Journal of Tecnologia Quantica
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.
Articles
45 Documents
<![CDATA[Recent Quantum Optics Experiments: Uncovering the Mysteries of Compressed Matter ]]>
<![CDATA[Guilin, Xie]]>;
<![CDATA[Jiao, Deng]]>;
<![CDATA[Wang, Yuanyuan]]>
<![CDATA[ Journal of Tecnologia Quantica Vol. 1 No. 1 (2024) ]]>
Publisher : <![CDATA[Yayasan Adra Karima Hubbi ]]>
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DOI: 10.70177/quantica.v1i1.871
<![CDATA[The physics of compressed matter has become a widely interesting research field mainly due to its relevance in understanding the structure and behavior of matter under extreme pressure conditions. Despite advances made, many mysteries within this field, especially related to the quantum properties of compressed matter, remain unsolved. This research aims to utilize recent quantum optics experiments to unveil the mysteries contained in compressed matter. The primary focus is to understand the quantum properties of matter under high pressure and explore unique behaviors that may emerge in this situation. This research employs a combined approach of quantum optics experiments and theoretical analysis. Experiments are conducted using sophisticated quantum optics equipment to manipulate and examine compressed matter on a quantum scale. Meanwhile, theoretical analysis is used to deepen understanding of the phenomena observed during the experiments. The findings indicate that recent quantum optics experiments have provided new insights into the quantum properties of compressed matter. Some intriguing results include the observation of quantum phase transitions and other quantum effects that may arise under extreme pressure conditions. These results contribute significantly to the understanding of the physics of compressed matter and pave the way for further research in this area. The conclusion of this study is that recent quantum optics experiments have helped unveil the mysteries contained in compressed matter. By integrating experimental and theoretical approaches, this research has deepened the understanding of the quantum properties of matter under high pressure.]]>
<![CDATA[Quantum Optics Innovations for the Future of Quantum Communications ]]>
<![CDATA[Zou, Guijiao]]>;
<![CDATA[Jie, Lie]]>;
<![CDATA[Jixiong, Cai]]>
<![CDATA[ Journal of Tecnologia Quantica Vol. 1 No. 1 (2024) ]]>
Publisher : <![CDATA[Yayasan Adra Karima Hubbi ]]>
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DOI: 10.70177/quantica.v1i1.872
<![CDATA[Quantum communication is a rapidly evolving field aimed at overcoming security challenges in modern communications. Challenges such as signal degradation and vulnerabilities to classical attacks necessitate new innovations to enhance the efficiency and security of quantum communications. This research explores potential innovations in quantum optics to advance future quantum communications. The primary focus is the development of new techniques that could improve transmission efficiency and enhance the security of quantum communications. The research methodology utilizes a combination of theoretical analysis and laboratory experiments. A review of recent literature in quantum optics is conducted to identify potential innovations that could enhance quantum communications. Subsequently, laboratory experiments are performed to validate the effectiveness of the proposed concepts. The findings indicate various potential innovations in quantum optics that could enhance quantum communications. Techniques such as using entanglement to enhance transmission security and developing more efficient quantum signal processing systems have shown promising results in laboratory trials. This research highlights the importance of innovations in quantum optics as solutions to challenges in quantum communications. By integrating these new concepts into the quantum communication infrastructure, it is expected to improve the efficiency, speed, and security of future quantum communications. Thus, innovations in quantum optics have significant potential to transform the landscape of quantum communications and bring about important advancements in the field.]]>
<![CDATA[New Challenges in Compressed Matter Physics: Future Research Projections ]]>
<![CDATA[Wei, Zhang]]>;
<![CDATA[Xu, Shanshan]]>;
<![CDATA[Xavier, Murphy]]>
<![CDATA[ Journal of Tecnologia Quantica Vol. 1 No. 1 (2024) ]]>
Publisher : <![CDATA[Yayasan Adra Karima Hubbi ]]>
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DOI: 10.70177/quantica.v1i1.873
<![CDATA[Compressed Matter Physics has become an increasingly important field in understanding the properties of matter under extreme conditions, such as those found inside giant planets, neutron stars, and in experiments with ultra-intense lasers. However, although there has been progress in the understanding of compressed matter, there are still major challenges that need to be overcome in understanding the behavior of matter under these extreme conditions. This research aims to explore new challenges in the physics of compressed matter and identify future research projections that can overcome these challenges as well as to improve understanding of the properties of matter under extreme conditions and develop potential applications in various fields, including astronomy, nuclear physics, and materials engineering. This research method involves analysis of the latest literature in the field of compressed matter physics, as well as discussion and collaboration with experts in the scientific community. The results show that there are several major challenges in understanding the physics of compressed matter, including a deeper understanding of the behavior of matter at very high pressures and temperatures, as well as the development of more sophisticated technologies to measure and model these extreme conditions. In addition, we also identify several future research projections that can address these challenges, including the development of new experimental techniques, the development of more sophisticated theoretical models, and the use of more powerful energy sources to achieve extreme conditions. higher. The conclusions of this study highlight the importance of continuing to explore the world of compressed matter to understand the properties of matter under extreme conditions. By identifying key challenges and future research projections, we hope to inspire continued research in this field and advance understanding of the universe at extreme scales.]]>
