Swiss Confederation,One step closer to quantum technologies: Fundamental quantum model recreated from nanographenes

One Step Closer to Quantum Technologies: Fundamental Quantum Model Recreated from Nanographenes

October 31, 2024

Swiss Confederation

Researchers at the Swiss Federal Institute of Technology in Lausanne (EPFL) have made a significant breakthrough in the field of quantum technologies by successfully recreating a fundamental quantum model using nanographenes. This breakthrough has the potential to pave the way for the development of new quantum computing and sensing devices.

Quantum Technologies

Quantum technologies are a new and rapidly emerging field that utilize the principles of quantum mechanics to develop new technologies. Quantum mechanics is the theory that governs the behavior of matter and energy at the atomic and subatomic level. It describes how particles can behave like waves and how they can be in multiple states at the same time.

Quantum technologies have the potential to revolutionize many fields, including computing, sensing, and communication. Quantum computers, for example, would be much faster and more powerful than classical computers. They could solve problems that are impossible to solve on classical computers, such as simulating complex chemical reactions or breaking modern encryption algorithms.

Nanographenes

Nanographenes are small, graphene-like materials that consist of a single layer of carbon atoms arranged in a hexagonal lattice. They are extremely small, with a typical size of only a few nanometers. Despite their small size, nanographenes have unique electronic and optical properties that make them ideal for use in quantum technologies.

Recreating the Quantum Model

In the latest study, the EPFL researchers recreated a fundamental quantum model using nanographenes. The model, known as the Hubbard model, describes the behavior of electrons in a crystal lattice. The Hubbard model is one of the most important models in quantum physics, and it has been used to understand a wide range of physical phenomena, such as superconductivity and magnetism.

The EPFL researchers recreated the Hubbard model by using nanographenes to simulate the crystal lattice. They used a technique called chemical vapor deposition to grow nanographenes on a substrate. The nanographenes were then patterned into the desired shape using electron beam lithography.

The researchers then used scanning tunneling microscopy to measure the electronic properties of the nanographenes. They found that the electronic properties of the nanographenes matched the predictions of the Hubbard model. This confirmed that the researchers had successfully recreated the Hubbard model using nanographenes.

Significance

The successful recreation of the Hubbard model using nanographenes is a significant breakthrough in the field of quantum technologies. It demonstrates that nanographenes can be used to simulate complex quantum systems. This opens up the possibility of using nanographenes to develop new quantum computing and sensing devices.

The researchers believe that their breakthrough could lead to the development of new quantum technologies that are smaller, faster, and more powerful than existing devices. These new technologies could have a major impact on a wide range of fields, including computing, sensing, and communication.


One step closer to quantum technologies: Fundamental quantum model recreated from nanographenes

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