overview of us quantum networking efforts · – ~4k entanglement distribution and ~400 swap events...
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Eden Figueroa
Overview of US Quantum Networking Efforts
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Quantum communication
Hefei‐QN Calgary QN
Tenerife QN Vienna QN
Quantum communication:Is the ability to transmit qubits or entanglement between two distant locations.
Chinese Space QN
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Quantum Repeaters
‐ Good entanglement sources compatible with QMs.‐ QuantumMemories with good efficiency, fidelity and storage time.‐ Entanglement distribution using optical fibers.‐ All connections must preserve entanglement with high fidelity
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(Atomic ensembles: USTC China, Barcelona, Caltech)
Types of quantum light‐matter interfaces (QLMI)
(NV Diamond centers: TU Delft, Chicago/Argonne)
(SiV centers: MIT, Harvard, USA)
Type I Read‐out QLMI (Q‐registers)
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Types of quantum light‐matter interfaces (QLMI)
(Room temperature ensembles: Stony Brook, Oxford)
Type II In‐out QLMI (Q‐memory buffer)
(Single‐atoms: MPQ, Munich)
(Rare‐earth doped crystals: MPQ, Munich)
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Boston‐Area Quantum TestbedValidated for state‐of‐art quantum secure comm* [>1 Mbit/sec @16 dB, > 20 Mbits/s local]Quantum memory node (QR1) broke repeaterless bound
QR1QR1
LukinLukinLoncarLoncar
NarangNarang
Englund Englund
PolyanskiyPolyanskiy
2019 2020
8 SNSPDsSPDC & modulated laser sourcesClock distribution
QKD > 1 Mbit/sec (2019)
6*C. Lee et al, Opt. Express 27 (2019); D. Bunandar et al, PRX 8, 021009 (2018)Courtesy Dirk Englund
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Quantum Repeaters Upgrade
43 km fiber43 km fiber
42 km fiber spool42 km fiber spool
QR1QR1
LukinLukin
NarangNarang
Englund ‐BerggrenEnglund ‐Berggren
PolianskiPolianski
2019 QR2*
* assuming ERC** assuming SnV centers
External funding
QR3*QR4**
2020
2021
2023
Quantum memory node (QR1) broke repeaterless boundERC year‐3 goal: >2 NSF‐ERC quantum repeaters operationalSoliciting separate funding for LL QRs by 2023
7Courtesy Dirk Englund
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Available quantum technology in SBU quantum network
Patent pending: PCT/US19/24601 (2019) Phys. Rev. Applied 8, 034023 (2017).
Phys. Rev. Applied 8, 064013 (2017).Scientific Reports 5, 7658 (2015).
Quantum memory buffers:• High‐Fidelity (~99%)• Storage efficiency (~50%)• Storage time (~100us)• Room‐Temperature
– Resonant to 87Rb absorption line– Single photons with a 2 MHz bandwidth– Entanglement production at 10^4/sec ratios.
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Quantum Channel
Quantum memory
Photon catcher
Bob’s remote site
Quantum Network SBU: random polarization qubits and quantum cryptography
‐ On average 1.6 photons per pulses before the memory
‐ QBER of ~3.0% for Z and X bases
Phys. Rev. Applied 8, 064013 (2017)
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SBU room temperature quantum network
arXiv:1808.07015v2 (2019)
‐ Four matched EIT resonances.‐ Four simultaneous storage experiments.‐ Two polarization independent single photonlevel filters
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Presentation Name - 11Author Initials MM/DD/YY
Marconi 2.0 – US-European MEO Dual-Span Ground-to-Ground Entanglement Swap Demonstration
MIT LL Firepond
MIT LL Fiber Network
ESA Optical Ground Station,
Tenerife
Medium-EarthOrbit (MEO)
Large-ApertureTerminal
10-GHz Entanglement
Source
• MEO satellite with two quantum terminals provides trans-Atlantic ground-to-ground entanglement swap
• Pathfinder Goals:
– Multi-span scalable quantum network demonstration
– Facilitates ground terminal and quantum technology partnering
• Multiple passes per day with trans-Atlantic ground terminal line-of-sight
– ~10-min session per pass, ground elevation angle >20o
– ~4K entanglement distribution and ~400 swap events per pass
Ground Stations
Quantum Satellite
Courtesy Scott Hamilton
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BNL QIST Laboratory January 2020
Laser equipment and experimental enclosures installed
Free‐space long distance quantum link in development Portable entanglement source in construction
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• Stage I: Intercampus network for MDI QKD Quantum‐secure keys and post quantum encryption for
key sharing with Analysis on the Wire (AoW) nodes Collaboration BNL (lead), SBU, ORNL, and LANL. Funded by DOE CESER and SBU
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ECC
CEWIT
QIT I
Quantum Memory
Entangled Source
Quantum Memoriesand Bell measurement
Entangled Source
Quantum Memory
@795nm
@795nm
QIT II
HST
Stage II: Quantum repeater prototype @ 795 nm Memory assisted entanglement swapping. Entanglement distribution beyond fibre losses. Funded by NSF, DOE ASCR, SBU and Simons Foundation
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Quantum entanglement distribution between BNL and SBU
SBU Hospital North Tower Elevator Shaft
SBU (view from BNL)
701 Roof
BNL (view from SBU) Top of SBU HST
QuantumTransmitter
QuantumReceiver
Entanglement source
Entanglement detection
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Free Space Link ~20km
SDCC535
701
ECC
CEWIT
HS TOWER
PHYSICS
Stage III: Free space expansion to BNL Long distance operation at 795 nm. Entanglement distribution between SBU and BNL. Funded by SBU and BNL PDs
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SDCC
535
Entangled Source
~60km ~50km
~100km
@795nm
FC
FC
Garden City
Stage IV: Entanglement distribution at telecom wavelengths. Memory‐compatible telecom entanglement. Polarization compensation over long distances. Funded DOE ASCAR and BNL LDRD.
Entanglement source
+
Quantum memories/frequency conversion
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SDCC535
ECC
CEWIT
QIT I
~60km
Entangled Source
Quantum Memory
Quantum Memory
Entangled Source
Quantum Memoriesand Bell measurement
Stage V: Quantum repeater prototype @ 1324 nm Memory assisted entanglement distribution > 170 km. First prototype of a long‐distance quantum repeater. Funded by DOE ASCR and DOE CESER.
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Research questions I
•Deployable “plug‐tune & play” systems. •Miniaturized for real‐networks & outside of the laboratory storage.
‐ Increase the memory depth.‐ Multiplexing and routing to enhance the network rates.
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•Demonstrate quantum‐memory‐assisted entanglement swapping in a full quantum repeater network.
•Add quantum‐gate capabilities to the entanglement distribution networks.• Investigate error correction.
Research questions II
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Science Advances 5, eaav4651(2019)
•Increase entanglement generation rates.•Interface hybrid systems materials/light/atoms.
•Interface different quantum light‐matter systems.
Research questions III