TY - JOUR
T1 - A Cryo-CMOS Controller with Class-DE Driver and DC Magnetic-Field Tuning for Quantum Computers Based on Color Centers in Diamond
AU - Fakkel, Niels
AU - Enthoven, Luc
AU - Yun, Jiwon
AU - Van Riggelen, Margriet
AU - Van Ommen, Hendrik Benjamin
AU - Schymik, Kai Niklas
AU - Bartling, Hans P.
AU - Katranara, Eftychia Tsapanou
AU - Tsapanou Katranara, E.
AU - Vollmer, Rene
AU - Taminiau, Tim H.
AU - Babaie, Masoud
AU - Sebastiano, Fabio
PY - 2024
Y1 - 2024
N2 - Striving toward a scalable quantum processor, this article presents the first cryo-CMOS quantum bit (qubit) controller targeting color centers in diamond. Color-center qubits enable a modular architecture that allows for the 3-D integration of photonics, cryo-CMOS control electronics, and qubits in the same package. However, performing quantum operations in a scalable manner requires large currents in the driving coils due to low coil-to-qubit coupling. Moreover, active calibration of the qubit Larmor frequency is required to compensate inhomogeneities of the bias magnetic field. To overcome these challenges, this work proposes both a cryo-CMOS alternating current (AC) controller consisting of a class-DE series-resonant driver and a DC current regulator (DC CR) that uses a triode-biased H-bridge for scalable low-power qubit operations. By experimentally validating the cryo-CMOS performance with a nitrogen-vacancy (NV) color-center qubit, the AC controller can drive a Rabi oscillation up to 2.5 MHz with a supply draw of 6.5 mA, and the DC CR can tune the Larmor frequency by ±9 MHz while driving up to ±20 mA in the bias coil. T
∗
2 coherence times up to 5.3μs and single-qubit gate fidelities above 98% are demonstrated with the cryo-CMOS control using Ramsey experiments and gate set tomography (GST), respectively. The results demonstrate the efficacy of the proposed cryo-CMOS chips and enable the development of a modular quantum processor based on color centers.
AB - Striving toward a scalable quantum processor, this article presents the first cryo-CMOS quantum bit (qubit) controller targeting color centers in diamond. Color-center qubits enable a modular architecture that allows for the 3-D integration of photonics, cryo-CMOS control electronics, and qubits in the same package. However, performing quantum operations in a scalable manner requires large currents in the driving coils due to low coil-to-qubit coupling. Moreover, active calibration of the qubit Larmor frequency is required to compensate inhomogeneities of the bias magnetic field. To overcome these challenges, this work proposes both a cryo-CMOS alternating current (AC) controller consisting of a class-DE series-resonant driver and a DC current regulator (DC CR) that uses a triode-biased H-bridge for scalable low-power qubit operations. By experimentally validating the cryo-CMOS performance with a nitrogen-vacancy (NV) color-center qubit, the AC controller can drive a Rabi oscillation up to 2.5 MHz with a supply draw of 6.5 mA, and the DC CR can tune the Larmor frequency by ±9 MHz while driving up to ±20 mA in the bias coil. T
∗
2 coherence times up to 5.3μs and single-qubit gate fidelities above 98% are demonstrated with the cryo-CMOS control using Ramsey experiments and gate set tomography (GST), respectively. The results demonstrate the efficacy of the proposed cryo-CMOS chips and enable the development of a modular quantum processor based on color centers.
KW - Calibration
KW - class-DE
KW - cryo-CMOS
KW - DC magnetic field biasing
KW - H-bridge
KW - Larmor frequency
KW - low-power DC current regulator (DC CR)
KW - microwave driver
KW - nitrogen-vacancy (NV) center
KW - output stage
KW - quantum computing
KW - resonator
KW - switch-mode amplifier
KW - system engineering
KW - triode
UR - http://www.scopus.com/inward/record.url?scp=85205287551&partnerID=8YFLogxK
U2 - 10.1109/JSSC.2024.3459392
DO - 10.1109/JSSC.2024.3459392
M3 - Article
AN - SCOPUS:85205287551
SN - 0018-9200
VL - 59
SP - 3627
EP - 3643
JO - IEEE Journal of Solid-State Circuits
JF - IEEE Journal of Solid-State Circuits
IS - 11
ER -