Electron spins confined in semiconductor quantum dots (QDs) are one of potential
candidates for physical implementation of scalable quantum information processing …

The mathematical equivalence between finite state stochastic machine and non-dissipative
and dissipative quantum tight-binding and Schrödinger model is derived. Stochastic Finite …

Analytical solutions for a tight-binding model are presented for a position-based qubit and N
interacting qubits realized by quasi-one-dimensional network of coupled quantum dots …

Non-local communication between position-based qubits is described for a system of a
quantum electromagnetic resonator entangled to two semiconductor electrostatic qubits via …

We describe a quantum computing hardware paradigm that exploits the current scaling
achievements of mainstream CMOS technology. Just like in a small IC chip, where a single …

Analytical solutions describing quantum swap and Hadamard gate are given with the use of
tight-binding approximation. Decoherence effects are described analytically for 2 interacting …

The analysis of superconducting nanowires placed in different electromagnetic
environments is presented in the framework of Ginzburg-Landau model. First domain of …

A derivation of a tight-binding model from Schrödinger formalism for various topologies of
position-based semiconductor qubits is presented in the case of static and time-dependent …

Detection of moving charge in free space is presented in the framework of single electron
CMOS devices. It opens the perspective for construction of new type detectors for beam …

A semiconductor‐based charge qubit, confined in double quantum dots, can be a platform to
implement quantum computing. However, it suffers severely from charge noises. Here, a …