Fact-checked by Grok 2 weeks ago

Rotating-wave approximation

The rotating-wave approximation (RWA) is a simplification in and , employed to model the coherent between a two-level quantum system—such as an or —and an by neglecting rapidly oscillating (counter-rotating) terms in the that average to negligible contributions over the relevant timescales. This approximation facilitates analytically tractable solutions to otherwise , transforming the full into a form where only near-resonant, energy-conserving terms are retained, often via a transformation to a rotating frame at the field's . Originating in the semiclassical treatment of magnetic resonance, the RWA was pioneered by Isidor Isaac Rabi in his 1937 analysis of space quantization in a gyrating magnetic field, where the rotating frame concept simplified the description of spin precession under a time-varying field. In the quantum domain, it gained prominence through the 1963 Jaynes–Cummings model, which applies the RWA to the quantum Rabi Hamiltonian—describing a two-level atom coupled to a single-mode quantized field—yielding exact eigenstates and predicting key effects like Rabi oscillations and normal-mode splitting in cavity quantum electrodynamics. The RWA's validity hinges on weak-coupling conditions, where the coupling strength () is much smaller than the system's transition frequency, ensuring counter-rotating terms oscillate too quickly to drive transitions. Applications span laser-atom interactions, quantum information processing in superconducting circuits, and , where it underpins simulations of qubit-photon entanglement and coherent control. However, the approximation breaks down in ultrastrong coupling regimes—achievable in modern platforms like circuit —where counter-rotating terms induce non-negligible effects, such as symmetry breaking and Bloch-Siegert shifts, necessitating beyond-RWA treatments.

Introduction

Definition and purpose

The rotating-wave approximation (RWA) is a fundamental simplification technique in and related fields, whereby rapidly oscillating counter-rotating terms in the interaction are neglected to isolate the resonant, slowly varying components that facilitate coherent exchange between a quantum system and an oscillatory driving field. Its primary purpose is to render the time-dependent more tractable for systems involving near-resonant interactions, such as two-level atoms coupled to electromagnetic fields, thereby reducing mathematical and while capturing the essential resonant dynamics without significant loss of accuracy under weak-coupling conditions. This approach is particularly valuable in modeling light-matter interactions, where the full Hamiltonian's oscillatory nature otherwise complicates exact solutions. A key advantage of the RWA lies in its facilitation of analytical solutions to describe core phenomena, including Rabi flopping, which manifests as coherent oscillations between the system's energy levels under resonant driving.

Historical context

The rotating-wave approximation originated in the context of (NMR) during the late and , where it served as a classical tool to simplify the description of spin dynamics under resonant oscillating fields. In 1937, Isidor I. Rabi introduced the theoretical foundation in his analysis of space quantization in a gyrating magnetic field, implicitly employing the approximation by using a rotating frame to neglect rapidly oscillating terms and focus on resonant interactions. This was experimentally realized in 1938 by Rabi and collaborators (J. R. Zacharias, S. Millman, and P. Kusch) in their seminal work on measuring nuclear magnetic moments using oscillating fields, which laid the foundation for treating near-resonant driving fields. Building on Rabi's insights, formalized the classical Bloch equations in 1946, incorporating a to a rotating frame at the driving frequency, which effectively applies the approximation by eliminating fast-oscillating counter-rotating components and simplifying the equations of motion for magnetization. Bloch's framework, recognized with the 1952 shared with Edward Purcell, established the approximation's utility in macroscopic descriptions of resonant phenomena. The approximation transitioned to in the 1960s, as researchers sought to describe light-matter interactions at the quantum level. A pivotal formalization occurred in 1963 with the work of Edwin T. Jaynes and Fred W. Cummings, who developed a fully quantum model of a two-level coupled to a quantized mode, explicitly applying the rotating-wave approximation to derive the . This model highlighted the approximation's role in capturing essential quantum features like Rabi oscillations while discarding non-resonant terms, marking a key milestone in applications to masers and early lasers. Their paper compared quantum and semiclassical theories, demonstrating the approximation's validity for weak couplings and resonant conditions. Parallel developments in resonance fluorescence during the mid-20th century further refined the approximation's scope, though quantum treatments gained prominence in the 1960s and 1970s through perturbative analyses. By the 1980s, the rotating-wave approximation became integral to , where it underpinned models of atoms interacting with confined modes in high-finesse cavities. Seminal experiments, such as those observing Rabi splitting in Rydberg atoms, relied on the Jaynes-Cummings under this approximation to predict and verify strong light-matter coupling regimes. This adoption extended its influence to modern , enabling theoretical descriptions of quantum gates and entanglement generation in cavity-based systems.

