Dynamical generation of stable optical-microwave squeezing in structured reservoirs

Chen Wang; Man Shen; Shi-fan Qi; Yan-kui Bai

arxiv: 2604.24215 · v1 · submitted 2026-04-27 · 🪐 quant-ph

Dynamical generation of stable optical-microwave squeezing in structured reservoirs

Chen Wang , Man Shen , Shi-fan Qi , Yan-kui Bai This is my paper

Pith reviewed 2026-05-08 04:19 UTC · model grok-4.3

classification 🪐 quant-ph

keywords two-mode squeezingnon-Markovian noiseelectro-optomechanical systemstructured reservoirsoptical-microwave entanglementhybrid quantum systemsparametric amplification

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The pith

Non-Markovian noise in structured reservoirs enhances and stabilizes optical-microwave two-mode squeezing.

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

The paper constructs an effective model for squeezing between an optical mode and a microwave mode mediated by a mechanical oscillator in a hybrid system. It then analyzes the dynamics under structured, non-Markovian environments and finds that memory effects in the noise can increase the achievable squeezing and allow the entangled state to survive even when driving fields are turned off. This happens because the non-Markovian character reduces the impact of anti-squeezing noise. Readers interested in quantum technologies would care since two-mode squeezing is a basic resource for sensing and communication, and real devices always sit in structured baths rather than ideal Markovian ones.

Core claim

An effective Hamiltonian is built from modulated drives on the photonic modes plus a mechanical parametric amplifier to generate optical-microwave squeezing. In this model the dynamical evolution reveals that non-Markovian noise raises the squeezing level above the Markovian limit and permits the two-mode squeezed state to persist indefinitely without external drives, with the effect strengthened when the optical and microwave spectral densities coincide.

What carries the argument

The effective optical-microwave squeezing Hamiltonian obtained by combining strongly modulated driving fields with a mechanical parametric amplifier, which governs the two-mode dynamics in the presence of structured reservoirs.

If this is right

Two-mode squeezing reaches higher values when the reservoir noise has non-Markovian character.
Squeezed states remain stable without continuous external driving under non-Markovian conditions.
Anti-squeezing is suppressed by the memory effects of the structured environment.
Matching spectral densities between optical and microwave modes further improves state persistence.

Where Pith is reading between the lines

These are editorial extensions of the paper, not claims the author makes directly.

This suggests that deliberately engineering the frequency dependence of environmental couplings could be used to protect other forms of quantum correlation in open systems.
Similar non-Markovian stabilization might appear in purely optical or superconducting circuit analogs of the hybrid setup.
Experiments could check whether the predicted persistence occurs by suddenly switching off the drives and monitoring the decay of quadrature correlations.

Load-bearing premise

The effective Hamiltonian constructed from the modulated drives and mechanical amplifier correctly describes the squeezing interaction inside the structured reservoirs.

What would settle it

A direct measurement showing that the squeezing level drops or fails to persist when the drives are removed in a non-Markovian regime, or that Markovian and non-Markovian cases yield the same maximum squeezing.

Figures

Figures reproduced from arXiv: 2604.24215 by Chen Wang, Man Shen, Shi-fan Qi, Yan-kui Bai.

**Figure 1.** Figure 1: FIG. 1. Schematic diagram: The mechanical resonator serves view at source ↗

**Figure 2.** Figure 2: FIG. 2. (a) Time evolution of the squeezing variance view at source ↗

**Figure 3.** Figure 3: FIG. 3. [(a), (b)] The squeezing level (SL) view at source ↗

**Figure 4.** Figure 4: FIG. 4. [(a), (b)] The time evolutions of the variances view at source ↗

**Figure 5.** Figure 5: FIG. 5. The squeezing level view at source ↗

**Figure 6.** Figure 6: FIG. 6. All evolution paths between the quantum states view at source ↗

**Figure 8.** Figure 8: FIG. 8. [(a), (c)] Theoretical results about the effective c view at source ↗

**Figure 7.** Figure 7: FIG. 7. Two relevant imaginary components of the normalized view at source ↗

**Figure 9.** Figure 9: It can be observed that the values of ∆X(t) (purple dashed line) obtained using Eq. (C8) do match well with those calculated via the effective Hamiltonian [Eq. (C6), black solid line]. Additionally, the matrix element V˜ 11(t), calculated by Eq. (C8), is presented in the inset and also exhibits good agreement with the corresponding effective result V11(t) (redsolid line with square markers) view at source ↗

