One of the most popular topics of recent years is quantum computers. The development process of these computers is very complex and their structure is very different from traditional computers. Scientists from Oxford have developed a nano-scale technology tool that will allow similarities between the two computer versions.
The main feature of this tool is that the working principle can work with both electrons and photons. The computers in our homes use electrons, while the quantum computers that make calculations on structures called cubits use photons.
In fact, studies have continued to use light for information transfer since the 1950s , but there is a very serious and structural problem here: the wavelength of light is greater than the wavelength of the electron. While electric chips are efficient in small sizes, systems using photons require more space.
The new device manages to compress the light to a smaller size. It does this in a way called surface plasmon polarization . Using the refractive index of light near the surface, light can be compressed. Thus, electric chips and photon chips can be used together . This opens the way for devices to work with both electrons and photons.
Nikolas Farmakidis , co-author of the research, says this discovery is a very promising discovery for computers and especially for areas with high computing capacity. There are many different areas where this technology can be used. The focus is on structures that require high processing power , such as artificial intelligence systems. The new vehicle can take current metal oxide semiconductor production and MOFSET’s transistor systems to the next level.
Nathan, one of the authors of the study Youngblood, the possibilities for using the new technology in describing this technology came to -akl somehow- frequently y totally different when you say intelligence in to use, light-based believes that photonic computers are the future CMOS systems able paired with the electric system, he said.
The results of the research were published in the journal Science Advances .