Physical basis

Rotating frame transformation

The rotating frame transformation provides physical intuition for the rotating-wave approximation by reparameterizing the dynamics of a driven quantum system into a frame co-rotating with the driving field at frequency \omega. In this frame, interactions near resonance appear nearly time-independent, facilitating the separation of slowly varying terms from rapidly oscillating ones. This approach reveals why resonant processes persist while off-resonant ones average to negligible effects over long times. A classical analogy arises in (NMR), where the rotating frame simplifies the Bloch equations governing dynamics under a static B_0 along the z-axis and a circularly polarized radiofrequency (RF) field B_1 rotating at frequency \omega. In the laboratory frame, the \mathbf{M} undergoes rapid at the frequency \omega_0 = \gamma B_0, where \gamma is the , complicating analysis of RF-induced . Transforming to a frame rotating about the z-axis at \omega eliminates this fast : the effective field becomes \mathbf{B}_\mathrm{eff} = (B_1, 0, ( \omega_0 - \omega ) / \gamma ), and on (\omega = \omega_0), \mathbf{B}_\mathrm{eff} aligns solely with the RF direction, reducing the motion to simple tipping at rate \gamma B_1. The Bloch equations in this frame are \begin{align*} \frac{dM_x}{dt} &= \Delta \omega \, M_y - \frac{M_x}{T_2}, \\ \frac{dM_y}{dt} &= -\Delta \omega \, M_x + \gamma B_1 M_z - \frac{M_y}{T_2}, \\ \frac{dM_z}{dt} &= -\gamma B_1 M_y - \frac{M_z - M_0}{T_1}, \end{align*} where \Delta \omega = \omega_0 - \omega is the detuning, T_1 and T_2 are relaxation times, and M_0 is the equilibrium magnetization; the fast Larmor term \gamma B_0 M_y (for M_x) and cyclic permutations vanish, leaving only slow variations driven by detuning and RF. The quantum extension applies this idea to two-level systems, such as or atoms, using a unitary transformation U(t) = \exp(-i \omega t S_z), where S_z is the z-component of the operator (often \sigma_z / 2 for , with \sigma_z = |e\rangle\langle e| - |g\rangle\langle g|). This operator rotates the state vectors in the , effectively shifting the bare energy levels of the ground |g\rangle and excited |e\rangle states by \mp \hbar \omega / 2, respectively. In the transformed frame, the free becomes \frac{\hbar}{2} (\omega_0 - \omega) \sigma_z, isolating the detuning \delta = \omega_0 - \omega, while the driving interaction—originally proportional to \cos(\omega t) \sigma_x—splits into slowly varying (near-resonant) components that remain finite and rapidly oscillating ones at $2\omega. These near-resonant terms, which connect states differing by approximately \hbar \omega, evolve slowly in the rotating frame and govern the long-time dynamics, such as Rabi oscillations under weak driving. The transformation thus underscores the dominance of energy-conserving processes near resonance.

Counter-rotating terms

In the context of the rotating-wave approximation applied to near-resonant interactions, counter-rotating terms are the components of the interaction Hamiltonian that oscillate at the sum of the system's transition frequency \omega_0 and the driving field frequency \omega, approximately $2\omega. These terms emerge after transforming to a rotating frame at frequency \omega and exhibit rapid phase accumulation, causing their time average to vanish over periods much longer than the oscillation timescale $1/(2\omega). This averaging effect renders their contribution negligible for dynamics on slower timescales relevant to resonant processes. Physically, counter-rotating terms describe virtual processes that inefficiently conserve energy, such as simultaneous and of by the system, which do not lead to real transitions under near-resonant conditions. Unlike the co-rotating terms that align with the system's natural evolution and facilitate efficient energy exchange, these terms drive off-resonant virtual excitations that quickly dephase without net effect. This intuition stems from the fact that counter-rotating interactions require the system to bridge an energy mismatch of roughly $2\hbar\omega, making them perturbative corrections rather than dominant drivers of evolution. A representative example occurs in the dipole interaction between a two-level and a single-mode quantized , where the full includes both rotating and counter-rotating contributions. The terms \sigma_+ a ( excitation with ) and \sigma_- a^\dagger ( de-excitation with ) are retained as they conserve near , while the counter-rotating terms \sigma_+ a^\dagger ( excitation with ) and \sigma_- a ( de-excitation with ) are dropped, as they would increase or decrease the total by nearly $2\hbar\omega. These counter-rotating processes thus correspond to highly improbable simultaneous and events that do not align with in the .

