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Circuit quantum electrodynamics

Circuit quantum electrodynamics (cQED) is a field of quantum physics that explores the strong, coherent interactions between superconducting nonlinear circuits—serving as artificial atoms or qubits—and quantized microwave electromagnetic fields confined in high-quality resonators, enabling precise control and measurement of quantum states at the single-photon and single-qubit level. At its core, cQED leverages the Jaynes-Cummings model to describe the coupling between a two-level qubit system and a harmonic oscillator representing the cavity mode, with the coupling strength g typically exceeding the dissipation rates of both the qubit (\gamma) and the cavity (\kappa) to achieve the strong-coupling regime. Superconducting qubits, such as transmons featuring Josephson junctions, exhibit anharmonicity that allows selective addressing of quantum transitions, while cavities—often implemented as coplanar waveguides or three-dimensional structures—provide long photon lifetimes with quality factors up to $10^8 or higher. Key operational regimes include the resonant regime for direct energy exchange and the dispersive regime, where detuning between qubit and cavity frequencies enables qubit state readout via cavity frequency shifts without destroying the qubit coherence. The field emerged from early observations of quantum effects in Josephson junctions in the , but gained momentum in the late 1990s with demonstrations of coherent qubit oscillations. Landmark achievements include the 2004 realization of strong coupling through vacuum Rabi splitting in superconducting systems, confirming the circuit analog of atomic cavity QED. Subsequent advances encompassed dispersive readout protocols in 2006, ultrastrong coupling regimes approaching g/\omega_q \sim 0.1 by 2010, and high-fidelity quantum operations, such as single-qubit gates with fidelities exceeding 99.9% and two-qubit entangling gates like the cross-resonance interaction. These developments have propelled cQED to the forefront of experimental quantum physics over the past two decades. cQED architectures underpin scalable platforms, facilitating universal gate sets, error-corrected logical s, and demonstrations of quantum advantage in systems with over 1000 s as of 2023. Beyond computing, they enable quantum simulations of many-body physics, single-photon nonlinearities for , and hybrid interfaces with other quantum systems like spins or photons, with applications in quantum networks and sensing. Ongoing challenges include mitigating decoherence from material losses and scaling to fault-tolerant regimes, driving innovations in designs and cryogenic control techniques.

Components

Superconducting Resonators

Superconducting resonators form the core photonic elements in circuit quantum electrodynamics (cQED), acting as low-loss cavities for storing and transmitting at gigahertz frequencies. These devices leverage the zero-resistance properties of superconductors at cryogenic temperatures to achieve extremely high quality factors, enabling coherent photon lifetimes on the order of microseconds or longer. In cQED architectures, resonators provide the electromagnetic environment for strong light-matter interactions while minimizing decoherence from . Two primary types of superconducting resonators are employed: lumped-element LC circuits and distributed transmission-line structures. Lumped LC resonators, composed of discrete inductors (often spiral or geometries) and capacitors ( or parallel-plate), model the resonator as a simple with resonance frequency f_r = \frac{1}{2\pi \sqrt{[LC](/page/LC)}}, where L is and C is ; they are suitable for compact designs at lower frequencies but are less common in high-frequency cQED due to challenges in achieving uniform fields. In contrast, (CPW) resonators, which are planar distributed elements etched into a thin superconducting film, dominate cQED implementations for their ease of integration and ability to support well-defined modes over millimeter scales. CPW resonators typically adopt quarter-wavelength (\lambda/4) or half-wavelength (\lambda/2) configurations to define the fundamental mode. In a \lambda/2 CPW, the central conductor of length L is open at both ends and flanked by ground planes, yielding a resonance frequency f_r = \frac{c}{2L \sqrt{\epsilon_{\rm eff}}}, where c is the speed of light in vacuum and \epsilon_{\rm eff} is the effective relative permittivity of the substrate (approximately 5.4 for high-resistivity silicon and 6.0 for sapphire). The \lambda/4 variant, shorted at one end and open at the other, has f_r = \frac{c}{4L \sqrt{\epsilon_{\rm eff}}} for its fundamental (odd) mode, offering voltage antinodes at the open end ideal for capacitive coupling. Fabricated from thin films of type-I or type-II superconductors such as aluminum (Al, thickness ~200 nm, T_c \approx 1.2 K), (Nb, T_c \approx 9.2 K), or (Ta, T_c \approx 4.5 K), these resonators are deposited on low-loss substrates like high-resistivity (\rho > 1 k\Omega·cm) or c-plane to suppress losses from two-level systems. Aluminum on has demonstrated internal factors Q_i > 10^7 at high powers and Q_i > 10^6 near single-photon levels around 4-6 GHz, limited primarily by and interfaces rather than . -titanium (NbTiN) variants achieve Q > 10^6 even at single-photon powers by mitigating two-level system losses through removal or grooved geometries. Recent advances as of 2025 include spiral geometries in superconducting resonators achieving intrinsic factors approaching $10^7 and -based CPW resonators with enhanced performance, further improving single-photon . The high Q factors (typically > 10^6) translate to photon decay rates \kappa < 1 MHz at 4-8 GHz resonances, ensuring long coherence times (T \approx Q / \omega > 50 μs) crucial for high-fidelity photon storage in cQED. This low loss arises from the superconducting gap suppressing excitations below 20 operating temperatures. Fabrication begins with substrate preparation, including and ion milling to remove contaminants, followed by superconducting film deposition via sputtering (for Nb or Ta) or electron-beam evaporation (for ) in . Patterning employs with , followed by (e.g., SF₆/O₂ for , CF₄/O₂ for Ta) and lift-off in solvents to define the CPW geometry with center conductor widths of 3-15 μm for (~50 \Omega). Post-fabrication annealing at 200-850°C in oxygen ambient further reduces interface losses by smoothing metal-dielectric boundaries.

