TY - GEN
T1 - A Study on the Impact of Temperature-Dependent Ferroelectric Switching Behavior in 3D Memory Architecture
AU - Parekh, Varun Darshana
AU - Xiao, Yi
AU - Xu, Yixin
AU - Zhao, Zijian
AU - Jiang, Zhouhang
AU - Biswas, Rudra
AU - George, Sumitha
AU - Ni, Kai
AU - Narayanan, Vijaykrishnan
N1 - Publisher Copyright:
© 2025 IEEE.
PY - 2025
Y1 - 2025
N2 - The flourishing development of neural networks that require exponentially growing amounts of data has presented an elevated demand for memory footprint. To address this, researchers have been exploring hardware accelerators with innovative memory architectures like 3D memory. These 3D memory architectures offer enhanced storage capacity and processing capabilities, at a cost of rising on-chip temperature during operation. Hafnium Zirconium Oxide (HZO) based Ferroelectric Random Access Memory (FeRAM) is a promising nonvolatile memory candidate in neural network hardware accelerators for its outstanding write performance and reliability. However, its implementation in the architecture regarding the temperature-dependent ferroelectric switching behavior has not been well studied. In this work, we study the thermal impacts on polarization switching through experimental devices and simulation results. We conduct the circuit and architecture-level simulations to showcase that one can exploit this temperature rise to reduce FeRAM's write voltage and write energy due to its unique temperature-activated polarization switching mechanisms. As the on-chip temperature increases to 351K (ambient temperature at 300K) due to neural network workloads, the access energy per bit can be reduced by 27.6% when a dynamic write voltage is applied.
AB - The flourishing development of neural networks that require exponentially growing amounts of data has presented an elevated demand for memory footprint. To address this, researchers have been exploring hardware accelerators with innovative memory architectures like 3D memory. These 3D memory architectures offer enhanced storage capacity and processing capabilities, at a cost of rising on-chip temperature during operation. Hafnium Zirconium Oxide (HZO) based Ferroelectric Random Access Memory (FeRAM) is a promising nonvolatile memory candidate in neural network hardware accelerators for its outstanding write performance and reliability. However, its implementation in the architecture regarding the temperature-dependent ferroelectric switching behavior has not been well studied. In this work, we study the thermal impacts on polarization switching through experimental devices and simulation results. We conduct the circuit and architecture-level simulations to showcase that one can exploit this temperature rise to reduce FeRAM's write voltage and write energy due to its unique temperature-activated polarization switching mechanisms. As the on-chip temperature increases to 351K (ambient temperature at 300K) due to neural network workloads, the access energy per bit can be reduced by 27.6% when a dynamic write voltage is applied.
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U2 - 10.1109/VLSID64188.2025.00080
DO - 10.1109/VLSID64188.2025.00080
M3 - Conference contribution
AN - SCOPUS:105000176137
T3 - Proceedings of the IEEE International Conference on VLSI Design
SP - 392
EP - 397
BT - Proceedings - 38th International Conference on VLSI Design, VLSID 2025 - held concurrently with 24th International Conference on Embedded Systems, ES 2025
PB - IEEE Computer Society
T2 - 38th International Conference on VLSI Design, VLSID 2025
Y2 - 4 January 2025 through 8 January 2025
ER -