Mathematical formulation

Interaction picture Hamiltonian

In the context of a two-level quantum system coupled to a single of a quantized , the total in the is expressed as H = H_0 + V, where H_0 = \frac{\hbar \omega_0}{2} \sigma_z + \hbar \omega a^\dagger a represents the free of the atom and field, with \omega_0 the atomic , \omega the field , \sigma_z the Pauli z-matrix for the two-level atom, and a^\dagger, a the for the field , respectively. The interaction term V arises from the electric and takes the form V = -\mathbf{d} \cdot \mathbf{E}, where \mathbf{d} is the atomic and \mathbf{E} is the associated with the . For a two-level atom aligned with the field , \mathbf{d} = \mathbf{d}_{eg} (\sigma_+ + \sigma_-), with \sigma_+ = |e\rangle\langle g| and \sigma_- = |g\rangle\langle e| the and lowering s, and the field is \mathbf{E} = i \mathcal{E}_0 (\ a e^{i\mathbf{k}\cdot\mathbf{r}} - a^\dagger e^{-i\mathbf{k}\cdot\mathbf{r}}\ ), but in the approximation and for a single at the atom's position, this simplifies to \mathbf{E} \propto (a + a^\dagger). Thus, the interaction becomes V = \hbar g (\sigma_+ + \sigma_-) (a + a^\dagger), where g = -\mathbf{d}_{eg} \cdot \mathcal{E}_0 / \hbar is the vacuum , assuming the rotating wave basis for the field but retaining the full counter-rotating structure. To analyze the dynamics near , it is convenient to transform to the with respect to H_0, where the evolves as |\psi_I(t)\rangle = e^{i H_0 t / \hbar} |\psi_S(t)\rangle, and the in this picture is H_I(t) = e^{i H_0 t / \hbar} V e^{-i H_0 t / \hbar}. The of the operators under H_0 yields \sigma_+(t) = \sigma_+ e^{i \omega_0 t}, \sigma_-(t) = \sigma_- e^{-i \omega_0 t}, a(t) = a e^{-i \omega t}, and a^\dagger(t) = a^\dagger e^{i \omega t}. Substituting these into V produces the explicit form of the interaction in the : H_I(t) = \hbar g \left[ \sigma_+ a \, e^{i (\omega_0 - \omega) t} + \sigma_+ a^\dagger \, e^{i (\omega_0 + \omega) t} + \sigma_- a \, e^{-i (\omega_0 + \omega) t} + \sigma_- a^\dagger \, e^{-i (\omega_0 - \omega) t} \right]. This expression reveals four oscillatory terms with frequencies determined by the sum and difference of \omega_0 and \omega. The detuning is defined as \delta = \omega_0 - \omega, which quantifies the mismatch between the atomic and field frequencies, setting the phase accumulation rate for the near-resonant terms \sigma_+ a e^{i \delta t} and \sigma_- a^\dagger e^{-i \delta t}. The remaining terms, involving \omega_0 + \omega, oscillate rapidly at approximately twice the transition frequency and are identified as the counter-rotating contributions. In treatments involving a classical driving field, the interaction can be modeled similarly by replacing the quantum field operators with a time-dependent classical field E(t) = E_0 (a + a^\dagger) \cos(\omega t), though the a, a^\dagger here represent coherent state expectations; expanding \cos(\omega t) = \frac{1}{2} (e^{i \omega t} + e^{-i \omega t}) in the interaction picture leads to analogous exponential terms e^{\pm i (\omega_0 \pm \omega) t}. This setup highlights the oscillatory nature central to the rotating-wave approximation, without yet neglecting any terms.

