Neuroelectronics and Memristive Nanomaterials Research Laboratory (NEUROMENA)

Scientific results:

A mathematical model of the formation of titanium oxide nanostructures by local anodic oxidation was developed. Based on the developed mathematical model, a theoretical study of the influence of the formation modes of oxide nanostructures on their geometric parameters, as well as the distribution of the chemical composition of the oxide and oxygen vacancies within the nanostructure, was conducted.

A model for the formation of biocompatible memristive nanomaterials based on metal oxide films obtained by pulsed laser deposition was developed, allowing for the calculation of the film thickness distribution profile on the substrate surface, taking into account the constructive and technological parameters of the equipment used.

The modeling of resistive switching in biocompatible memristive nanomaterials based on metal oxide films, gradient nanocomposite oxide films, oxide nanostructures, and 2D materials was performed. A mathematical model of the formation and destruction of nanoscale conduction channels (filaments) in the titanium oxide nanostructure was developed, considering the processes of generation and migration of oxygen vacancies within the nanostructure under the influence of an external electric field.

Experimental studies on the synthesis patterns of biocompatible memristive nanomaterials based on metal oxide films and oxide nanostructures by pulsed laser deposition were conducted. The influence of the number of pulses, thickness, oxygen pressure, annealing temperature, and laser pulse frequency on the parameters of metal oxide films was established.

A mathematical model of neuro-like dynamics of biocompatible memristive structures and a neural generator model, representing a modified FitzHugh-Nagumo neuron with complex threshold excitation and memristor nonlinearity, were developed. The proposed neural generator model with memristive nonlinearity reproduces the complex threshold response dynamics, which is advantageous for designing spike-based neuromorphic systems.

Studies on the structure, phase, and elemental composition of biocompatible memristive nanomaterials based on metal oxide films obtained by pulsed laser deposition using X-ray diffraction (XRD), energy-dispersive X-ray spectroscopy (EDX), and X-ray photoelectron spectroscopy (XPS) methods were conducted, establishing the influence patterns of pulsed laser deposition modes on the structural properties of BaTiO₃, LiNbO₃, ZnO, and VO₂.

The resistive switching in transparent memristor structures based on ZnO and TiO₂ films obtained by magnetron sputtering at room temperature in an oxygen-free environment on glass substrates for use in neuromorphic systems, including dynamic machine vision systems, transparent, and flexible electronics, was investigated. Studies were also conducted on the formation of memristor structures by magnetron sputtering with varying ZnO film thicknesses and different electrode materials on silicon substrates. Based on the obtained experimental results, a technological route for forming transparent memristor structures by magnetron sputtering (MF and RF modes) at room temperature in an oxygen-free environment was developed and optimized.

Regularities of the influence of dimensional effects on resistive switching in titanium oxide nanostructures obtained by LAO method have been established. The analysis of the data showed that this method allows for the controlled formation of memristor structures with switching voltages in a wide range of values. The result demonstrates the absence of parasitic connections during resistive switching in non-forming titanium ONC and allows for significant simplification of the memristor array manufacturing technology by forming a common oxide layer for all ReRAM elements, rather than for each element individually.

A study of the temporal stability of the surface charge of TiO₂ films was conducted. Based on the results, time dependence of voltage and charge region size were constructed. It was shown that the voltage decreased from 320±21 mV to 22±5 mV over 90 minutes, and the structure size increased from 3.43±0.12 μm to 4.12±0.14 μm.

Experimental studies of multilevel resistive switching in nanocrystalline films of zinc oxide, titanium oxide, and hafnium oxide have been conducted. Analysis of the results showed that TiO₂, HfO₂, and ZnO films exhibit multilevel resistive switching. Increasing the voltage sweep and current compliance leads to an increase in the number of resistive states.

The influence of top electrode materials on the resistive switching of memristor structures based on nanocrystalline zinc oxide films has been investigated. It was shown that memristor structures with a top electrode made of carbon (C) exhibit the highest RHRS/RLRS ratio, while structures with a top electrode made of platinum (Pt) demonstrate the lowest switching voltage values. Thus, the choice of top electrode material should be determined based on the initial requirements when manufacturing neuromorphic structures: if the priority is maximizing the RHRS/RLRS ratio, then the top electrodes should be made of carbon (C); if the priority is energy efficiency, then they should be made of platinum (Pt).

The influence of temperature on the main parameters of memristor structures based on nanocrystalline zinc oxide film has been investigated. It was shown that memristor structures based on nanocrystalline zinc oxide film are capable of functioning in the temperature range from 25 °C to 120 °C, which is important for the operation of future elements of neuromorphic structures in adverse environmental conditions.

The influence of top electrode materials on the resistive switching of titanium oxide-based memristor structures has been studied. Analysis of the results showed that the nanostructures formed on the surface of the Ti film exhibit a stable resistive switching effect without the need for additional forming operations. The material of the top contact significantly affected the current-voltage characteristics of the Ti/TiO2/top electrode structure. It was shown that using Pt as the top contact resulted in a symmetrical current-voltage characteristic, while using TiN and C as top contacts resulted in asymmetrical current-voltage characteristics. Using Pt as the top contact reduces the power consumption of the Ti/TiO2/top electrode structure compared to TiN, and also reduces power consumption compared to C.

An adaptive model of a memristive device Au/Zr/SiO₂/TiN/Ti/SiO₂/Si demonstrating stochastic resistive switching characteristics under the influence of a neuromorphic signal, which ensures adaptive coupling and synchronization of neuromorphic FitzHugh-Nagumo memristive oscillators, has been experimentally investigated. 

Education and personnel occupational retraining:

During the laboratory's operation, its employees have successfully completed 20 courses of additional professional education and advanced training courses.

A new main professional educational program of higher education for students in the field of study 11.04.04 "Electronics and Nanoelectronics," specializing in "Neuromorphic and Neurohybrid Artificial Intelligence Systems," has been developed and is being implemented at the Southern Federal University. Qualification: Master's degree.

The laboratory staff have successfully habilitated 6 bachelor's theses, 6 master's theses, and 2 candidate dissertations in the field of scientific research.

Cooperation:

1. Chandigarh University
2. Lovely Professional University
3. N. I. Lobachevsky State University of Nizhny Novgorod
4. Molecular Electronics Research Institute
5. Immanuel Kant Baltic Federal University
6. Vladimir State University
7. Skolkovo Institute of Science and Technology