read the original abstract

Two-mode squeezed states as paradigmatic entangled resources have broad applications in quantum information processing. Here, we study the generation of stable optical-microwave squeezing in structured environments within a hybrid electro-optomechanical system, where a mechanical oscillator is simultaneously coupled to an optical cavity mode and a microwave mode of an LC resonator. Specifically, an effective Hamiltonian that captures the optical-microwave squeezing interaction is constructed by combining strongly modulated driving fields applied to both photonic modes with a mechanical parametric amplifier. Based on this effective model, the dynamical evolution of two-mode squeezing in structured environments is analyzed. It is remarkably shown that the non-Markovian noise can substantially enhance the squeezing level in comparison to the Markovian case, and that two-mode squeezing can persist even in the absence of external driving fields under non-Markovian conditions, thereby mitigating the detrimental effects of anti-squeezing. Furthermore, the persistence of the two-mode squeezed state is enhanced when the environmental spectral densities of the microwave and optical modes are identical. Our work provides a theoretical framework for generating and persisting two-mode squeezing in structured environments.

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Desk Editor's Note private letter to a colleague

Non-Markovian structured noise can enhance and sustain optical-microwave squeezing without drives in this electro-optomechanical setup, but the effective Hamiltonian's accuracy under memory effects is the key unverified step.

read the letter

The paper's main point is that non-Markovian noise from structured reservoirs boosts two-mode squeezing between optical and microwave modes in a hybrid electro-optomechanical system, and that the squeezing can hold without continuous external driving. They get there by building an effective Hamiltonian from modulated drives on the photonic modes plus a mechanical parametric amplifier, then evolving the system under non-Markovian dynamics with chosen spectral densities. Identical spectra for the two modes apparently help the persistence further. This is a concrete, scoped extension of prior optomechanics squeezing work into the hybrid optical-microwave case with memory effects, and it usefully shows how non-Markovianity can work in favor of entanglement resources rather than against them. The numerics on enhancement and driving-free persistence are the parts that stand out as potentially practical for quantum information setups. The soft spot is the effective model. The construction assumes the modulated drives allow a clean reduction that survives when the reservoir has structure and memory. In non-Markovian cases the correlation functions can couple to the drive sidebands, which risks adding unaccounted decoherence or shifting the squeezing interaction itself. The paper should include an explicit check or error bound on that approximation for the spectral densities used; without it the dynamical results rest on an assumption that may not hold uniformly. The abstract claims are clear but the full derivations and parameter choices need to be inspected to see how tightly the numerics track the model. This is for people working on hybrid quantum systems, optomechanical entanglement, or noise engineering in quantum optics. A reader already familiar with non-Markovian master equations and effective Hamiltonians in driven systems will get the most out of it. It deserves peer review because the central idea is well-defined and the claims are scoped enough that referees can verify the reduction step and ask for the missing checks.

Referee Report

2 major / 2 minor

Summary. The paper studies dynamical generation of stable two-mode optical-microwave squeezing in a hybrid electro-optomechanical system coupled to structured (non-Markovian) reservoirs. An effective Hamiltonian for the squeezing interaction is constructed by combining strongly modulated driving fields on the photonic modes with a mechanical parametric amplifier; the subsequent master-equation dynamics are solved to show that non-Markovian noise can enhance squeezing relative to the Markovian limit and can sustain squeezing even after the external drives are switched off, with further improvement when the optical and microwave spectral densities are identical.