Applying the approximation

To apply the rotating-wave approximation (RWA) in the , the time-dependent for a two-level coupled to a quantized field is first expressed using the raising and lowering operators, yielding terms that oscillate at frequencies determined by the detuning and sum of the transition and field frequencies. Specifically, the takes the form \hat{H}_\text{int} = \hbar g (\hat{\sigma}^+ \hat{a} e^{i (\omega_0 - \omega) t} + \hat{\sigma}^+ \hat{a}^\dagger e^{i (\omega_0 + \omega) t} + \hat{\sigma}^- \hat{a} e^{-i (\omega_0 + \omega) t} + \hat{\sigma}^- \hat{a}^\dagger e^{-i (\omega_0 - \omega) t}), where \omega_0 is the atomic transition frequency, \omega is the field frequency, and g is the coupling strength. Near resonance, where the detuning \delta = \omega_0 - \omega satisfies |\delta| \ll \omega, the terms \hat{\sigma}^+ \hat{a} e^{i \delta t} and \hat{\sigma}^- \hat{a}^\dagger e^{-i \delta t} oscillate slowly, while the counter-rotating terms involving \hat{\sigma}^+ \hat{a}^\dagger e^{i (\omega_0 + \omega) t} and \hat{\sigma}^- \hat{a} e^{-i (\omega_0 + \omega) t} oscillate rapidly at approximately $2\omega. The procedure involves averaging over these fast oscillations, retaining only the slowly varying (resonant) terms where |\omega_0 - \omega| \ll |\omega_0 + \omega|. This averaging is justified by the secular approximation, which discards contributions from terms whose frequencies are much larger than the system's decay rates, as they average to zero over timescales relevant to the dynamics. The resulting approximated Hamiltonian in the RWA is \hat{H}_\text{RWA} = \hbar g (\hat{\sigma}^+ \hat{a} + \hat{\sigma}^- \hat{a}^\dagger) at exact (\delta = 0), where the time dependence vanishes and the form conserves number. For the off-resonant case with small \delta \neq 0, the time-dependent version is retained as \hat{H}_\text{RWA} = \hbar g (\hat{\sigma}^+ \hat{a} e^{i \delta t} + \hat{\sigma}^- \hat{a}^\dagger e^{-i \delta t}), incorporating the slow due to detuning while still neglecting the $2\omega terms. This simplified form enables exact solvability in the Jaynes-Cummings model and underlies much of analysis.

Derivation in two-level systems

Step-by-step process

The derivation of the rotating-wave approximation (RWA) for a two-level quantum system, modeled as a interacting with a coherent classical , follows a systematic in the . Step 1: Bare Hamiltonian. The starting point is the total describing the system in the dipole approximation and semiclassical limit, where the field is treated classically without quantization: H = \frac{\hbar \omega_0}{2} \sigma_z + \hbar g \cos(\omega t) \sigma_x, with \omega_0 the transition frequency of the two-level system, \omega the frequency of the driving field, g the coupling strength proportional to the field amplitude, and \sigma_z, \sigma_x the corresponding Pauli operators (the \sigma_x term arises from the dipole interaction -\vec{\mu} \cdot \vec{E}(t), where \vec{E}(t) \propto \cos(\omega t)). This form assumes the rotating dipole approximation and neglects permanent dipole moments. Step 2: Transformation to the interaction picture. To capture the perturbative dynamics due to the drive, transform to the interaction picture with respect to the free Hamiltonian H_0 = \frac{\hbar \omega_0}{2} \sigma_z. In this picture, the interaction term evolves as H_I(t) = \hbar g \cos(\omega t) \left( \sigma_+ e^{i \omega_0 t} + \sigma_- e^{-i \omega_0 t} \right), where \sigma_\pm = (\sigma_x \pm i \sigma_y)/2 are the raising and lowering operators. Expanding the cosine using Euler's formula, \cos(\omega t) = \frac{1}{2} \left( e^{i \omega t} + e^{-i \omega t} \right), yields H_I(t) = \frac{\hbar g}{2} \left[ \sigma_+ \left( e^{i (\omega_0 - \omega) t} + e^{i (\omega_0 + \omega) t} \right) + \sigma_- \left( e^{-i (\omega_0 - \omega) t} + e^{-i (\omega_0 + \omega) t} \right) \right]. This expansion reveals the time-dependent perturbation structure. Step 3: Identification of resonant and counter-rotating terms. The terms oscillating at frequencies \pm (\omega_0 - \omega) are the near-resonant or "rotating" terms, which vary slowly when the detuning \delta = \omega_0 - \omega is small compared to \omega_0. In contrast, the terms oscillating at \pm (\omega_0 + \omega) \approx \pm 2\omega_0 are the counter-rotating or "fast" terms, which oscillate rapidly due to the high carrier frequency. These fast terms do not contribute significantly to energy exchange between the system and the field near resonance. Step 4: Applying the approximation. In the weak-coupling regime, where g \ll |\omega_0|, |\omega| and near-resonance |\delta| \ll \omega_0, the fast-oscillating counter-rotating terms average to negligible contributions over timescales of interest (longer than $1/g but shorter than $1/(g^2/\omega_0)). These terms are thus dropped, retaining only the resonant terms to obtain the RWA Hamiltonian in the : H_I^{\text{RWA}}(t) = \frac{\hbar g}{2} \left[ \sigma_+ e^{i \delta t} + \sigma_- e^{-i \delta t} \right]. This semiclassical RWA simplifies the analysis while preserving the essential coherent dynamics, such as Rabi oscillations, and aligns with the no-field-quantization limit of the full quantum treatment.

