TY - JOUR
T1 - Back-End-of-Line Integration of Synaptic Weights using HfO2/ZrO2 Nanolaminates
AU - Bégon-Lours, Laura
AU - Slesazeck, Stefan
AU - Falcone, Donato Francesco
AU - Havel, Viktor
AU - Hamming-Green, Ruben
AU - Fernandez, Marina Martinez
AU - Morabito, Elisabetta
AU - Mikolajick, Thomas
AU - Offrein, Bert Jan
N1 - Publisher Copyright:
© 2024 The Authors. Advanced Electronic Materials published by Wiley-VCH GmbH.
PY - 2024/5
Y1 - 2024/5
N2 - In artificial neural networks, the “synaptic weights” connecting the neurons are adjusted during the training. Beyond silicon, functionalizing the back-end-of-line (BEOL) of CMOS circuits with novel materials is a key enabler for deploying neural network accelerators. The hardware implementation of the synaptic weights requires linear and reprogrammable resistive elements. In ferroelectric tunnel junctions, the resistance is programmed by controlling the configuration of the ferroelectric domains with electrical pulses. From ferroelectric HfZrO4 to HfO2–ZrO2 nanolaminates (NL), the crystallization temperature lowers below the upper limit of 400 °C required for CMOS BEOL. The device footprint is reduced, and the maximum-to-minimum conductance ratio increases from 7 to 32. Operated with pulses in the ultra-fast (20 ns) and biological (500 µs) timescales, the synaptic plasticity exhibits several regimes. Dynamic hysteresis mode characterization after up to 1011 switching cycles indicates the coexistence of ferroelectric and non-ferroelectric effects such as defect rearrangement. Temperature-dependent transport measurements in the Ohmic (linear) regime support these conclusions. Multi-level resistive switching is achieved in HfO2–ZrO2 NL co-integrated to CMOS in the BEOL. 1T-1R operation is demonstrated, paving the way for hardware implementation of synaptic weights for in-memory neuromorphic computing.
AB - In artificial neural networks, the “synaptic weights” connecting the neurons are adjusted during the training. Beyond silicon, functionalizing the back-end-of-line (BEOL) of CMOS circuits with novel materials is a key enabler for deploying neural network accelerators. The hardware implementation of the synaptic weights requires linear and reprogrammable resistive elements. In ferroelectric tunnel junctions, the resistance is programmed by controlling the configuration of the ferroelectric domains with electrical pulses. From ferroelectric HfZrO4 to HfO2–ZrO2 nanolaminates (NL), the crystallization temperature lowers below the upper limit of 400 °C required for CMOS BEOL. The device footprint is reduced, and the maximum-to-minimum conductance ratio increases from 7 to 32. Operated with pulses in the ultra-fast (20 ns) and biological (500 µs) timescales, the synaptic plasticity exhibits several regimes. Dynamic hysteresis mode characterization after up to 1011 switching cycles indicates the coexistence of ferroelectric and non-ferroelectric effects such as defect rearrangement. Temperature-dependent transport measurements in the Ohmic (linear) regime support these conclusions. Multi-level resistive switching is achieved in HfO2–ZrO2 NL co-integrated to CMOS in the BEOL. 1T-1R operation is demonstrated, paving the way for hardware implementation of synaptic weights for in-memory neuromorphic computing.
KW - back-end-of-line
KW - CMOS
KW - ferroelectrics
KW - hafnia, nanolaminates
KW - superlattices
KW - synaptic weights
UR - http://www.scopus.com/inward/record.url?scp=85184200569&partnerID=8YFLogxK
U2 - 10.1002/aelm.202300649
DO - 10.1002/aelm.202300649
M3 - Article
AN - SCOPUS:85184200569
SN - 2199-160X
VL - 10
JO - Advanced electronic materials
JF - Advanced electronic materials
IS - 5
M1 - 2300649
ER -