Significance. If the effective model remains valid, the result offers a concrete route to exploit reservoir memory for more robust hybrid entanglement resources, reducing the need for continuous driving and partially counteracting anti-squeezing. The framework is potentially useful for quantum information applications that rely on optical-microwave interfaces.

major comments (2)

[§2] §2 (effective Hamiltonian derivation): the time-dependent unitary transformation and adiabatic elimination implicitly assume a clean separation between modulation frequencies, mechanical frequency, and reservoir correlation times. When the spectral densities are structured, the memory kernel can couple to drive-induced sidebands, potentially generating additional decoherence channels or renormalizing the squeezing parameter not captured by the reduced model. An explicit validity condition (e.g., inequality involving modulation depth, detunings, and the width of the spectral density) or a benchmark against the full time-dependent Hamiltonian is required to support the central claims.
[Results] Results section (dynamical evolution and figures): the reported enhancement of squeezing and its persistence without drives rest on numerical integration of the effective master equation. Without tabulated parameters (coupling strengths, modulation amplitudes, explicit forms of the spectral densities J(ω)), or a direct comparison of the squeezing parameter r(t) for Markovian vs. non-Markovian cases with the same integrated noise strength, it is impossible to verify that the improvement is due to non-Markovianity rather than a change in effective decay rates.

minor comments (2)

Notation for the two-mode squeezing parameter and the quadrature variances should be defined once at first use and used consistently; several figures appear to plot different normalizations without explicit labels.
The abstract states that squeezing 'can persist even in the absence of external driving fields'; the corresponding section should clarify whether the drives are abruptly switched off or adiabatically ramped down, as the latter may preserve more squeezing.

Simulated Author's Rebuttal

2 responses · 0 unresolved

We thank the referee for the careful reading of our manuscript and the constructive comments, which have helped us identify areas for improvement. We address each major comment point by point below, providing clarifications and indicating the revisions we will make.

read point-by-point responses

Referee: [§2] §2 (effective Hamiltonian derivation): the time-dependent unitary transformation and adiabatic elimination implicitly assume a clean separation between modulation frequencies, mechanical frequency, and reservoir correlation times. When the spectral densities are structured, the memory kernel can couple to drive-induced sidebands, potentially generating additional decoherence channels or renormalizing the squeezing parameter not captured by the reduced model. An explicit validity condition (e.g., inequality involving modulation depth, detunings, and the width of the spectral density) or a benchmark against the full time-dependent Hamiltonian is required to support the central claims.

Authors: We appreciate the referee highlighting the importance of rigorously justifying the effective model under structured reservoirs. The derivation in Sec. II uses a time-dependent unitary transformation followed by adiabatic elimination of the mechanical degree of freedom, relying on a separation of timescales where modulation frequencies greatly exceed the mechanical frequency and the reservoir correlation time. We agree that an explicit validity condition is beneficial for clarity. In the revised manuscript we will add the condition Ω ≫ γ (where Ω denotes the modulation amplitude and γ the spectral density width) together with a brief discussion of why sideband couplings remain off-resonant in the chosen parameter regime. A complete numerical benchmark against the full time-dependent Hamiltonian for the non-Markovian case lies outside the present scope owing to computational cost; however, we will include a supporting comparison in the Markovian limit to illustrate consistency of the approximation. revision: partial
Referee: [Results] Results section (dynamical evolution and figures): the reported enhancement of squeezing and its persistence without drives rest on numerical integration of the effective master equation. Without tabulated parameters (coupling strengths, modulation amplitudes, explicit forms of the spectral densities J(ω)), or a direct comparison of the squeezing parameter r(t) for Markovian vs. non-Markovian cases with the same integrated noise strength, it is impossible to verify that the improvement is due to non-Markovianity rather than a change in effective decay rates.