Resulting simplified equations

After applying the rotating wave approximation, the effective for a two-level in the rotating frame becomes time-independent: H_{\mathrm{eff}} = \frac{\hbar \delta}{2} \sigma_z + \frac{\hbar \Omega}{2} (\sigma_+ + \sigma_-), where \delta = \omega_0 - \omega is the detuning, \omega_0 is the atomic transition frequency, \omega is the driving field frequency, and \Omega is the on-resonance Rabi frequency. In this semiclassical derivation, \Omega = g = |\vec{d} \cdot \vec{E}| / \hbar, where g is the coupling strength and \vec{E} is the electric field amplitude. (Note: In the quantum Jaynes–Cummings model for a single photon, the effective Rabi frequency is $2g, where g denotes the vacuum coupling strength.) This form arises from the prior derivation steps and enables exact solutions for the due to its constant coefficients, avoiding the need for perturbative methods. The inclusion of detuning effects is captured through the \sigma_z term, which tilts the effective field in the representation, leading to of the Bloch vector \vec{r} = (r_x, r_y, r_z) governed by the torque equation \dot{\vec{r}} = \vec{\Omega}_{\mathrm{eff}} \times \vec{r} with \vec{\Omega}_{\mathrm{eff}} = (\Omega, 0, \delta). For the undamped case starting from the , the excited-state probability is P_e(t) = \frac{\Omega^2}{\delta^2 + \Omega^2} \sin^2 \left( \frac{\sqrt{\delta^2 + \Omega^2}\, t}{2} \right), where the argument of the sine involves the generalized \sqrt{\delta^2 + \Omega^2}. In the presence of at rate \gamma, the full dynamics are described by the optical Bloch equations, yielding damped Rabi oscillations; precise solutions incorporate transverse and longitudinal relaxation terms.

Applications

Quantum optics examples

In quantum optics, the rotating-wave approximation (RWA) plays a central role in the Jaynes-Cummings model, which describes the interaction between a two-level atom and a single mode of the quantized in a . Under the RWA, the model's is diagonalized to yield dressed states, which are hybrid atom-photon eigenstates exhibiting energy splittings proportional to the atom-field coupling strength. These dressed states underpin phenomena such as collapse and revival in the photon number statistics, where an initial coherent field state leads to rapid dephasing (collapse) followed by periodic rephasing (revival) at characteristic times determined by the mean photon number. A key experimental manifestation of the RWA in (QED) is vacuum Rabi splitting, observed in the transmission spectra of systems coupling a single to a resonant cavity mode. In the strong-coupling regime enabled by the RWA, the empty-cavity resonance splits into two peaks separated by twice the vacuum , reflecting the coherent energy exchange between the atom and the single-photon . This splitting has been directly measured in cavities with Rydberg atoms, confirming the predictions of the Jaynes-Cummings model and serving as a benchmark for strong light-matter coupling. The RWA also facilitates the analysis of resonance fluorescence from a strongly driven two-level atom, where the emitted spectrum under resonant excitation displays the characteristic Mollow triplet: a central Rayleigh peak flanked by two sidebands shifted by the Rabi frequency. This three-peak structure arises from transitions between dressed states of the driven atom, with the RWA ensuring the neglect of rapid-oscillating terms that would otherwise complicate the dynamics. The triplet has been observed in atomic vapors and solid-state emitters, highlighting the RWA's utility in predicting nonlinear optical responses. In simulations of open quantum systems, the RWA simplifies quantum trajectory methods, such as the wavefunction approach, by reducing the effective for dissipative light-matter interactions. This approximation allows efficient numerical unraveling of the into stochastic trajectories that account for quantum jumps due to or cavity loss, enabling studies of nonclassical effects like in cavity . Such methods have been instrumental in modeling realistic quantum optical devices, where the RWA maintains computational tractability while capturing essential coherence dynamics.