Three-Dimensional Superconducting Resonators

In addition to planar designs, three-dimensional () superconducting resonators play a vital role in cQED, providing superior isolation from surface losses and higher quality factors. These are typically machined from bulk superconducting materials like high-purity aluminum or , forming cavities such as rectangular, , or reentrant geometries. For example, qubits are often housed in such cavities, where the is capacitively coupled through an . Aluminum cavities achieve internal quality factors of $10^6 to $10^7, while cavities can exceed $10^8, enabling times up to several milliseconds at millikelvin temperatures. These structures minimize participation of lossy surfaces and two-level systems in dielectrics, making them ideal for dispersive readout and applications. Fabrication involves precision milling or , followed by surface treatment to reduce losses. As of 2025, cavities continue to support record-long in hybrid quantum systems.

Artificial Atoms and Qubits

Artificial atoms in circuit quantum electrodynamics (cQED) are superconducting nonlinear circuit elements that emulate the energy level structure of natural atoms, providing the anharmonicity necessary for two-level behavior. These devices, typically based on Josephson junctions, introduce discrete energy levels that can be coupled to photons in superconducting resonators, enabling strong light-matter interactions at the single-quantum level. The development of these artificial atoms began with charge qubits, such as the Cooper-pair box, which consists of a small superconducting connected to a via a and capacitively gated to control the offset charge. In this design, the qubit states correspond to different numbers of excess Cooper pairs on the , but it suffers from high sensitivity to charge noise, limiting times to nanoseconds. To mitigate this, the qubit was introduced, featuring a shunt capacitance across the Josephson junction that increases the total capacitance and reduces charge sensitivity by operating in the regime where the Josephson energy E_J greatly exceeds the charging energy E_C (E_J / E_C \gg 1). The Hamiltonian is given by H = 4 E_C (n - n_g)^2 - E_J \cos \phi, where n is the number of Cooper pairs, n_g is the gate-induced offset charge, \phi is the phase across the , E_C = e^2 / 2 C_\Sigma with total capacitance C_\Sigma, and E_J is the Josephson energy. This design yields times exceeding 1 ms in implementations as of 2025, a significant improvement over early charge qubits. Flux qubits represent another class of artificial atoms, formed by a superconducting interrupted by three or four Josephson junctions, where the qubit states are clockwise and counterclockwise persistent currents. These devices are biased to a flux sweet spot at half a (\Phi = \Phi_0 / 2), minimizing first-order sensitivity to flux noise and achieving times on the order of tens of microseconds. A variant, the fluxonium qubit, incorporates a large geometric (superinductance) in series with a Josephson junction shunted by a small junction, further suppressing charge noise through a low plasma frequency and multilevel structure, with reported times up to 1 ms. The effective dipole moments of these superconducting artificial atoms are up to $10^3 to $10^5 times larger than those of atoms, arising from their micrometer-scale dimensions compared to atomic scales. This enhancement enables vacuum Rabi coupling strengths g / 2\pi \approx 100 MHz between the and photons, facilitating the strong-coupling regime essential for cQED. Readout of these s is typically achieved through the dispersive interaction, where the qubit state induces a frequency shift \chi in the (on the order of 1-10 MHz), allowing state discrimination via without direct qubit excitation.