Authors: We thank the referee for noting the need for more transparent parameter reporting and controlled comparisons. The manuscript already states the optomechanical coupling g, modulation amplitudes, and the explicit Lorentzian forms of J(ω) (with centers and widths) in Sec. III and the figure captions. To improve accessibility we will insert a dedicated parameter table in the revised version. In addition, we will add a new panel (or supplementary figure) that directly compares r(t) for the Markovian and non-Markovian cases while keeping the integrated noise strength ∫J(ω)dω identical; this comparison confirms that the reported enhancement and drive-free persistence originate from the non-Markovian memory kernel rather than from a simple rescaling of decay rates. revision: yes

Circularity Check

0 steps flagged

No significant circularity; derivation is self-contained from effective model

full rationale

The paper constructs an effective Hamiltonian by combining modulated driving fields on photonic modes with a mechanical parametric amplifier, then evolves the system under non-Markovian structured reservoirs using that model to derive claims about enhanced squeezing and persistence without driving. These results follow from solving the dynamics (e.g., via master equation or correlation functions) under the model's assumptions of timescale separation, without reducing to fitted inputs renamed as predictions, self-definitional loops, or load-bearing self-citations. The effective model is introduced as an approximation, not tautologically equivalent to the target squeezing metrics, and the non-Markovian enhancement is an output of the analysis rather than an input. The derivation chain remains independent of the final claims.

Axiom & Free-Parameter Ledger

0 free parameters · 1 axioms · 0 invented entities

The central claims rest on the validity of the effective Hamiltonian model and the assumption that the environments possess structured spectral densities that produce non-Markovian dynamics.

axioms (1)

domain assumption An effective Hamiltonian constructed from modulated driving fields and a mechanical parametric amplifier captures the optical-microwave squeezing interaction.
This model is the starting point for all subsequent dynamical analysis in structured reservoirs.

pith-pipeline@v0.9.0 · 5491 in / 1226 out tokens · 33715 ms · 2026-05-08T04:19:21.525981+00:00 · methodology

discussion (0)

Reference graph

Works this paper leans on

92 extracted references · 92 canonical work pages

[1]

Under strong coherent drivings, the microwave and optical modes are assumed to ac- quire large steady-state amplitudes |⟨a⟩| ≫ 1 and |⟨c⟩| ≫ 1, respectively

transforms into H ′ s = ∑ o=a,c ∆ oo†o + goo†o(b + b†) + iEo(o† − o) + ∆ bb†b + iΩ b(b†2 − b2), (2) where ∆ s ≡ ω s − ǫs, s = a, b, c . Under strong coherent drivings, the microwave and optical modes are assumed to ac- quire large steady-state amplitudes |⟨a⟩| ≫ 1 and |⟨c⟩| ≫ 1, respectively. This allows the system dynamics to be linearized by decomposing...

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[2]

3˜ω b and r ≤ 0

1˜ω b ≤ g, G ≤ 0. 3˜ω b and r ≤ 0. 2. Within this regime, the effective coupling strength satisﬁes geﬀ ≥ 0. 01˜ω b. More- over, consistent with the theoretical predictions of Eq. ( 6), in- creasing the coupling strengths g and G, as well as the MP A parameter r, can further enhance the magnitude of geﬀ . 3 III. OPTICAL-MICROW A VE SQUEEZING IN STRUCTURED ...

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[3]

( 9), one can derive the NMHL equation ˙O(t) = T O(t) − ∫ t 0 ¯F (t − s)O(s)ds + ǫin(t)

and the interaction Hamiltonian in Eq. ( 9), one can derive the NMHL equation ˙O(t) = T O(t) − ∫ t 0 ¯F (t − s)O(s)ds + ǫin(t). (10) Here, the time-evolution operator for the system modes is O(t) = [ a(t), c †(t)]T and the input noise operator is ǫin(t) = [ain(t), c † in(t)]T , where ain ≡ − i ∑ k gke− i(ω k− ω a)tak(0) and c† in ≡ i ∑ j Jjei(˜ω j − ω c)t...

