posted on 2021-12-08, 16:13authored byMohammad Karbalaei
Akbari, Serge Zhuiykov
The
assembly of geometrically complex and dynamically active liquid
metal/semiconductor heterointerfaces has drawn extensive attention
in multidimensional electronic systems. In this study the chemovoltaic
driven reactions have enabled the microfluidity of hydrophobic galinstan
into a three-dimensional (3D) semiconductor matrix. A dynamic heterointerface
is developed between the atomically thin surface oxide of galinstan
and the TiO2–Ni interface. Upon the growth of Ga2O3 film at the Ga2O3–TiO2 heterointerface, the partial reduction of the TiO2 film was confirmed by material characterization techniques. The
conductance imaging spectroscopy and electrical measurements are used
to investigate the charge transfer at heterointerfaces. Concurrently,
the dynamic conductance in artificial synaptic junctions is modulated
to mimic the biofunctional communication characteristics of multipolar
neurons, including slow and fast inhibitory and excitatory postsynaptic
responses. The self-rectifying characteristics, femtojoule energy
processing, tunable synaptic events, and notably the coordinated signal
recognition are the main characteristics of this multisynaptic device.
This novel 3D design of liquid metal–semiconductor structure
opens up new opportunities for the development of bioinspired afferent
systems. It further facilitates the realization of physical phenomena
at liquid metal–semiconductor heterointerfaces.