Recent Developments in Quantum‐Circuit Refrigeration

Abstract: The recent progress in direct active cooling of the quantum‐electric degrees of freedom in engineered circuits, or quantum‐circuit refrigeration is reviewed. In 2017, the discovery of a quantum‐circuit refrigerator (QCR) based on photon‐assisted tunneling of quasiparticles through normal‐metal–insulator–superconductor junctions inspired a series of experimental studies demonstrating the following main properties: i) the direct‐current (dc) bias voltage of the junction can change the QCR‐induced damping rate of… Show more

“…The EP-2 used for stabilization is thus achieved with κ 2 /(2π) ≈ 5.66 MHz and κ 3 /(2π) = 1.0 kHz, while the EP-3 with κ 2 /(2π) ≈ 2.83 MHz and κ 3 /(2π) ≈ 5.66 MHz. Even though the almost four-orders-of-magnitude tunability required to interchange between this particular EP-2 and the EP-3 may be technically challenging, the maximum achievable decay rates with the QCR are beyond the ones considered here and their demonstrated on/off ratios are close to these requirements [23].…”

“…The decay rates of resonators R2 and R3 can be controlled by quantum-circuit refrigerators (QCRs) placed at the resonator input ports. Each QCR is comprised of a normalmetal-insulator-superconducting (NIS) junction and can remove photons incoherently from the system mediated by electron tunneling at specific bias-voltage pulses [22,23].…”

“…4b. Using the lower envelopes of the fitting functions (23) in Eq. ( 24), one can estimate the quasi-stabilization time as…”

“…In circuit quantum electrodynamics (cQED), for example, efforts have been made to integrate devices with in-situ-tunable dissipation to prepare specific quantum states [5][6][7][8][9][10][11][12], produce fast reset [13][14][15][16][17][18][19][20][21][22][23][24], and to exploit the potential benefits of open-system degeneracies, referred to as exceptional points (EPs) [17,21,[25][26][27][28][29]. In contrast to Hermitian degeneracies, EPs induce the coalescence of eigenvalues and eigenvectors of the dynamical matrix governing the open-system evolution leading to critical dynamics manifested by polynomial solutions in time [30,31].…”

Exceptional-point-assisted entanglement, squeezing, and reset in a chain of three superconducting resonators

“…The EP-2 used for stabilization is thus achieved with κ 2 /(2π) ≈ 5.66 MHz and κ 3 /(2π) = 1.0 kHz, while the EP-3 with κ 2 /(2π) ≈ 2.83 MHz and κ 3 /(2π) ≈ 5.66 MHz. Even though the almost four-orders-of-magnitude tunability required to interchange between this particular EP-2 and the EP-3 may be technically challenging, the maximum achievable decay rates with the QCR are beyond the ones considered here and their demonstrated on/off ratios are close to these requirements [23].…”

“…The decay rates of resonators R2 and R3 can be controlled by quantum-circuit refrigerators (QCRs) placed at the resonator input ports. Each QCR is comprised of a normalmetal-insulator-superconducting (NIS) junction and can remove photons incoherently from the system mediated by electron tunneling at specific bias-voltage pulses [22,23].…”

“…4b. Using the lower envelopes of the fitting functions (23) in Eq. ( 24), one can estimate the quasi-stabilization time as…”

“…In circuit quantum electrodynamics (cQED), for example, efforts have been made to integrate devices with in-situ-tunable dissipation to prepare specific quantum states [5][6][7][8][9][10][11][12], produce fast reset [13][14][15][16][17][18][19][20][21][22][23][24], and to exploit the potential benefits of open-system degeneracies, referred to as exceptional points (EPs) [17,21,[25][26][27][28][29]. In contrast to Hermitian degeneracies, EPs induce the coalescence of eigenvalues and eigenvectors of the dynamical matrix governing the open-system evolution leading to critical dynamics manifested by polynomial solutions in time [30,31].…”

Exceptional-point-assisted entanglement, squeezing, and reset in a chain of three superconducting resonators

“…In reservoir engineering, the idea is to turn the usually detrimental effects of dissipation into a resource. In this article, we demonstrate that the flexibility to engineer dissipation in a controllable manner in transmon circuits [41][42][43][44][45] can be utilized for realizing NH topological quantum phases. In our proposal, the NH topological phase is created by introducing a spatial modulation of dissipation [7,46] in the one-dimensional Bose-Hubbard transmon chain [47,48], where the dissipation strength in each transmon is controlled by the tunable coupling of the transmon to a quantum circuit refrigerator (QCR) [41][42][43][44] (see Fig.…”

Non-Hermitian topological quantum states in a reservoir-engineered transmon chain

Applications of Superconductor–Normal Metal Interfaces