Nuclear magnetic resonance

In (NMR), the rotating-wave approximation (RWA) plays a central role in simplifying the dynamics of nuclear spins under radiofrequency (RF) irradiation. The classical description relies on the Bloch equations, which model the evolution of the macroscopic vector \mathbf{M}. To handle the oscillatory nature of the RF field, these equations are transformed into a frame rotating at the RF \omega, close to the Larmor frequency \omega_0 = \gamma B_0 of the static field B_0. In this rotating frame, the dominant interaction from the RF field $2 B_1 \cos(\omega t) along the x-axis decomposes into co-rotating and counter-rotating components; the RWA neglects the rapidly oscillating counter-rotating (at $2\omega), leaving an effective static transverse field B_1. This yields the simplified Bloch equations: \frac{dM_x}{dt} = \gamma \Delta M_y - \frac{M_x}{T_2}, \frac{dM_y}{dt} = -\gamma \Delta M_x + \gamma B_1 M_z - \frac{M_y}{T_2}, \frac{dM_z}{dt} = -\gamma B_1 M_y - \frac{M_z - M_0}{T_1}, where \Delta = \omega_0 - \omega is the detuning, \gamma is the gyromagnetic ratio, T_1 and T_2 are longitudinal and transverse relaxation times, and M_0 is the equilibrium magnetization. On resonance (\Delta = 0), the equations describe nutation of \mathbf{M} around the effective field \mathbf{B}_\mathrm{eff} = (B_1, 0, 0) at the Rabi frequency \Omega = \gamma B_1, enabling precise control of flip angles in pulse sequences. The RWA facilitates analytic solutions for key NMR pulse sequences, such as spin echoes and experiments. In the Hahn spin-echo sequence, a \pi/2 tips the into the , allowing due to field inhomogeneities or chemical shifts; a subsequent \pi refocuses , producing an at time $2\tau after the initial excitation. Under the RWA, the evolution in the rotating frame treats the pulses as instantaneous rotations around the effective field, yielding exact expressions for the echo amplitude that decay only due to T_2 relaxation, independent of static field variations. experiments, involving continuous RF irradiation, reveal the directly from oscillations in the transverse , confirming the effective field strength predicted by the RWA. These solutions underpin the design of multidimensional NMR , where coherent transfers are optimized for signal enhancement. In quantum treatments of few-spin NMR systems, the RWA extends to the microscopic density operator or , simplifying the in the . For isolated pairs, such as an electron-nuclear system coupled via hyperfine under RF , the RWA yields a Jaynes-Cummings-like H = \frac{\Omega}{2} (\sigma_+ a + \sigma_- a^\dagger) + \Delta (\sigma_z/2 + a^\dagger a), where \sigma acts on the spin and a on the effective bosonic mode representing the driven field or coupled spins. This form captures Rabi oscillations and vacuum Rabi splitting analogously to quantum optics, enabling analytic solutions for coherence evolution and entanglement generation in applications like dynamical decoupling or quantum sensing. Such models are essential for interpreting spectra in low-spin-density samples, like dilute radicals in ENDOR spectroscopy. Experimentally, the RWA is routinely applied in (MRI) for resonant slice selection, where a frequency-swept or band-limited RF is applied alongside a linear G_z to excite in a specific . The approximation ensures that only the co-rotating component interacts effectively with whose Larmor frequencies match the pulse bandwidth \Delta \omega \approx \gamma G_z \Delta z, defining the slice thickness \Delta z = \Delta \omega / (\gamma G_z). This technique, standard since the , achieves high-resolution with minimal off-resonance artifacts in clinical fields up to 7 T.

Validity and limitations

Conditions for applicability

The rotating-wave approximation (RWA) is quantitatively accurate in regimes where the counter-rotating terms in the interaction contribute negligibly to the system's dynamics, primarily due to their rapid oscillations averaging out over relevant timescales. A key condition is near- between the driving field frequency \omega and the system's transition frequency \omega_0, quantified by the detuning satisfying |\delta| \ll \omega_0 where \delta = \omega - \omega_0. This ensures that the slowly varying terms near resonance dominate, while detuning-induced oscillations remain slow compared to the fast counter-rotating frequencies around $2\omega_0. Another essential requirement is the weak-coupling limit, where the interaction strength g obeys g \ll \omega_0. Under this condition, the amplitudes of transitions driven by counter-rotating terms are suppressed, as these processes involve high-energy intermediate states far from , rendering their effects perturbative and small. This regime is typical in dilute atomic gases or setups with low photon densities. The approximation further relies on an observation timescale long enough for the averaging of the rapidly oscillating counter-rotating terms to effectively vanish. Additionally, RWA validity assumes minimal thermal excitations, such as at low temperatures where the bosonic field occupies the or a coherent state with small photon number \bar{n} \ll [1](/page/1), preserving the single-mode description without significant multi-photon or multi-mode contributions.