Theoretical Framework

Jaynes-Cummings Model

The Jaynes-Cummings model provides the foundational theoretical description of the interaction between a single two-level quantum system () and a single mode of a quantized in circuit quantum electrodynamics (cQED). Adapted from to superconducting circuits, it captures the coherent exchange of excitations between an artificial atom and a , enabling the strong coupling regime where quantum effects dominate. This model assumes the qubit can be approximated as a two-level system and the resonator as a , with their coupling mediated by the circuit's capacitive or inductive interactions. The of the Jaynes-Cummings model in cQED is derived through circuit quantization, where the voltage and current variables in the of the superconducting circuit are promoted to operators satisfying commutation relations. For a resonator modeled as an , the or charge operators are mapped to bosonic a^\dagger and a, yielding the free resonator term \hbar \omega_r a^\dagger a, with \omega_r the resonator frequency. The qubit, such as a transmon or Cooper pair box, is treated as a nonlinear inductor (Josephson junction) truncated to two levels, leading to the qubit term (\hbar \omega_q / 2) \sigma_z, where \omega_q is the qubit transition frequency and \sigma_z is the Pauli-z operator. The interaction arises from the cross-term in the charging or energy, resulting in the full : H = \hbar \omega_r a^\dagger a + \frac{\hbar \omega_q}{2} \sigma_z + \hbar g (\sigma_+ a + \sigma_- a^\dagger), where g is the vacuum coupling strength, and \sigma_+ (\sigma_-) are the raising (lowering) operators. This form is obtained under the rotating wave approximation (RWA), valid when the coupling is weak compared to the frequencies, g \ll \omega_r, \omega_q, neglecting rapidly oscillating counter-rotating terms. In the resonant case (\omega_q = \omega_r), the eigenstates are dressed states forming the Jaynes-Cummings ladder, with energy levels for n excitations given by E_n^\pm = n \hbar \omega_r + \frac{\hbar}{2} (\omega_r + \omega_q) \pm \frac{\hbar}{2} \sqrt{(\omega_q - \omega_r)^2 + 4 g^2 (n+1)}, where the \pm denotes the split doublets. At zero detuning and for the vacuum (n=0), this yields the vacuum Rabi splitting of $2g, marking the avoided crossing between the qubit and resonator bare states and signifying strong coupling. For nonzero detuning \Delta = \omega_q - \omega_r, the splitting generalizes to \sqrt{\Delta^2 + 4g^2 (n+1)}, highlighting the dependence on photon number. The model's dynamics reveal vacuum Rabi oscillations, where an excitation initially in the or coherently oscillates between the two at the $2g \sqrt{n+1} for n s in the . When the resonator is prepared in a with mean photon number \bar{n} \gg 1, these oscillations exhibit collapse due to from the spread in Rabi frequencies across different n, followed by revivals at times t_R = 2\pi \sqrt{\bar{n}}/g arising from quantum of the photon number states. These features underscore the quantized nature of the field and the strong limit in cQED, where g exceeds rates.

Coupling Regimes

In circuit quantum electrodynamics (cQED), the coupling regimes are classified based on the vacuum Rabi rate g relative to the decay rate \kappa and the qubit decay rate \gamma. The weak regime is defined by g \ll \kappa, \gamma, where dissipative processes dominate and prevent observable coherent energy exchange between the qubit and . Conversely, the strong regime requires g > \kappa, \gamma, enabling the system to undergo multiple vacuum Rabi oscillations—manifested as an in the energy spectrum—before decoherence sets in; this regime was first experimentally demonstrated in superconducting circuits using charge qubits coupled to . A key operational subregime within strong coupling is the dispersive regime, accessed when the qubit-resonator detuning satisfies |\Delta| = |\omega_q - \omega_r| \gg g > \kappa, \gamma. Here, a Schrieffer-Wolff transformation of the Jaynes-Cummings yields the effective dispersive H_\text{eff} = \hbar \chi a^\dagger a \sigma_z, with the dispersive shift \chi = g^2 / \Delta. This state-dependent pulling of the resonator frequency by \pm \chi allows for quantum nondemolition readout of the qubit state via microwave pulses tuned to the shifted resonator modes. For qubits, which exhibit reduced charge sensitivity, typical dispersive shifts are \chi / 2\pi \sim 1--$10 MHz, balancing readout speed with minimal qubit disturbance. The ultrastrong coupling regime emerges when g approaches a substantial fraction of the bare frequency, typically g / \omega_r \gtrsim 0.1. In this limit, the fails, as counter-rotating terms in the full quantum Rabi Hamiltonian contribute significantly, enabling phenomena such as exchange and enhanced ground-state entanglement. Experimental access to this regime has been achieved with flux qubits inductively coupled to coplanar waveguide s, yielding normalized couplings up to g / \omega_r = 0.12. The realizability of these regimes is constrained by losses and decoherence, quantified by the qubit energy relaxation time T_1 = 1/\gamma, pure time T_2^*, and resonator time $1/\kappa. Strong and dispersive couplings demand sufficiently long times to resolve the Rabi splitting, typically requiring g T_1 > 1 and g / \kappa > 1; advances in material and fabrication have extended T_1 and T_2 to microseconds and resonator Q = \omega_r / \kappa to $10^6, thereby broadening to these coherent strengths.

