Access the full text.
Sign up today, get DeepDyve free for 14 days.
A.A. Orlikovskii (2007)
Nanoelectronicsquantum computers and electronic sector in Russia, Elektron.: Nauka, Tekhnol., Biznes, 5
R.J. Hughes, J.E. Nordholt, D. Derkacs, C.G. Peterson (2002)
Practical free-space quantum key distribution over 10 km in daylight and at nightNew J. Phys., 4
V.L. Kurochkin, A.V. Kolyako (2016)
Investigating the bit rate of a quantum key over free spacedepending on the conditions of transmission, Bull. Russ. Acad. Sci.: Phys., 80
W. Boucher, T. Debuisschert (2005)
Experimental implementation of time-coding quantum key distributionPhys. Rev. A, 72
Yu.V. Gulyaev, Yu.L. Kopylov (1988)
VLSI technology: fundamentals and applicationsPhys. Usp., 31
Yu.I. Bogdanov, B.I. Bantysh, A.Yu. Chernyavskiy, V.F. Lukichev, A.A. Orlikovsky (2015)
Investigating the effect of amplitude and phase relaxation on the quality of quantum information technologiesRuss. Microelectron., 44
C.H. Bennet, G. Brassard (1984)
in Proceedings of the IEEE International Conference on Computer Systems and Signal Processing, Bangalore, India, December 10–19
P. Villoresi, T. Jennewein, F. Tamburini (2008)
Experimental verification of the feasibility of a quantum channel between space and earthNew J. Phys., 10
V.L. Kurochkin, A.V. Zverev, Yu.V. Kurochkin, I.I. Ryabtsev, I.G. Neizvestny (2009)
Using single-photon detectors for quantum key distribution in an experimental fiber-optic communication systemOptoelectron., Instrum. Data Process., 45
C. Kurtsiefer, P. Zarda, M. Halder (2002)
Quantum cryptography: a step towards global key distributionNature, 419
A.K. Ekert (1991)
Quantum cryptography based on Bell’s theoremPhys. Rev. Lett., 67
D. Stucki, N. Gisin, O. Guinnard, G. Ribordy, H. Zbinden (2002)
Quantum key distribution over 67 km with a plug&play systemNew J. Phys., 4
I.I. Ryabtsev, I.I. Beterov, D.B. Tretyakov, V.M. Entin, V.L. Kurochkin, A.V. Zverev, I.G. Neizvestny (2013)
Experimental quantum information with single atoms and photonsHerald Russ. Acad. Sci., 83
J.G. Rarity, P.M. Tapster, P.M. Gorman, P. Knight (2002)
Ground to satellite secure key exchange using quantum cryptographyNew J. Phys., 4
V.L. Kurochkin, I.I. Ryabtsev, I.G. Neizvestnyi (2004)
Quantum key generation based on coding of polarization states of photonsOpt. Spectrosc., 96
H. Takesue, S.W. Nam, Q. Zhang (2007)
Quantum key distribution over a 40-dB channel loss using superconducting single-photon detectorsNat. Photon., 1
A.V. Kolyako, I.G. Neizvestny, V.L. Kurochkin (2014)
Investigation the bit rate of quantum key using Si single photon detectorsJ. Phys.: Conf. Ser., 541
A. Muller, J. Breguet, N. Gisin (1993)
Experimental demonstration of quantum cryptography using polarized photons in optical fibre over more than 1 kmEurophys. Lett., 23
C.E. Shannon (1949)
Communication theory of secret systemsBell Syst. Tech. J., 28
V.L. Kurochkin, A.V. Zverev, Yu.V. Kurochkin, I.I. Ryabtsev, I.G. Neizvestny (2011)
Experimental studies in quantum cryptographyRuss. Microelectron., 40
C.H. Bennet (1992)
Quantum cryptography using any two nonorthogonal statesPhys. Rev. Lett., 68
V.L. Kurochkin, I.I. Ryabtsev, I.G. Neizvestnyi (2006)
Quantum cryptography and quantum-key distribution with single photonsRuss. Microelectron., 35
C.H. Bennet, F. Bessette, G. Brassard (1992)
Experimental quantum cryptographyJ. Cryptol., 5
J.-M. Merolla, Yu. Mazurenko, J.P. Goedgebuer, W.T. Rhodes (1999)
