Researchers, who continue their work at NIST (National Institute of Standarts and Technology), announced that they managed to create and display a pair of quantum points for the first time in history. The interaction between these islets, which we can call compressed electric charge islets, is not very similar to the phenomena previously studied in quantum physics and cannot be fully explained by existing models. The new alternative in quantum computers Our classic computers use a dual system. In other words, a bit has only two values: 1 and 0. In quantum computers, information is stored in qubits. Qubits can have more than one value at a time. Naturally, they can make larger transactions easier and faster. Electrons act in certain patterns according to their energy levels. Contrary to the models we learned in secondary school, electrons do not always move steadily, sometimes disappearing and reappearing. If these electrons are shared by two points and remain in a fixed range, qubits emerge. The NIST team, on the other hand, raised the voltage of the tip by keeping the ultra-sharp tip of the scanning tunneling microscope (STM) on an extremely cold graphene surface to create quantum points. Paired quantum point created for the first time The NIST team created structural irregularities between the atoms with its work, allowing energy channels and wells to be formed. These changes were observed when the applied magnetic field was brought between 4 and 8 tesla. Thanks to the STM tip used, the team managed to create dots of approximately 100 nanometer diameter. Thus, the researchers managed to completely view the point. Details of the building have been revealed. The work, signed by Daniel Walkup, Fereshte Ghahari, Christopher Gutiérrez, Kenji Watanabe, Takashi Taniguchi, Nikolai B. Zhitenev and Joseph A. Stroscio, has been published in the journal Physical Review B. Walkup, one of the researchers, said that the structure in this model cannot be explained by existing quantum physics theories. This may affect the future use of qubits.