Breakdown scenarios and alternatives

The rotating-wave approximation (RWA) breaks down in the ultrastrong coupling regime, where the coupling strength g approaches or exceeds the transition \omega_0, such as g \approx 0.82 GHz in (QED) systems with superconducting qubits and resonators. In this regime, the counter-rotating terms in the interaction Hamiltonian, which are typically neglected under RWA, become significant and lead to effects like the Bloch-Siegert shift—a shift in the due to virtual transitions induced by these terms. This failure manifests in circuit QED experiments where the vacuum Rabi splitting spectrum deviates from RWA predictions, requiring inclusion of the full quantum Rabi model for accurate description. Breakdown also occurs under broadband driving or in multiphoton processes, where the RWA's assumption of near-resonant, monochromatic fields fails to capture higher-order harmonics and multi-photon transitions. For instance, in strongly driven like donor-bound spins in , intense fields induce dynamics where counter-rotating terms contribute to multi-photon resonances, leading to deviations in Rabi oscillations and fluorescence spectra that RWA cannot reproduce. In multiphoton interactions with multiple emitters, the RWA overlooks virtual photon exchanges and higher harmonics, resulting in inaccurate predictions of collective emission rates. Experimental signatures of RWA breakdown include asymmetric Mollow triplets in resonance fluorescence spectra, where the sidebands exhibit unequal intensities due to counter-rotating contributions in ultrastrongly coupled systems. In the deep strong coupling regime, parity effects emerge, such as the of photon number in the Jaynes-Cummings model, leading to oscillatory where packets propagate along parity chains without violating conservation laws predicted by the full . These signatures have been observed in trapped atom experiments achieving coupling strengths up to 6.5 times the field mode frequency, highlighting non-RWA physics like enhanced virtual processes. To address these limitations, alternatives to the RWA include full numerical of the complete , which provides exact solutions for finite-dimensional systems but scales poorly with system size. For periodically driven scenarios, offers an effective framework by expanding the time-dependent in Floquet modes, capturing high-frequency expansions and avoiding RWA neglect of counter-rotating terms. Perturbative methods, such as the Schrieffer-Wolff transformation, enable inclusion of counter-rotating effects through unitary transformations that block- the , applicable in both static ultrastrong coupling and time-dependent deep strong coupling regimes. These approaches have been extended to driven systems via Floquet-Schrieffer-Wolff methods for effective Floquet .

