Deconstructing squeezed light: Schmidt decomposition versus the Whittaker-Shannon interpolation (2024)

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Deconstructing squeezed light: Schmidt decomposition versus the Whittaker-Shannon interpolation

C. Drago and J. E. Sipe

Phys. Rev. A 110, 023710 – Published 6 August 2024

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Abstract

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Article Text

INTRODUCTION

JOINT TEMPORAL AMPLITUDE

SCHMIDT MODES

AN APPROXIMATE SCHMIDT DECOMPOSITION

THE WHITTAKER-SHANNON DECOMPOSITION

EMPLOYING THE WHITTAKER-SHANNON…

LOCAL STATES AND CORRELATION FUNCTIONS

THE STRONGLY SQUEEZED LIMIT

A FINAL EXAMPLE

CONCLUSION

ACKNOWLEDGMENTS

APPENDICES

References

Abstract

We develop a formalism to describe squeezed light with large spectral-temporal correlations. This description is valid in all regimes, but is especially applicable in the long pulse to continuous-wave limit where the photon density at any particular time is small, although the total number of photons can be quite large. Our method relies on the Whittaker-Shannon interpolation formula applied to the joint temporal amplitude of squeezed light, which allows us to “deconstruct” the squeezed state. This provides a local description of the state and its photon statistics, making the underlying physics more transparent than does the use of the Schmidt decomposition. The formalism can easily be extended to more exotic nonclassical states where a Schmidt decomposition is not possible.

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Received 4 December 2023
Accepted 15 April 2024

DOI:https://doi.org/10.1103/PhysRevA.110.023710

Physics Subject Headings (PhySH)

Research Areas

Photon statisticsQuantum opticsQuantum states of lightSqueezing of quantum noise

Atomic, Molecular & Optical

Authors & Affiliations

C. Drago^* and J. E. Sipe^†

Department of Physics, University of Toronto, 60St. George Street, Toronto, Ontario, Canada, M5S 1A7

^*Contact author: christian.drago@mail.utoronto.ca
^†Contact author: sipe@physics.utoronto.ca

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Vol. 110, Iss. 2 — August 2024

