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Journal of Tecnologia Quantica
Published by Yayasan Adra Karima Hubbi
ISSN : 30626757     EISSN : 30481740     DOI : 10.70177/quantica
Core Subject : Science,
Physics
Journal of Tecnologia Quantica is dedicated to bringing together the latest and most important results and perspectives from across the emerging field of quantum science and technology. Journal of Tecnologia Quantica is a highly selective journal; submissions must be both essential reading for a particular sub-field and of interest to the broader quantum science and technology community with the expectation for lasting scientific and technological impact. We therefore anticipate that only a small proportion of submissions to Journal of Tecnologia Quantica will be selected for publication. We feel that the rapidly growing QST community is looking for a journal with this profile, and one that together we can achieve. Submitted papers must be written in English for initial review stage by editors and further review process by minimum two international reviewers.
Arjuna Subject : Fisika dan Astronomi - Fisika Nuklir dan Molekuler, dan Ooptik
Articles 5 Documents
 1 
Search results for , issue "Vol. 1 No. 3 (2024)" : 5 Documents clear
New Breakthroughs in Quantum Optics: Research Towards More Efficient Compressed Matter Nitin, Mahon; Tandon, Meredith; Jonathan, Bouyea
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.v1i3.921

Abstract

In quantum physics, understanding compressed matter brought to extreme states, such as those found inside neutron stars or planetary cores, is the key to unlocking mysteries about the structure and behaviour of matter at a fundamental level. Quantum Optics, as a tool for manipulating and measuring particles on atomic and subatomic scales, offers new methods for investigating properties of compressed matter that are inaccessible through conventional techniques. This research aims to develop Quantum Optics techniques that are more efficient in characterizing and manipulating compressed materials to better understand materials' mechanical and electronic properties under extreme conditions. This research method combines laboratory experiments with sophisticated mathematical modelling techniques. The experiments involve using high-intensity lasers and ion traps to generate and measure compressed states of matter. Mathematical models, supported by computer simulations, predict experimental results and provide theoretical insight into observations. This research shows that using adapted Quantum Optics techniques can achieve greater control over compressed materials and measure their properties with unprecedented accuracy. This includes revealing electrons' behaviour under high pressure and extreme temperatures. This research concludes that innovative Quantum Optics techniques can provide new and significant insights into the properties of compressed matter. This research advances the field of Quantum Optics and expands our understanding of condensed matter physics and astrophysics. It also paves the way for developing new technologies based on the unique properties of compressed materials.
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.
History of Computer Networks Sirait, Hasanuddin
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.v1i3.1447

Abstract

With has each other connected so between computer can interact And send data. Data transmission is carried out To use spread information And data processing becomes something information . So that man as user information can take advantage of it in necessary jobs? speed And data accuracy and accuracy information. Various network models computer seen of type and benefits network the such as one to one, one to anywhere , many to one and many to many. Development system network computer This started since 1960s by? company electronics famous like ARPANET. Development network computer the will explained on discussion following .
Ultra-Sensitive Quantum Sensor for Detection of Pollutants in Water Fathoni, Mohammad; Zaki, Amin; Razak, Faisal
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.v1i3.1677

Abstract

Water pollution by hazardous substances, such as heavy metals and industrial chemicals, is a global problem that threatens the sustainability of ecosystems and human health. Early detection of these pollutants is essential to prevent further damage. This study aims to evaluate the effectiveness of ultra-sensitive quantum sensors in detecting pollutants in water at very low concentrations. The method used in this study is laboratory and field experiments, by comparing the performance of quantum sensors and conventional sensors in detecting heavy metals and other chemicals in water. The results show that quantum sensors have a much higher sensitivity compared to conventional sensors, with the ability to detect contaminants up to lower concentrations. Quantum sensors can detect lead (Pb) at 0.1 ppb, while conventional sensors can only detect at 0.4 ppb. In conclusion, quantum sensor technology can provide a more efficient and sensitive solution for water quality monitoring, and it has great potential to be implemented in a wider range of environmental monitoring systems. Further research is needed to overcome cost constraints and improve the integration of these technologies in water monitoring in the field.
Quantum Teleportation via Optical Communication Channels Chai, Nong; Pao, Chai; Chai, Som
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.v1i3.1678

Abstract

Quantum teleportation through optical communication channels is one of the promising technologies to create secure communication systems in the future. This study aims to evaluate the efficiency of quantum teleportation through various types of optical communication channels, such as standard optical fibers, low-loss optical fibers, and free photon-based communication lines. The research was conducted using a quantitative experimental method, measuring the success rate of teleportation based on channel length, channel type, and environmental disturbances. The results showed that low-loss optical fibers had the highest efficiency, with a success rate of 85% at distances of up to 50 km. The free photon-based path shows good performance at short distances, but decreases drastically at longer distances due to atmospheric disturbances. The study also found that photon loss and environmental disturbances are the main factors affecting entanglement stability, especially in channels more than 75 km long. The conclusion of this study confirms that low-loss optical fiber is the best choice to support quantum teleportation on a local to medium scale. The main challenges in the development of this technology are the reduction of photon loss and the management of environmental disturbances. Further research is needed to address these limitati

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