Single-photon interference in sidebands of phase-modulated light for quantum cryptographyPhys. Rev. Lett., 82
R. Ursin, F. Tiefenbacher, T. Schmitt-Manderbach (2007)
Entanglement based quantum communication over 144 kmNat. Phys., 3
V.L. Kurochkin, A.V. Zverev, Yu.V. Kurochkin, I.I. Ryabtsev, I.G. Neizvestnyi, R.V. Ozhegov, G.N. Gol’tsman, P.A. Larionov (2015)
Long-distance fiber-optic quantum key distribution using superconducting detectors, Optoelectron.Instrum. Data Process., 51
H. Kosaka, A. Tomita, Y. Nambu (2003)
Single-photon interference experiment over 100 km for quantum cryptography system using balanced gated-mode photon detectorElectron. Lett., 39
C. Peng, T. Yang, X. Bao (2005)
Experimental freespace distribution of entangled photon pairs over 13 km: towards satellite-based global quantum communicationPhys. Rev. Lett., 94
N. Gisin, G. Ribordy, W. Tittel (2002)
Quantum cryptographyRev. Mod. Phys., 74
V.F. Lukichev, Yu.L. Shikolenko (2015)
Modern element base of the storage devicesNano-Mikrosist. Tekh., 11
J.G. Rarity, P.R. Tapster, P.M. Gorman (2001)
Secure free-space key exchange to 1.9 km and beyondJ. Mod. Opt., 48
W.K. Wooters, W.H. Zurek (1982)
A single quantum cannot be clonedNature, 299
I.V. Radchenko, K.S. Kravtsov, S.P. Kulik, S.N. Molotkov (2014)
Relativistic quantum cryptographyLaser Phys. Lett., 11
O.V. Ivanov, S.A. Nikitov, Yu.V. Gulyaev (2006)
Cladding modes of optical fibers: properties and applicationsPhys. Usp., 49
Yu.I. Bogdanov, A.A. Kokin, V.F. Lukichev, A.A. Orlikovskii, I.A. Semenikhin, A.Yu. Chernyavskii (2012)
Quantum mechanics and development of information technologyInform. Tekhnol. Vychisl. Sist, 1
G.K. Krivyakin, A.S. Pleshkov, A.V. Zverev, I.I. Ryabtsev, V.L. Kurochkin (2014)
Noise reduction methods of single photon detector based on InGaAs/InP avalanche photodiodesJ. Phys.: Conf. Ser., 541
A. Muller, H. Zbinden, N. Gisin (1996)
Quantum cryptography over 23 km in istalled under-lake telecom fibreEurophys. Lett., 33
A.V. Gleim, V.I. Egorov, Yu.V. Nazarov (2016)
Secure polarization-independent subcarrier quantum key distribution in optical fiber channel using BB84 protocol with a strong referenceOpt. Express, 24
A. Trifonov, D. Subacius, A. Berzanskis, A. Zavriev (2004)
Single photon counting at telecom wavelength and quantum key distributionJ. Mod. Opt., 51
R.T. Thew, D. Stucki, J.-D. Gautier, H. Zbinden, A. Rochas (2007)
Free-running InGaAs/InP avalanche photodiode with active quenching for single photon counting at telecom wavelengthsAppl. Phys. Lett., 91
C. Peng, J. Zhang, D. Yang (2007)
Experimental long-distance decoy-state quantum key distribution based on polarization encodingPhys. Rev. Lett., 98
Quantum cryptography can provide almost complete security of the data transmitted in optical telecommunication systems by single photons based on the laws of quantum mechanics. The paper presents a brief overview of the element base and experimental investigations in the field of quantum cryptography and data transmission by single photons in atmospheric and optical fiber quantum communication lines. Two experimental setups for the single-photon quantum key distribution in the atmospheric and optical fiber quantum channels are described. The results of the quantum key distribution experiments performed on them are given.
Russian Microelectronics – Springer Journals
Published: Mar 23, 2017
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.