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Figure 1
Schematic of a joint intensity represented in time on the left and frequency on the right. The horizontal width of the joint temporal (spectral) amplitude is denoted by $T_{p}$ ( $B_{c}$ ), which is the effective pulse duration (bandwidth). The narrow horizontal width at $t_{2} = 0$ is denoted by $T_{c} = 1 / B_{c}$ and is the coherence time of photon pairs.
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Figure 2
For the double-Gaussian, from left to right we plot the joint temporal intensity divided by its maximum value with the axes normalized by $T_{p}^{DG}$ , the joint spectral intensity divided by its maximum value with the axes normalized by $2 π B_{c}^{DG}$ , and the Schmidt amplitudes $p_{n}$ up to $n = 39$ .
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Figure 3
For the double-Gaussian, from left to right we plot ${\bar{G}}^{(1)} (t) / Φ$ and a few contributions from different Schmidt modes in Eq.(3.20) with the horizontal axis normalized by $T_{p}^{DG}$ for $β = 0.1$ , 5, and 10. In each plot the $n = 0$ term is the largest Schmidt mode contribution and they get smaller as $n$ increases.
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Figure 4
For the double Gaussian, from left to right we plot ${\bar{G}}^{(2)} (t_{1}, t_{2}) / Φ^{2}$ (top) and the coherent and incoherent contribution to ${\bar{G}}^{(2)} (t / 2, - t / 2) / Φ^{2}$ (bottom) with the axes normalized by $T_{p}^{DG}$ for $β = 0.1$ , 5, and 10.
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Figure 5
For the sinc hat, from left to right we plot the joint temporal intensity divided by its maximum value with the axes normalized by $T_{p}^{SH}$ , the joint spectral intensity divided by its maximum value with the axes normalized by $2 π B_{c}^{SH}$ , and the Schmidt amplitudes $p_{n}$ up to $n = 39$ .
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Figure 6
For the sinc hat, from left to right we plot ${\bar{G}}^{(1)} (t) / Φ$ and a few contributions from different Schmidt modes in Eq.(3.20) with the horizontal axis normalized by $T_{p}^{SH}$ for $β = 0.1$ , 5, and 10.
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Figure 7
For the sinc hat, from left to right we plot ${\bar{G}}^{(2)} (t_{1}, t_{2}) / Φ^{2}$ (top) and the coherent and incoherent contribution to ${\bar{G}}^{(2)} (t / 2, - t / 2) / Φ^{2}$ (bottom) with the axes normalized by $T_{p}^{SH}$ for $β = 0.1$ , 5, and 10.
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Figure 8
Plot of the approximate joint spectral intensity divided by its maximum value with the axes normalized by $2 π B_{c}^{SH}$ . The “false” contributions highlighted by the black dashed circles are due to the periodicity of the function $\hat{u} (ω)$ with a period $T_{c}$ ; see the discussion in the paragraph above Eq.(4.14).
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Figure 9
From left to right we plot the sinc-hat joint temporal intensity divided by its maximum value, the approximate joint temporal intensity divided by its maximum value, and two contributions to the approximate joint temporal intensity divided by its maximum value when $n = 0$ and $n = 5$ with the axes all normalized by $T_{p}^{SH}$ .
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Figure 10
For the sinc hat calculated from the pseudo-Schmidt decomposition, from left to right we plot ${\bar{G}}^{(1)} (t) / Φ$ and a few contributions from different pseudo-Schmidt modes in Eq.(4.16) with the horizontal axis normalized by $T_{p}^{SH}$ for $β = 0.1$ , 5, and 10. In each plot the $n = - 6$ pseudo-Schmidt mode is the leftmost contribution and they move towards to right as $n$ increases.
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Figure 11
For the sinc hat calculated from the pseudo-Schmidt decomposition, from left to right we plot ${\bar{G}}^{(2)} (t_{1}, t_{2}) / Φ^{2}$ (top) and the coherent and incoherent contribution to ${\bar{G}}^{(2)} (t / 2, - t / 2) / Φ^{2}$ (bottom) with the axes normalized by $T_{p}^{SH}$ for $β = 0.1$ , 5, and 10.
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Figure 12
Using the analytical result (4.27), from left to right we plot ${\bar{G}}^{(2)} (t_{1}, t_{2}) / Φ^{2}$ (top) and the coherent and incoherent contribution to ${\bar{G}}^{(2)} (t / 2, - t / 2) / Φ^{2}$ (bottom) with the axes normalized by $T_{p}^{SH}$ for $β = 0.1$ , 5, and 10.
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Figure 13
For the double-Gaussian and using the Whittaker-Shannon decomposition, from left to right we plot the joint temporal intensity divided by its maximum value with the axes normalized by $T_{p}^{DG}$ , the joint spectral intensity divided by its maximum value with the axes normalized by $2 π B_{c}^{DG}$ , and the amplitudes $r_{n m}$ .
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Figure 14
