Advancements and Challenges in Quantum Technologies Using Low-Dimensional Systems

Quantum technologies based on low-dimensional systems have emerged as a field with immense potential for technological breakthroughs and innovation. Low-dimensional systems, such as two-dimensional materials, nanowires, molecular magnetic systems, and quantum dots, offer a unique platform for studying and exploiting quantum phenomena. Recent advancements in understanding and manipulating the quantum states of these systems have led to the development of novel quantum devices and technologies, including quantum batteries, transistors, sensors, and heat engines. Despite these advancements, several challenges remain, such as environmental interference, decoherence, and scalability, which must be addressed to realize the full potential of these technologies. This Research Topic aims to explore the latest advancements and innovations in quantum technologies based on low-dimensional systems, highlighting significant studies, ongoing debates, and the need for further investigation in this rapidly evolving field.

The collection intends to provide a comprehensive understanding of the quantum properties of low-dimensional systems and to develop novel techniques for manipulating and controlling these systems. The main objectives include addressing specific questions related to the scalability and error correction of quantum devices, exploring quantum algorithms and applications, and investigating methods to mitigate noise and decoherence. Additionally, the research will focus on the potential applications of these technologies in quantum computing, communication, and sensing, as well as the challenges faced in their development and implementation.

To gather further insights into the advancements and challenges in quantum technologies based on low-dimensional systems, we welcome articles addressing, but not limited to, the following themes:

- Low-dimensional materials for quantum applications: properties and fabrication
- Experimental and theoretical studies of low-dimensional quantum systems, including two-dimensional materials, nanowires, molecular magnetic systems, and quantum dots
- Quantum computing and communication based on low-dimensional systems:
- Quantum gates and qubit implementations
- Scalability and error correction
- Quantum algorithms and applications
- Quantum communication protocols
- Noise and decoherence mitigation
- Quantum computing architectures
- Quantum sensing and metrology:
- Quantum-enhanced measurements
- Quantum imaging
- Single-spin magnetometry
- Quantum capacitance sensors
- Optomechanical sensors
- Integration with classical sensing technologies
- Quantum batteries and energy harvesting:
- Quantum-enhanced energy storage
- Quantum coherence in energy harvesting
- Quantum materials for energy storage
- Quantum-inspired energy harvesting devices
- Quantum heat engines and thermodynamics: heat transfer, work extraction, and energy fluctuations in low-dimensional systems

We invite original research articles, review articles, perspective articles, and technical notes that provide novel insights and contribute significantly to the field of quantum technologies based on low-dimensional systems. Manuscripts should be written in clear and concise language, adhering to the highest standards of scientific rigor and ethics.