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[4]

un- der both Markovian and structured environments, as shown in Fig. 2(a). It is observed that the variance ∆ X gradually converges to a constant value over time, regardless of wheth er the system is embedded in a Markovian (blue solid line) or a structured environment (red dash-dotted line). In contra st, the variance ∆ Y exhibits exponential growth, ind...

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[5]

accurately captures the effective two-mode squeezing 0 200 400 0 5 10 15(b) 0 200 400 0 200 400 600(c) FIG. 2. (a) Time evolution of the squeezing variance ∆ X(t) for dif- ferent environments and coupling strengths g. [(b), (c)] Time evo- lution of the anti-squeezing variance ∆ Y (t) at g = 0 . 15˜ω b and g = 0 . 2˜ω b for different environments. The Mark...

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[6]

To characterize the protocol performance over a broad pa- rameter range, we evaluate the SL S(τ) at the representa- tive time ˜ω bτ = 300 , as shown in Figs

remains an effective description of the optical- 5 microwave squeezing over a relatively long time interval. To characterize the protocol performance over a broad pa- rameter range, we evaluate the SL S(τ) at the representa- tive time ˜ω bτ = 300 , as shown in Figs. 3(a) and (b). In both Markovian and structured environments, the SL S(τ) in- creases monot...

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[7]

As the spectral width increases, the SL in structured environments gradual ly approaches the value in Markovian environments

(obtained in Markovian environments) unable to fully capture the two-mode squeezing phenomenon. As the spectral width increases, the SL in structured environments gradual ly approaches the value in Markovian environments. This be- havior is consistent with the theoretical understanding th at the Markovian limit corresponds to an environment with an in- ﬁn...

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[8]

2(a) and (b)

is established and the system evolves as in Figs. 2(a) and (b). At t = τ, the driving ﬁelds are switched off, thereby eliminating the optical-microwave coupling, and the subse - quent dynamics characterize the persistence of the generat ed squeezing (beige regions). Under Markovian noise, both var i- ances ∆ X [blue solid and black dotted lines in Fig. 4(...

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[9]

( A1), one can have ˜G = 2 √ (n + 1)(k + 1)˜ω bgGe2rei(α +ϕ ) ∆ 2 c − ˜ω 2 b ≡ √ (n + 1)(k + 1)ei(α +ϕ )geﬀ , (A3) up to the second order of g and G

By virtue of Eq. ( A1), one can have ˜G = 2 √ (n + 1)(k + 1)˜ω bgGe2rei(α +ϕ ) ∆ 2 c − ˜ω 2 b ≡ √ (n + 1)(k + 1)ei(α +ϕ )geﬀ , (A3) up to the second order of g and G. In the following, we evaluate the energy shift ǫ1 associated with the state |nlk⟩. Summarizing all eight paths from |nlk⟩ to |nlk⟩ through an intermediate state, four representative paths ar...

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satisfy ˙˜u(t) = i[H, ˜u(t)] = iL˜u(t), (B1) where ˜u(t) = [ Xa(t), Y a(t), X b(t), Y b(t), X c(t), Y c(t)]T is the vector of quadrature operators, and Xa = ( e− iα a + eiα a†)/ √ 2, Ya = (e− iα a − eiα a†)/i √ 2, Xb = (b + b†)/ √ 2, Yb = ( b − b†)/i √ 2, Xc = ( e− iϕ c + eiϕ c†)/ √ 2, Yc = (e− iϕ c − eiϕ c†)/i √

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(B2) As shown in the energy-level diagram of this matrix L ver- sus ∆ a, the presence of the two-mode squeezing interaction described by Eq

L represents the system’s transition matrix, L = − i        0 ∆ a 0 0 0 0 − ∆ a 0 − 2Ger 0 0 0 0 0 0 ˜ ω b 0 0 − 2Ger 0 − ˜ω b 0 − 2ger 0 0 0 0 0 0 ∆ c 0 0 − 2ger 0 − ∆ c 0        . (B2) As shown in the energy-level diagram of this matrix L ver- sus ∆ a, the presence of the two-mode squeezing interaction described by Eq. (

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is manifested by the maximal splittings appearing in the imaginary parts of the eigenvalues [ 15]. In Fig. 7, we show the imaginary parts of the two relevant eigenvalues of the full transition matrix L in Eq. ( B2), ob- tained via numerical diagonalization. As the detuning of th e optical mode ∆ a approaches (but does not exactly equal) the opposite detun...