For the double-Gaussian, from left to right we plot ${\bar{G}}^{(1)} (t) / Φ$ calculated using the Whittaker-Shannon decomposition and a few contributions from different packets in Eq.(6.8) compared with the exact calculation (3.20), with the horizontal axis normalized by $T_{p}^{DG}$ for $β = 0.1, 5$ , and 10. In each plot the $n = - 32$ packet is the leftmost contribution and they move towards to right as $n$ increases.
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Figure 15
For the double-Gaussian, from left to right we plot ${(sinh P)}_{n m}$ normalized by the respective maximum values for $β = 0.1, 5$ , and 10 with the horizontal axis normalized by $T_{p}^{DG}$ .
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Figure 16
For the double-Gaussian and using Whittaker-Shannon decompositions, from left to right we plot ${\bar{G}}^{(2)} (t_{1}, t_{2}) / Φ^{2}$ (top) and the coherent and incoherent contribution to ${\bar{G}}^{(2)} (t / 2, - t / 2) / Φ^{2}$ (bottom) with the axes normalized by $T_{p}^{DG}$ for $β = 0.1$ , 5, and 10.
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Figure 17
Schematic of the matrix $R^{I}$ which has nonzero entries centered at $β_{n_{I} n_{I}}$ with a width $d$ and zeros everywhere else. The matrix $K = β - R^{I}$ and consists of every nonzero element that we set to zero in $R^{I}$ .
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Figure 18
For the double-Gaussian, from left to right we plot ${\bar{G}}^{(1)} (t) / Φ$ calculated using the Whittaker-Shannon decomposition with the full $β_{n m}$ compared with the approximate calculation using $R^{I}$ near $t_{I} = 0$ for $d = 7, 9$ and 11, with the horizontal axis normalized by $T_{p}^{DG}$ for $β = 0.1$ , 5, and 10.
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Figure 19
Schematic of the matrix $β$ partitioned into a set of nonoverlapping matrices $R^{J}$ , each with nonzero values centered at $β_{n_{J} n_{J}}$ of size $d_{J}$ denoted by the red squares. The matrix $K = β - R^{I} - R^{II} - \dots$ and consists of every other nonzero element contained in $β$ .
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Figure 20
For the double-Gaussian joint amplitude, we plot ${\bar{G}}^{(1)} (t) / Φ$ calculated using the Schmidt decomposition (top) and Whittaker-Shannon decomposition (bottom) as well as a few contributions from each calculation, for $β = 150$ with the horizontal axis normalized by $T_{p}^{DG}$ . In the bottom plot, the smallest and leftmost contribution is from the $n = - 4$ packet and the largest is the $n = 0$ packet.
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Figure 21
For the double-Gaussian joint amplitude, we plot ${\bar{G}}^{(2)} (t_{1}, t_{2}) / Φ^{2}$ (top), and the coherent and incoherent contribution to ${\bar{G}}^{(2)} (t / 2, - t / 2) / Φ^{2}$ (bottom) calculated using the Schmidt decomposition, for $β = 150$ with the horizontal and vertical axis normalized by $T_{p}^{DG}$ .
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Figure 22
From left to right we plot the joint temporal intensity, the joint spectral intensity, and the Schmidt amplitudes generated from a dual-pump spontaneous four-wave mixing process. The two pump functions are centered at the wavelengths ${\bar{λ}}_{P1} = 1.556 µ m$ and ${\bar{λ}}_{P2} = 1.547 µ m$ and each have temporal FWHM of 100ns and an energy of $10^{3}$ pJ. The generated photons are centered at ${\bar{λ}}_{S} = 1.552 µ m$ ( ${\bar{ω}}_{S} / 2 π = 193.164$ THz) and have a bandwidth on the order of a GHz. The ring resonator has quality factors $Q_{P1} = 1 529 378, Q_{P2} = 3 844 257$ , and $Q_{S} = 2 704 405$ for the three modes and a nonlinear coupling $Λ = 5$ THz [4].
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Figure 23
Joint temporal intensity calculated using the Whittaker-Shannon decomposition.
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Figure 24
Plot of ${\bar{G}}^{(1)} (t)$ calculated using the Schmidt decomposition (top) and Whittaker-Shannon decomposition (bottom). In the top plot the $n = 10$ Schmidt corresponds to the larger contribution. In the bottom plot the $n = - 20$ is the leftmost packet.
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Figure 25
Plot of $G^{(2)} (t_{1}, t_{2})$ (top) and the coherent and incoherent contribution to $G^{(2)} (t / 2, - t / 2)$ calculated using the Whittaker-Shannon decomposition.
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Figure 26
Schematic of the sinc-hat joint intensities showing the extra contributions to the horizontal widths in the respective corners.
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Figure 27
Schematic of a general joint temporal amplitude with a pulse duration and coherence time denoted by $T_{p}$ and $T_{c}$ , respectively, in the original and rotated coordinate system.
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