<![CDATA[Current Quantum Optics Research: Exploring the Potential of Quantum Computing ]]>
<![CDATA[Elliot, McCarty]]>;
<![CDATA[Oscar, Scherschligt]]>;
<![CDATA[Kathryn, Morse]]>
<![CDATA[ Journal of Tecnologia Quantica Vol. 1 No. 1 (2024) ]]>
Publisher : <![CDATA[Yayasan Adra Karima Hubbi ]]>
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DOI: 10.70177/quantica.v1i1.874
<![CDATA[Quantum Optics is a branch of physics that studies the interaction between light and matter on a quantum scale. Research in this field aims to understand the basic properties of light particles (photons) and matter (atoms, molecules) and utilize them in various applications, including quantum computing. The aim of this research is to explore the potential of quantum computing in the context of Quantum Optics. This includes quantum algorithm development, experimental implementation, and practical applications in quantum information processing. The research method used involves a combination of theoretical and experimental approaches. The theoretical approach involves the development and mathematical analysis of Quantum Optics models, while the experimental approach involves the design and implementation of quantum physics systems in the laboratory. The research results show significant progress in the development of quantum algorithms that can be used in modeling quantum physics systems, quantum information processing, and other applications. In addition, the experimental results also show achievements in the implementation of quantum system prototypes that can be applied in the field of quantum computing. From the research that has been conducted, it can be concluded that quantum computing has great potential in improving the understanding of quantum physical systems and in developing new technologies based on quantum principles. However, challenges such as quantum quality control and maintenance and system scalability remain the focus of future research. As such, current Quantum Optics research offers exciting and potentially paradigm-shifting insights into future information processing and computing technologies]]>
<![CDATA[Sustainability in Quantum Optics: Future Research in Renewable Energy ]]>
<![CDATA[Intes, Amina]]>;
<![CDATA[Barroso, Uwe]]>;
<![CDATA[Cale, Wolnough]]>
<![CDATA[ Journal of Tecnologia Quantica Vol. 1 No. 1 (2024) ]]>
Publisher : <![CDATA[Yayasan Adra Karima Hubbi ]]>
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DOI: 10.70177/quantica.v1i1.894
<![CDATA[Quantum optics is a field that has shown great potential in developing renewable energy technology. The interaction between light and matter on the quantum scale opens up opportunities for higher energy efficiency and more sustainable energy sources. However, further research is needed to integrate the principles of quantum optics into technologies that can be widely applied in the renewable energy sector. This research explores how quantum optics-based technologies can be developed and integrated into renewable energy applications to increase efficiency and sustainability. This research seeks to identify and test various approaches in quantum optics that can improve renewable energy generation and storage methods. The methods used include laboratory experiments and computer simulations to test the effectiveness of various quantum optical configurations in enhancing the energy conversion process. A multi-disciplinary approach with collaboration between physicists, engineers, and materials experts is used to achieve a deeper understanding of the potential of this technology. The research results show that using quantum entanglement and non-linear phenomena in quantum optics can significantly improve the efficiency of solar energy collection and conversion. This technique has succeeded in increasing the conversion efficiency of solar cells from conventional models by 10 to 15 percent in laboratory conditions. The conclusions of this study confirm that quantum optics have significant potential to improve sustainability and efficiency in renewable energy technologies. With further research and development, quantum optics-based technologies could contribute to global efforts to reduce dependence on fossil fuels and tackle climate change. Thus, integrating quantum optical principles into renewable energy systems should be a significant focus in future research]]>
<![CDATA[Quantum Optics Research Prospects: Transformation Towards Faster Quantum Computing ]]>
<![CDATA[Barroso, Uwe]]>;
<![CDATA[Nitin, Mahon]]>;
<![CDATA[Bradford, Snyder]]>
<![CDATA[ Journal of Tecnologia Quantica Vol. 1 No. 2 (2024) ]]>
Publisher : <![CDATA[Yayasan Adra Karima Hubbi ]]>
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DOI: 10.70177/quantica.v1i2.895
