitate the development of new environmentally friendly materials and energy-efficient technologies. The methodology used involves a combination of Quantum Optics experiments and theoretical modelling. Experiments include using high-intensity lasers and ion traps to create compressed conditions. In contrast, theoretical models are used to predict the behaviour of the material and its effects on energy efficiency and sustainability. Results from experiments and theoretical models show that Quantum Optics techniques can be effectively used to control and manipulate compressed matter, providing new data on its mechanical and electronic properties. These findings suggest that exploiting the physics of compressed matter can play an important role in developing sustainable technologies. The conclusion of this research is to strengthen the position of Quantum Optics as a vital tool in sustainability research. Through Quantum Optics, the physics of compressed matter offers an uncharted path for innovation in sustainable materials and technologies. Further research is recommended to explore the practical application of these findings in industrial and environmental contexts.
Co-Authors Akhmad Feri Fatoni Ali Mufron, Ali Barra, Ling Barroso, Uwe Buka, Sisilia Prima Yanuaria Emdat Suprayitno Erliana, Leni Fitriani, Rani Guilin, Xie Harjoni Harjoni Haruka, Hide Intes, Amina Jiao, Deng Linty, Mathieu Maharjan, Kailie Margarida, Kruger Mark, Elladdadi Marlina Nitin, Mahon Niva, Matteson Oscar, Schersclight PAHAR KURNIADI, PAHAR Qoidul Khoir Sarip, Mohamad Suhada, Karya Zulaekah Zulaekah