Experimental Developments

Historical Milestones

The foundational ideas of circuit quantum electrodynamics (cQED) emerged from a theoretical proposal by Blais et al., who outlined an architecture using one-dimensional superconducting resonators to couple artificial atoms, such as superconducting qubits, achieving the strong-coupling regime of in a solid-state platform. This work envisioned scalable by leveraging microwave photons as a quantum bus between qubits, building on atomic cavity QED but adapted for superconducting circuits. The first experimental demonstration of strong coupling in cQED was reported in 2004 by the group, led by Michel Devoret and Robert Schoelkopf, in collaboration with Alexandre Blais. In their experiment, a superconducting charge was coupled to an on-chip resonator, observing vacuum Rabi splitting with a qubit-cavity coupling strength of g/2\pi = 43 MHz, surpassing the resonator linewidth \kappa/2\pi = 6 MHz and the qubit dephasing rate. This marked the realization of coherent photon-qubit interactions dominating over dissipation, a cornerstone for processing in solid-state systems. Building on this, in 2007, the same Yale group, with Andreas Wallraff and colleagues, demonstrated coherent transfer between two fixed-frequency superconducting qubits mediated by the bus, along with full quantum control of the coupled system. They achieved iSWAP gates with fidelities exceeding 80%, enabling remote qubit-qubit entanglement without direct electrical connections, thus validating the as a versatile quantum bus for multi-qubit operations. During the 2010s, research shifted toward three-dimensional (3D) superconducting cavities to minimize dielectric losses and enhance coherence times, as pioneered by Hanhee Paik et al. in 2011 at Yale. By embedding qubits in macroscopic 3D aluminum cavities, they reported qubit relaxation times T_1 up to 60 μs and times T_2^* around 20 μs—orders of magnitude longer than in 2D planar designs—while maintaining strong dispersive coupling. This architectural advance facilitated more robust qubit operations and laid the groundwork for scalable arrays. In the 2020s, significant milestones included the 2021 demonstration of error-corrected logical qubits in cQED by the Yale group, using bosonic encoding in modes of cavities coupled to qubits to suppress photon loss errors via hardware-efficient codes like the Gottesman–Kitaev–Preskill (GKP) code. This achieved logical lifetimes exceeding physical decoherence, a critical step toward fault-tolerant . The field's progress was celebrated at the CircuitQED@20 conference in 2024, hosted by Yale to mark two decades since the strong-coupling breakthrough, highlighting advancements from single-qubit control to complex quantum networks. In 2025, the was awarded for demonstrations of quantum tunneling and discrete charge effects in superconducting circuits, recognizing foundational experimental work enabling cQED architectures. Key contributions came from the Yale group under Devoret and Schoelkopf, who drove early experiments in coherent coupling and scaling, and parallel efforts by the Quantronics group at CEA-Saclay led by Daniel Estève.

