TY - GEN
T1 - A 0.16-3.7GHz Ultra-Compact Noise-Canceling Cryogenic Low-Noise Amplifier at 4 K using 16nm FinFET Technology for Qubit Readout
AU - Chen, Runzhou
AU - Mani, Hamdi
AU - Marsh, Phil
AU - Al Hadi, Richard
AU - Shrestha, Pragya
AU - Campbell, Jason
AU - Chen, Christopher
AU - Chien, Hao Yu
AU - Chang, Mau Chung Frank
N1 - Publisher Copyright:
© 2024 IEEE.
PY - 2024
Y1 - 2024
N2 - The rapid evolution of quantum computing drives the demand for CMOS cryogenic electronics to support qubit scaling (Fig. 1). In this regard, we present a 16 nm FinFET technology-based cryogenic low noise amplifier (LNA) crucial for enhancing qubit readout fidelity [1]. FinFETs offer fewer temperature deviations compared to planar generations due to improved gate control [ 2 - 3 ]. The choice of the 16 nm technology node maximizes modern digital capabilities and enables superior system-on-chip (SoC) integration for quantum applications. Our circuit design is based on the cryogenic FinFET device gain and noise temperature characterization at 20 K (Fig. 2) with 50-Ohm ports and the given device models down to -40°C (Fig. 3). Although transistor operation at low temperatures follows standard theory, deviations occur due to factors such as dopant freeze-out and subthreshold slope saturation caused by band tails [4]. This underscores the need for accurate device characterization at low temperatures during the early design stages. Initial results at 4 K suggest the FinFET LNA's potential for low noise, low power, and high gain operation.
AB - The rapid evolution of quantum computing drives the demand for CMOS cryogenic electronics to support qubit scaling (Fig. 1). In this regard, we present a 16 nm FinFET technology-based cryogenic low noise amplifier (LNA) crucial for enhancing qubit readout fidelity [1]. FinFETs offer fewer temperature deviations compared to planar generations due to improved gate control [ 2 - 3 ]. The choice of the 16 nm technology node maximizes modern digital capabilities and enables superior system-on-chip (SoC) integration for quantum applications. Our circuit design is based on the cryogenic FinFET device gain and noise temperature characterization at 20 K (Fig. 2) with 50-Ohm ports and the given device models down to -40°C (Fig. 3). Although transistor operation at low temperatures follows standard theory, deviations occur due to factors such as dopant freeze-out and subthreshold slope saturation caused by band tails [4]. This underscores the need for accurate device characterization at low temperatures during the early design stages. Initial results at 4 K suggest the FinFET LNA's potential for low noise, low power, and high gain operation.
UR - https://www.scopus.com/pages/publications/85201057733
U2 - 10.1109/DRC61706.2024.10605367
DO - 10.1109/DRC61706.2024.10605367
M3 - Contribution to conference proceedings
AN - SCOPUS:85201057733
T3 - Device Research Conference - Conference Digest, DRC
BT - DRC 2024 - 82nd Device Research Conference
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 82nd Device Research Conference, DRC 2024
Y2 - 24 June 2024 through 26 June 2024
ER -