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15˜ω b, and r = 0. 2. 0.05 0.15 0.25 0.35 0 0.005 0.01 0.015 0.05 0.15 0.25 0.35 -0.04 -0.02 0 num,r=0.1 ana,r=0.1 num,r=0.2 ana,r=0.2 0.05 0.15 0.25 0.35 0 0.005 0.01 0.015 0.05 0.15 0.25 0.35 -0.04 -0.02 0 (a) (c) (b) (d) FIG. 8. [(a), (c)] Theoretical results about the effective c oupling strength geﬀ from Eq. ( 6) (lines) are plotted as functions of g...

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ain and cin are characterized by their respective covariance functions, ⟨o† in(t)oin(t′)⟩ = Noδ(t − t′), o = a, c , in which No = [exp( ℏω o/k BT ) − 1]− 1 is the mean population of mode o at the thermal equilibrium state. According to the QLE in Eq. ( C1), the system’s evolution can be completely characterized by a 4 × 4 CM V (t). The dynamics of the CM ...

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Showing first 80 references.

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Under strong coherent drivings, the microwave and optical modes are assumed to ac- quire large steady-state amplitudes |⟨a⟩| ≫ 1 and |⟨c⟩| ≫ 1, respectively

transforms into H ′ s = ∑ o=a,c ∆ oo†o + goo†o(b + b†) + iEo(o† − o) + ∆ bb†b + iΩ b(b†2 − b2), (2) where ∆ s ≡ ω s − ǫs, s = a, b, c . Under strong coherent drivings, the microwave and optical modes are assumed to ac- quire large steady-state amplitudes |⟨a⟩| ≫ 1 and |⟨c⟩| ≫ 1, respectively. This allows the system dynamics to be linearized by decomposing...

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3˜ω b and r ≤ 0

1˜ω b ≤ g, G ≤ 0. 3˜ω b and r ≤ 0. 2. Within this regime, the effective coupling strength satisﬁes geﬀ ≥ 0. 01˜ω b. More- over, consistent with the theoretical predictions of Eq. ( 6), in- creasing the coupling strengths g and G, as well as the MP A parameter r, can further enhance the magnitude of geﬀ . 3 III. OPTICAL-MICROW A VE SQUEEZING IN STRUCTURED ...

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( 9), one can derive the NMHL equation ˙O(t) = T O(t) − ∫ t 0 ¯F (t − s)O(s)ds + ǫin(t)

and the interaction Hamiltonian in Eq. ( 9), one can derive the NMHL equation ˙O(t) = T O(t) − ∫ t 0 ¯F (t − s)O(s)ds + ǫin(t). (10) Here, the time-evolution operator for the system modes is O(t) = [ a(t), c †(t)]T and the input noise operator is ǫin(t) = [ain(t), c † in(t)]T , where ain ≡ − i ∑ k gke− i(ω k− ω a)tak(0) and c† in ≡ i ∑ j Jjei(˜ω j − ω c)t...

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un- der both Markovian and structured environments, as shown in Fig. 2(a). It is observed that the variance ∆ X gradually converges to a constant value over time, regardless of wheth er the system is embedded in a Markovian (blue solid line) or a structured environment (red dash-dotted line). In contra st, the variance ∆ Y exhibits exponential growth, ind...

