Abstract: A method and a device for determining a nucleotide sequence are proposed. The method comprises immobilizing circularized fragments of a nucleic acid and a polymerase on a sensor surface and adding a mixture of unlabeled nucleotides onto the sensor surface. Moreover, in the mixture added, the nucleotides of each type are present in their own concentration, which differs from the concentrations of the other three types of nucleotides. The time intervals between each of the charge separation events are determined and the registration steps for each nucleotide are repeated, regardless of the type of nucleotides. The nucleotide sequence of a nucleic acid molecule is determined by the analysis of the time intervals between each of the charge separation events registered, which result from the insertion, facilitated by the polymerase, of said unlabeled nucleotides into the growing nucleic acid chain.

Abstract: A method and a device for determining a nucleotide sequence are proposed. The method comprises immobilising looped fragments of a nucleic acid and a polymerase on a sensor surface and adding a mixture of unlabelled nucleotides onto the sensor surface. Moreover, in the mixture added, one nucleotide type is present at a much lower concentration compared to the other nucleotides. Time intervals between each of the charge separation events are determined and the mixture addition and the registration steps are repeated. Moreover, at each repetition, the nucleotide type present at a much lower concentration compared to the other nucleotides in the mixture added is changed. The nucleotide sequence of a nucleic acid molecule is determined by the analysis of the time intervals between each of the charge separation events registered, which result from the insertion, facilitated by the polymerase, of said unlabelled nucleotides into the growing nucleic acid chain.

Abstract: A method and a device for determining a nucleotide sequence are proposed. The method comprises immobilising looped fragments of a nucleic acid and a polymerase on a sensor surface and adding a mixture of unlabelled nucleotides onto the sensor surface. Moreover, in the mixture added, one nucleotide type is present at a much lower concentration compared to the other nucleotides. Time intervals between each of the charge separation events are determined and the mixture addition and the registration steps are repeated. Moreover, at each repetition, the nucleotide type present at a much lower concentration compared to the other nucleotides in the mixture added is changed. The nucleotide sequence of a nucleic acid molecule is determined by the analysis of the time intervals between each of the charge separation events registered, which result from the insertion, facilitated by the polymerase, of said unlabelled nucleotides into the growing nucleic acid chain.

Abstract: The tunnel-effect device comprises an input electrode 3, an output electrode 4, and N control electrodes 5 separated with tunneling barriers, the latter barriers and the interbarrier space therein appear as an ordered structure of molecules and clusters establishing tunneling junctions; each control electrode 5 is located in the region of the ordered structure of molecules and clusters 2. The dimensions and properties of the molecules and clusters provide for single-electron correlated electron tunneling at a relatively high (room) temperature. The tunnel-effect device functions on the base of controlled correlated electron tunneling. Possibility of controlling the tunneling current opens the way to constructing various electronic gate circuits on the base of single-electron tunneling junctions and hence to preparing single-electron analog and digital devices, in particular, high-sensitivity sensors.