References

  1. [1]
    https://doi.org/10.4236/jmp.2017.812124
  2. [2]
    https://doi.org/10.1103/PhysRev.51.652
  3. [3]
    [PDF] Introduction to the Rotating Wave Approximation (RWA) - arXiv
    May 23, 2014 · The rotating wave approximation (RWA) is an approximation used in Quantum Optics to obtain analytic solutions by removing fast oscillating ...
  4. [4]
    [PDF] A Hands on Introduction to NMR
    ... rotating frame, B1, then the Bloch equations simplify to, where, ∆ω is a small off-resonance term (the difference between the rotating frame frequency and the.
  5. [5]
    Comparison of quantum and semiclassical radiation theories with ...
    This paper has two purposes: 1) to clarify the relationship between the quantum theory of radiation, where the electromagnetic field-expansion coefficients ...
  6. [6]
    [PDF] Atom-Photon Interactions - Physics Department Sites
    The Schrödinger equation becomes. (. ∂tα = i ΩR. 2 β. ∂tβ = i ΩR. 2 α + i∆β. (2.63). Let us suppose we do not make the rotating wave approximation (RWA). The ...
  7. [7]
    [PDF] Jaynes-Cummings Model - Ali Ramadhan
    Mar 22, 2016 · Interaction Hamiltonian. □ In the interaction picture, the operators evolve like. ˆa(t)=ˆa(0)e. −iωct. ˆa. †. (t)=ˆa. †. (0)eiωct. ˆσ± = ˆσ±(0)e.
  8. [8]
    https://arxiv.org/pdf/1301.3585
  9. [9]
    None
    ### Summary of Rotating Wave Approximation (RWA) Derivation in Jaynes-Cummings Model
  10. [10]
    [1301.3585] Introduction to the Rotating Wave Approximation (RWA)
    Jan 16, 2013 · The rotating wave approximation (RWA) is a mysterious approximation used in Quantum Optics to obtain an analytic approximate solution of some ...
  11. [11]
    https://phsites.technion.ac.il/eric/wp-content/uploads/sites/6/2017/08/Atom_Photon.pdf
  12. [12]
    Periodic Spontaneous Collapse and Revival in a Simple Quantum ...
    May 19, 1980 · This Letter reports on the existence of periodic spontaneous collapse and revival of coherence in the dynamics of a simple quantum model.
  13. [13]
    Observation of resonance fluorescence and the Mollow triplet from a ...
    We observe the characteristic Mollow triplet [22 –24] in the resonance fluorescence spectra under continuous-wave excitation conditions, and demonstrate the ...Missing: rotating | Show results with:rotating
  14. [14]
    https://arxiv.org/pdf/1111.1143
  15. [15]
    None
    Nothing is retrieved...<|control11|><|separator|>
  16. [16]
    Spin Echoes | Phys. Rev. - Physical Review Link Manager
    The properties and underlying principles of these spin echo signals are discussed with use of the Bloch theory. Relaxation times are measured directly and ...
  17. [17]
    Nuclear Magnetic Resonance for Arbitrary Spin Values in the ... - arXiv
    Mar 16, 2022 · Nuclear Magnetic Resonance for Arbitrary Spin Values in the Rotating Wave Approximation. Authors:Zhichen Liu, Sunghyun Kim, Richard A. Klemm.Missing: echo | Show results with:echo
  18. [18]
    Slice-selective excitation - Questions and Answers ​in MRI
    Two steps are required to uniquely excite a slice in 2D MR imaging: (1) a slice-select gradient is imposed along an axis perpendicular to the plane of the ...
  19. [19]
    https://opg.optica.org/josab/abstract.cfm?uri=josab-10-3-524
  20. [20]
    https://journals.aps.org/pr/abstract/10.1103/PhysRev.70.460
  21. [21]
    Observation of the Bloch-Siegert Shift in a Qubit-Oscillator System in ...
    This demonstrates the failure of the rotating-wave approximation in this ultrastrong coupling regime of circuit QED. The large coupling of 0.82 GHz is ...
  22. [22]
    Dissipation and ultrastrong coupling in circuit QED | Phys. Rev. A
    Oct 19, 2011 · Special attention is given to the ultrastrong coupling regime, where the failure of the quantum optical master equation is manifest. ... rotating- ...
  23. [23]
    Breaking the rotating wave approximation for a strongly driven ...
    Oct 17, 2016 · This allows us to investigate the regime where the rotating wave approximation breaks down without requiring microwave power levels that would ...
  24. [24]
    Quantifying the breakdown of the rotating-wave approximation in ...
    Dec 9, 2021 · We study quantitatively the breakdown of the rotating-wave approximation when calculating collective light emission by quantum emitters, in ...Missing: broadband driving processes
  25. [25]
    Multiphoton pulses interacting with multiple emitters in a one ...
    Nov 3, 2020 · We should note that the rotating wave approximation is applied in the Hamiltonian shown in Eq. (1) . Thus, our theory developed here is valid ...<|separator|>
  26. [26]
    Multiphoton-resonance-induced fluorescence of a strongly driven ...
    Mar 13, 2018 · In these systems, the standard Mollow triplet as well as the ... The breakdown of the RWA is because it misses the effects of the CR terms.
  27. [27]
    Deep Strong Coupling Regime of the Jaynes-Cummings Model
    We propose an intuitive and predictive physical frame to describe the DSC regime where photon number wave packets bounce back and forth along parity chains of ...Abstract · Article Text
  28. [28]
    Quantum Rabi dynamics of trapped atoms far in the deep strong ...
    Feb 20, 2023 · With this method we achieve a Rabi coupling strength of 6.5 times the field mode frequency, which is far in the deep strong coupling regime, and ...<|separator|>
  29. [29]
    Variational Schrieffer-Wolff transformations for quantum many-body ...
    Jan 10, 2020 · There is an alternative approach based on first mapping the static Hamiltonian to the Floquet one, and then using the high-frequency expansions
  30. [30]
    Perturbative Diagonalization for Time-Dependent Strong Interactions
    Aug 3, 2022 · We present a systematic method to implement a perturbative Hamiltonian diagonalization based on the time-dependent Schrieffer-Wolff transformation.