Modern Techniques and Implementations

Fabrication of circuit quantum electrodynamics (cQED) devices relies on advanced nanofabrication techniques, such as , to precisely pattern superconducting thin films and Josephson junctions for both two-dimensional (2D) coplanar waveguide resonators and three-dimensional (3D) cavity structures. These methods enable the creation of high-fidelity artificial atoms, like qubits, integrated with cavities, while minimizing parasitic capacitances and losses. To operate these superconducting components, experiments are performed in dilution refrigerators that cool the system to temperatures below 20 mK, suppressing thermal noise and enabling quantum . Measurement and control in modern cQED setups employ dispersive readout, where the qubit state shifts the resonator frequency, detected via heterodyne techniques that mix the signal with a local oscillator for high-sensitivity phase and amplitude analysis. This non-demolition approach achieves single-shot readout fidelities exceeding 99% in microseconds. Qubit manipulation uses microwave pulse sequences, including Rabi oscillations for driving coherent rotations and for probing dephasing times, allowing precise characterization of coherence properties up to hundreds of microseconds. Efforts to enhance coherence times focus on mitigating decoherence from two-level systems (TLS) at dielectric interfaces, addressed through surface treatments like chemical passivation and niobium encapsulation of qubit structures, which reduce TLS-induced relaxation rates and extend T1 times beyond 100 μs. Transitioning to 3D resonators fabricated from bulk superconductors, such as , yields quality factors > 10^7 at multi-GHz frequencies, minimizing radiation and surface losses for improved qubit-resonator coupling stability. Scalability in multi-qubit cQED architectures incorporates bus resonators to mediate tunable interactions between distant qubits, enabling all-to-all in setups with up to dozens of qubits while preserving individual readout lines. Low-noise cryogenic amplification is provided by Josephson parametric amplifiers (JPAs), which operate near the with gains over 20 and bandwidths up to several GHz, essential for resolving weak readout signals without adding significant noise. From 2023 to 2025, cQED platforms have advanced toward fault-tolerant quantum computing through integration with error correction hardware; for instance, Google's Sycamore processor demonstrated surface code error suppression below the threshold in a 49-qubit array, leveraging transmon qubits dispersively coupled to resonators. In December 2024, Google further demonstrated dynamic surface codes achieving error suppression with distance-3 to distance-5 implementations. Similarly, IBM's processors, evolving from the 127-qubit Eagle to the Heron chip with 133 qubits in 2023, incorporate cQED-based transmons in modular designs supporting error-corrected logical qubits with improved connectivity and readout; in November 2025, IBM announced new processors and Qiskit updates enabling 24% higher accuracy in dynamic circuits. Recent experiments as of November 2025 have also demonstrated scalable quantum circuits for simulating complex nuclear physics on over 100 qubits using cQED systems.

Applications and Advances

Quantum Computing

Circuit quantum electrodynamics (cQED) provides the foundational architecture for implementing superconducting qubits in , particularly through qubits that enable universal single-qubit via precise pulses. These , such as rotations and phase shifts, are executed by applying resonant drives to the , achieving fidelities exceeding 99.9% in durations under 50 ns, as demonstrated in early proposals for all-resonance operations in cQED systems. Two-qubit , essential for universal computation, leverage mediation to couple transmons dispersively, enabling iSWAP and controlled-Z () operations. For instance, ZZ-free iSWAP with 99.6% fidelity in 30 ns and with 99.8% fidelity in 60 ns have been realized using tunable couplers that adjust the effective coupling strength between fixed-frequency transmons via the shared mode. Readout and control in cQED processors rely on the dispersive χ-shift, where the qubit state induces a frequency pull in the coupled resonator, allowing state-dependent transmission or reflection of probe microwaves for high-fidelity discrimination. This χ-shift, typically on the order of 1-10 MHz for transmon-resonator pairs, enables single-shot readout fidelities above 99% in under 300 ns, with the resonator frequency shifting by 2χ depending on whether the transmon is in ground or excited state. Fast feedback loops further enhance control by processing readout signals in real-time—within 100-500 ns—and applying conditional microwave pulses to reset or stabilize qubits, improving overall circuit fidelity by mitigating errors during computation. Such digital feedback has been integral to deterministic qubit initialization and entanglement purification in multi-qubit arrays. Scalability in cQED quantum computing has advanced through 2D and 3D integration schemes, enabling processors with over 100 qubits while addressing challenges. Tileable 3D architectures, for example, integrate qubits on separate chips connected via superconducting vias, achieving times of 150 μs and below 250 kHz in 2x2 lattices, with simulations confirming to larger arrays without introducing low-frequency loss modes. Systems like IBM's 127-qubit and 133-qubit processors exemplify this, incorporating nearest-neighbor coupling via coplanar waveguides and couplers to minimize parasitic interactions, though challenges persist in wiring and ZZ-, limited to under 100 kHz through optimized shielding and planning. Larger lattices, such as 4x4 arrays with 16 qubits, demonstrate single-qubit gate errors below 0.2% simultaneously across devices, paving the way for >100-qubit scaling with modular interconnects. Error correction in cQED leverages the surface code, where qubits form a 2D lattice with ancillary resonators for syndrome measurement, enabling fault-tolerant computation. Google's 2024 demonstration on the Willow processor implemented surface codes, with a distance-5 code suppressing logical errors below the ~1% physical threshold by a factor of 2.14 relative to distance-3, marking the first below-threshold exponential suppression with code distance. Advances in 2024-2025 have extended logical qubit lifetimes beyond 1 ms using cavity-encoded qubits in cQED, achieving T1 times of 1-1.4 ms for on-chip superconducting quantum memories—over ten times longer than typical individual s. These milestones, including a 2024 distance-7 code on 105 qubits with 0.143% logical error per cycle, underscore cQED's progress toward practical fault tolerance. Benchmarks for cQED processors highlight their computational capability through metrics like (QV), which assesses circuit depth, width, and fidelity. IBM's 2023 Heron processor enabled algorithms up to depth 10 on subsets of its 133 qubits, reflecting improved gate fidelities and connectivity. As of 2025, IBM's Heron r3 variant has surpassed QV 2048. Google's chip in 2024 demonstrated equivalent scaling in surface code cycles, with logical QV implicitly boosted by below-threshold operations on 105 qubits. Rigetti's Ankaa-2, an 84-qubit system integrated in 2024, achieved median two-qubit gate fidelities of 98%, emphasizing modular scaling toward 100+ qubits by 2025. These metrics establish cQED's lead in superconducting platforms for near-term quantum advantage.