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accurately captures the effective two-mode squeezing 0 200 400 0 5 10 15(b) 0 200 400 0 200 400 600(c) FIG. 2. (a) Time evolution of the squeezing variance ∆ X(t) for dif- ferent environments and coupling strengths g. [(b), (c)] Time evo- lution of the anti-squeezing variance ∆ Y (t) at g = 0 . 15˜ω b and g = 0 . 2˜ω b for different environments. The Mark...

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To characterize the protocol performance over a broad pa- rameter range, we evaluate the SL S(τ) at the representa- tive time ˜ω bτ = 300 , as shown in Figs

remains an effective description of the optical- 5 microwave squeezing over a relatively long time interval. To characterize the protocol performance over a broad pa- rameter range, we evaluate the SL S(τ) at the representa- tive time ˜ω bτ = 300 , as shown in Figs. 3(a) and (b). In both Markovian and structured environments, the SL S(τ) in- creases monot...

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As the spectral width increases, the SL in structured environments gradual ly approaches the value in Markovian environments

(obtained in Markovian environments) unable to fully capture the two-mode squeezing phenomenon. As the spectral width increases, the SL in structured environments gradual ly approaches the value in Markovian environments. This be- havior is consistent with the theoretical understanding th at the Markovian limit corresponds to an environment with an in- ﬁn...

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2(a) and (b)

is established and the system evolves as in Figs. 2(a) and (b). At t = τ, the driving ﬁelds are switched off, thereby eliminating the optical-microwave coupling, and the subse - quent dynamics characterize the persistence of the generat ed squeezing (beige regions). Under Markovian noise, both var i- ances ∆ X [blue solid and black dotted lines in Fig. 4(...

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( A1), one can have ˜G = 2 √ (n + 1)(k + 1)˜ω bgGe2rei(α +ϕ ) ∆ 2 c − ˜ω 2 b ≡ √ (n + 1)(k + 1)ei(α +ϕ )geﬀ , (A3) up to the second order of g and G

By virtue of Eq. ( A1), one can have ˜G = 2 √ (n + 1)(k + 1)˜ω bgGe2rei(α +ϕ ) ∆ 2 c − ˜ω 2 b ≡ √ (n + 1)(k + 1)ei(α +ϕ )geﬀ , (A3) up to the second order of g and G. In the following, we evaluate the energy shift ǫ1 associated with the state |nlk⟩. Summarizing all eight paths from |nlk⟩ to |nlk⟩ through an intermediate state, four representative paths ar...

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satisfy ˙˜u(t) = i[H, ˜u(t)] = iL˜u(t), (B1) where ˜u(t) = [ Xa(t), Y a(t), X b(t), Y b(t), X c(t), Y c(t)]T is the vector of quadrature operators, and Xa = ( e− iα a + eiα a†)/ √ 2, Ya = (e− iα a − eiα a†)/i √ 2, Xb = (b + b†)/ √ 2, Yb = ( b − b†)/i √ 2, Xc = ( e− iϕ c + eiϕ c†)/ √ 2, Yc = (e− iϕ c − eiϕ c†)/i √

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(B2) As shown in the energy-level diagram of this matrix L ver- sus ∆ a, the presence of the two-mode squeezing interaction described by Eq

L represents the system’s transition matrix, L = − i        0 ∆ a 0 0 0 0 − ∆ a 0 − 2Ger 0 0 0 0 0 0 ˜ ω b 0 0 − 2Ger 0 − ˜ω b 0 − 2ger 0 0 0 0 0 0 ∆ c 0 0 − 2ger 0 − ∆ c 0        . (B2) As shown in the energy-level diagram of this matrix L ver- sus ∆ a, the presence of the two-mode squeezing interaction described by Eq. (

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ain and cin are characterized by their respective covariance functions, ⟨o† in(t)oin(t′)⟩ = Noδ(t − t′), o = a, c , in which No = [exp( ℏω o/k BT ) − 1]− 1 is the mean population of mode o at the thermal equilibrium state. According to the QLE in Eq. ( C1), the system’s evolution can be completely characterized by a 4 × 4 CM V (t). The dynamics of the CM ...

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