An Open Dossier · 001 · v1.0.1 (living) · June 2026

Temporal-Imaging-Enhanced Dispersive-Optics Quantum Key Distribution

Irfan Ali-Khan — Independent Researcher, Saratoga, California

Energy–time entangled photon pairs carry 16–20 bits of potential key per coincidence; demonstrated systems extract 3–7, limited by detector timing jitter. This work proposes placing single-photon time lenses inside the receivers of a dispersive-optics QKD link, magnifying arrival-time structure before detection so the effective resolution beats the jitter by the magnification M — projecting 13–15 bits per coincidence and key rates of order 10⁸ b/s from demonstrated components (rate figure amended hours after launch: architecture-dependent, issue #1), with a nonlocal variant in which the fiber's own dispersion completes an imaging system that exists only in coincidences. Every number below is recomputable in your browser. Don't trust this paper — run it.

Explore the result Self-explaining edition Read the PDF Audit trail Source & issues

01 · Table 1, alive

How many bits can one photon pair carry?

This is the paper's central equation with handles on it. Pick a detector, a lens, and a guard factor; the photon information efficiency recomputes live from Eqs. (2)–(6) of the manuscript. The presets reproduce every row of Table 1.

detector jitter τ_j 30 ps

magnification M 158

lens point-spread δτ_L 1.30 ps

guard factor α 4.0

13.1bits per coincidence (PIE)

effective width σ_obs
1.86 ps

projected key rate*
3.1×10⁷ b/s

vs. no lens (M=1)
+4.5 bits

presets: 2007 SPCM · Zhong 2015 · demonstrated lens (Joshi '22) · 3 ps SNSPD + lens · projected EO lens *8 ch × 10⁶ cps × κ=0.5 × 0.6·PIE, saturation-limited (Eq. 7) · rate projections architecture-dependent — see issue #1

02 · The claims, executable

Run the paper

Sixteen checks recompute every number in the manuscript from its stated assumptions — the same arithmetic as the repository's verify_numbers.py, which CI reruns on every commit. During this paper's own audit, this process caught Table 1 overstating its result by 1.5–2.5 bits; the paper was corrected, and the catch is published in the audit trail.

verification console · 16 checks · model: Eqs. (2)–(7)

IDLEAwaiting run.

03 · Learn as you read

The five ideas this paper stands on

Schmidt number — the alphabet's size

A cw-pumped down-conversion pair is correlated to ~100 femtoseconds but coherent over ~a microsecond. The ratio K = T_coh/τ_c counts the independent "letters" the pair can encode — 10⁵–10⁶ of them, i.e. 16–20 bits per detected pair. The whole game is reading letters as small as the correlation time.

The time lens — a magnifier for moments

Dispersion is to time what diffraction is to space, so a quadratic phase in time acts exactly like a lens. Dispersion → lens → dispersion magnifies a waveform's time axis by M. Put one before your detector and a 30 ps-blurry detector resolves 30/M ps features. Demonstrated on single photons at M = 158 (Joshi et al., Optica 2022).

Nonlocal dispersion cancellation — the strange one

The pair's frequencies are anticorrelated, so dispersion applied to one photon and opposite dispersion applied to its distant partner cancel — but only in the coincidences (Franson 1992). Each photon alone is a nanosecond blur; together they are sharp. The paper conscripts this twice: as the security check, and to let the fiber itself act as a lens element.

Why not Franson interferometers?

The classic security check postselects on interferometer paths, and that postselection is a provable loophole — attacked with purely classical light (Jogenfors et al., Sci. Adv. 2015). The dispersive check involves no path postselection: two measured variances bound the eavesdropper's information through an entropic uncertainty relation.

PIE — why bits-per-photon beats raw speed

Record QKD systems extract ≲1 bit per detected photon and win by clocking fast. Wherever detected photons are the scarce resource — long-haul fiber, satellites, saturated detectors, multiplexed networks — photon information efficiency sets the rate. Moving PIE from ~7 to ~13–15 bits is the claim of this work.

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