QKD: add part on MDI-QKD

main.bib

@@ -70,6 +70,26 @@
   file = {/home/jaseg/Zotero/storage/2EYFTVCY/Amiri et al. - 2018 - Efficient Unconditionally Secure Signatures Using .pdf}
 }
 
+@article{amitonovaQuantumKeyEstablishment2020,
+  title = {Quantum Key Establishment via a Multimode Fiber},
+  author = {Amitonova, Lyubov V. and Tentrup, Tristan B. H. and Vellekoop, Ivo M. and Pinkse, Pepijn W. H.},
+  date = {2020-03-02},
+  journaltitle = {Optics Express},
+  shortjournal = {Opt. Express, OE},
+  volume = {28},
+  number = {5},
+  pages = {5965--5981},
+  publisher = {Optica Publishing Group},
+  issn = {1094-4087},
+  doi = {10.1364/OE.380791},
+  url = {https://opg.optica.org/oe/abstract.cfm?uri=oe-28-5-5965},
+  urldate = {2024-09-04},
+  abstract = {Quantum communication aims to provide absolutely secure transmission of secret information. State-of-the-art methods encode symbols into single photons or coherent light with much less than one photon on average. For long-distance communication, typically a single-mode fiber is used and significant effort has been devoted already to increase the data carrying capacity of a single optical line. Here we propose and demonstrate a fundamentally new concept for remote key establishment. Our method allows high-dimensional alphabets using spatial degrees of freedom by transmitting information through a light-scrambling multimode fiber and exploiting the no-cloning theorem. Eavesdropper attacks can be detected without using randomly switched mutually unbiased bases. We prove the security against a common class of intercept-resend and beam-splitting attacks with single-photon Fock states and with weak coherent light. Since it is optical fiber based, our method allows to naturally extend secure communication to larger distances. We experimentally demonstrate this new type of key exchange method by encoding information into a few-photon light pulse decomposed over guided modes of an easily available multimode fiber.},
+  langid = {english},
+  keywords = {Multicore fibers,Multimode fibers,Quantum communications,Quantum key distribution,Single mode fibers,Space division multiplexing},
+  file = {/home/jaseg/Sync/Research/Zotero/2020_Amitonova et al_Quantum key establishment via a multimode fiber.pdf}
+}
+
 @online{AntimatterAlgorithmThat,
   title = {Antimatter: An Algorithm That Prunes {{CRDT}}/{{OT}} History},
   url = {https://braid.org/antimatter},
@@ -775,6 +795,26 @@
   file = {/home/jaseg/Zotero/storage/VI2VBKAG/Choi et al. - 2010 - Halbach Magnetic Circuit for Voice Coil Motor in H.pdf}
 }
 
+@article{choiQuantumKeyDistribution2010,
+  title = {Quantum Key Distribution on a {{10Gb}}/s {{WDM-PON}}},
+  author = {Choi, Iris and Young, Robert J. and Townsend, Paul D.},
+  date = {2010-04-26},
+  journaltitle = {Optics Express},
+  shortjournal = {Opt. Express, OE},
+  volume = {18},
+  number = {9},
+  pages = {9600--9612},
+  publisher = {Optica Publishing Group},
+  issn = {1094-4087},
+  doi = {10.1364/OE.18.009600},
+  url = {https://opg.optica.org/oe/abstract.cfm?uri=oe-18-9-9600},
+  urldate = {2024-09-04},
+  abstract = {We present the first demonstration of quantum key distribution (QKD) on a multi-user wavelength division multiplexed passive optical network (WDM-PON) with simultaneous, bidirectional 10Gb/s classical channel transmission. The C-Band QKD system operates at a clock rate of 10GHz and employs differential phase shift keying (DPSK). A dual feeder fiber and band filtering scheme is used to suppress classical to quantum channel cross-talk generated by spontaneous Raman scattering, which would otherwise prevent secure key distribution. Quantum keys were distributed to 4 users with negligible Raman cross-talk penalties. The mean QBER value for 4 users was 3.5\% with a mean raw key distribution rate of 1.3Mb/s, which decreased to 696kb/s after temporal windowing to reduce inter-symbol interference due to single photon detector timing jitter.},
+  langid = {english},
+  keywords = {Passive optical networks,Quantum cryptography,Quantum key distribution,Raman scattering,Stimulated Raman scattering,Wavelength division multiplexing},
+  file = {/home/jaseg/Sync/Research/Zotero/2010_Choi et al_Quantum key distribution on a 10Gb-s WDM-PON.pdf}
+}
+
 @incollection{choudhuriComplexitySecureComputation2020,
   title = {The {{Round Complexity}} of {{Secure Computation Against Covert Adversaries}}},
   booktitle = {Security and {{Cryptography}} for {{Networks}}},