@misc{10481/91823,
year = {2024},
month = {4},
url = {https://hdl.handle.net/10481/91823},
abstract = {Memristors are devices in which the conductance state can be alternately switched between a high and
a low value by means of a voltage scan. In general, systems involving a chemical inductor mechanism as
solar cells, asymmetric nanopores in electrochemical cells, transistors, and solid state memristive
devices, exhibit a current increase and decrease over time that generates hysteresis. By performing small
signal ac impedance spectroscopy, we show that memristors, or any other system with hysteresis relying
on the conductance modulation effect, display intrinsic dynamic inductor-like and capacitance-like
behaviours in specific input voltage ranges. Both the conduction inductance and the conduction
capacitance originate in the same delayed conduction process linked to the memristor dynamics and
not in electromagnetic or polarization effects. A simple memristor model reproduces the main features
of the transition from capacitive to inductive impedance spectroscopy spectra, which causes a nonzero
crossing of current–voltage curves.},
organization = {European Research Council (ERC)
via Horizon Europe Advanced Grant, grant agreement no.
101097688 (‘‘PeroSpiker’’)},
organization = {Projects
PID2022-139586NB-C41 and PID2022-139586NB-C44
funded by MCIN/AEI/10.13039/501100011033 and FEDER, EU.},
publisher = {Royal Society of Chemistry},
title = {Hysteresis in memristors produces conduction inductance and conduction capacitance effects},
doi = {10.1039/D4CP00586D},
author = {Bisquert, Juan and Roldán Aranda, Juan Bautista and Miranda, Enrique},
}