Quantum Simulation and Sensing

Circuit quantum electrodynamics (cQED) enables analog quantum simulation by mapping complex quantum many-body models onto tunable superconducting circuits, particularly for studying open quantum systems through the spin-boson model. In this framework, a superconducting acts as the spin coupled to a bosonic bath represented by microwave resonators or transmission lines, allowing precise control over dissipation and coupling strengths to mimic environmental interactions. This approach has been experimentally realized by engineering reservoirs in cQED setups, where the qubit-resonator interaction simulates broadband or structured baths for investigating decoherence and relaxation dynamics. Additionally, circuit lattices formed by arrays of coupled resonators and qubits facilitate simulations of Ising models, where tunable flux biases emulate spin-spin interactions in one- or two-dimensional lattices. Key demonstrations include Yale's 2020 experiment using a superconducting bosonic processor to sample molecular vibronic spectra, where multiple microwave modes simulated electronic-nuclear couplings in polyatomic molecules like SO₂, achieving efficient multiphoton sampling beyond classical limits. More recently, in 2023, advancements in bosonic platforms extended this to multi-mode boson sampling for quantum chemistry applications, leveraging non-interacting photonic circuits in cQED to approximate electron structure problems intractable on classical computers. These simulations highlight cQED's ability to access regimes of strong electron-vibration coupling, providing insights into photochemical processes. In sensing applications, cQED cavities enhance detection sensitivity for fundamental physics probes. For axion dark matter searches, superconducting resonators in strong magnetic fields convert hypothetical axions into microwave photons, with quantum-enhanced readout using qubits improving signal-to-noise ratios by exploiting cavity-qubit hybridization. Flux qubits in cQED architectures enable ultrasensitive magnetometry, achieving sensitivities down to 3.3 pT/√Hz at 10 MHz by dispersive readout of flux-induced state shifts. Hybrid systems further extend these capabilities, coupling cQED elements to solid-state spins or optical photons for quantum networks; for instance, kinetic inductance detectors interface microwave photons with electron spins in diamond defects, enabling coherent spin-photon entanglement over cryogenic distances. Recent 2024-2025 integrations of with cQED have advanced hybrid sensing and simulation platforms, incorporating mechanical resonators to couple magnons, photons, and vibrations for enhanced entanglement in multi-mode systems. These developments leverage cQED's tunable parameters—such as variable coupling rates and frequencies—to perform analog simulations of otherwise intractable problems, offering advantages in scalability and fidelity over digital approaches for exploring non-equilibrium dynamics.

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    In this paper, we aim to construct a cavity–magnon and optomechanical hybrid system based on circuit QED, with the incorporation of mechanical nonlinearity ...<|control11|><|separator|>