<![CDATA[Advancements in quantum computing have become a primary focus in modern computer science. However, one of the major challenges in creating more powerful quantum computers is developing more stable and efficient qubits. In this context, research in quantum optics offers game-changing solutions. By leveraging quantum physics principles and quantum optics technology, this research aims to transform the quantum computing landscape by creating more stable and faster qubits. The goal of this study is to explore the potential of quantum optics in creating more stable and efficient qubits for quantum computing. This research method involves a combination of experimental and theoretical approaches. Data obtained from these experiments will be analyzed using advanced theoretical methods to understand the quantum properties of the produced qubits. The results indicate that the quantum optics approach can be key in creating more stable and faster qubits for quantum computing. Experiments have successfully demonstrated better control over qubits in photonic systems and compressed matter, producing qubits with higher reliability. Theoretical analysis also reveals a deeper understanding of the quantum properties of the produced qubits, opening the door for further development in this field. The conclusion of this research shows that quantum optics has great potential to transform quantum computing by creating more stable and faster qubits. By continuing to develop quantum optics technology and deepening the understanding of quantum properties of compressed matter and photonic systems, quantum computing can be taken to a new level.]]>
<![CDATA[Quantum Optics Innovation in Photonics-Based Technology Development ]]>
<![CDATA[Xavier, Embrechts]]>;
<![CDATA[Guilin, Xie]]>;
<![CDATA[Jiao, Deng]]>
<![CDATA[ Journal of Tecnologia Quantica Vol. 1 No. 2 (2024) ]]>
Publisher : <![CDATA[Yayasan Adra Karima Hubbi ]]>
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DOI: 10.70177/quantica.v1i2.901
<![CDATA[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.]]>
<![CDATA[Current Research in the Interaction of Light and Matter: Implications for Future Technology ]]>
<![CDATA[Barra, Ling]]>;
<![CDATA[Wang, Yuanyuan]]>;
<![CDATA[Zou, Guijiao]]>
<![CDATA[ Journal of Tecnologia Quantica Vol. 1 No. 2 (2024) ]]>
Publisher : <![CDATA[Yayasan Adra Karima Hubbi ]]>
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DOI: 10.70177/quantica.v1i2.902
<![CDATA[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.]]>
<![CDATA[Future Challenges of Quantum Optics: Research for Improved Energy Efficiency ]]>
<![CDATA[Cale, Wolnough]]>;
<![CDATA[Jie, Lie]]>;
<![CDATA[Cale, Woolnough]]>
<![CDATA[ Journal of Tecnologia Quantica Vol. 1 No. 2 (2024) ]]>
Publisher : <![CDATA[Yayasan Adra Karima Hubbi ]]>
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DOI: 10.70177/quantica.v1i2.904
<![CDATA[In the midst of the increasing need for efficient and sustainable energy, Quantum Optics has shown great potential in the energy technology revolution. These technological advances provide opportunities to address some of the most pressing challenges facing the energy sector today, including the need for cleaner and more efficient energy sources. However, there are still obstacles in the practical application of Quantum Optics-based technologies, especially in the context of energy efficiency. This research aims to identify and analyze the challenges that exist in the development and application of Quantum Optics in the energy sector, as well as proposing innovative solutions to increase energy efficiency. The main focus is on improving the efficiency of energy use in photovoltaic systems and energy storage systems. The method used in this research includes theoretical and experimental analysis. The theoretical approach involves using mathematical models and computer simulations to predict the behavior and capabilities of systems using Quantum Optics technology. Meanwhile, the experimental approach consists in testing device prototypes built on the principles of Quantum Optics to verify theoretical predictions and assess their effectiveness in practical applications. The research results show that with modifications to the design and materials, the energy conversion efficiency in photovoltaic systems can be increased by up to 20%. Additionally, the use of new materials in energy storage systems shows an increase in storage capacity of up to 25% compared to current technology. The conclusions of this study confirm that Quantum Optics has great potential to improve energy efficiency in various applications. By continuing to drive innovation in design and materials, and overcome implementation barriers, Quantum Optics can play a key role in meeting the global need for cleaner, more efficient energy in the future.]]>
<![CDATA[The Future of Quantum Optics: Mapping the Path to Scalable Quantum Computing ]]>
<![CDATA[Maharjan, Kailie]]>;
<![CDATA[Wei, Zhang]]>;
<![CDATA[Barroso, Uwe]]>
<![CDATA[ Journal of Tecnologia Quantica Vol. 1 No. 2 (2024) ]]>
Publisher : <![CDATA[Yayasan Adra Karima Hubbi ]]>
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DOI: 10.70177/quantica.v1i2.905
<![CDATA[quantum computing. However, the main challenge in creating a scalable quantum computer involves overcoming the technical and physical obstacles of manipulating and maintaining stable quantum states. This research aims to identify and map potential pathways that could lead to the realization of scalable quantum computing. This research explores various approaches in Quantum Optics that can support scalability in quantum computing, focusing on innovations in quantum state control techniques, more efficient system design, and the development of new materials. The methods include comprehensive literature analysis, laboratory experiments, and mathematical modelling. The literature analysis aims to identify recent advances and shortcomings in current techniques. Experiments were conducted to test the feasibility of newly developed techniques in controlling quantum states, while mathematical modelling was used to predict system performance under various operational conditions. This study's results show that using phase and amplitude modulation techniques in quantum state settings offers increased stability and reduced errors. Additionally, new nano-based materials show the potential to enhance interactions between qubits, which is crucial for scalability. This research concludes that combining more advanced state control techniques with innovative materials could significantly advance the prospects for scalable quantum computing. Further research aimed at systems integration and automation of quantum state control is needed to overcome the remaining obstacles.]]>
