Quantum remote sensing under the effect of dephasing

The quantum remote sensing (QRS) is a scheme to add security about the measurement results of a qubit-based sensor. A client delegates a measurement task to a remote server that has a quantum sensor, and eavesdropper (Eve) steals every classical information stored in the server side. By using quantum properties, the QRS provides an asymmetricity about the information gain where the client gets more information about the sensing results than Eve. However, quantum states are fragile against decoherence, and so it is not clear whether such a QRS is practically useful under the effect of realistic noise. Here, we investigate the performance of the QRS with dephasing during the interaction with the target fields. In the QRS, the client and server need to share a Bell pair, and an imperfection of the Bell pair leads to a state preparation error in a systematic way on the server side for the sensing. We consider the effect of both dephasing and state preparation error. The uncertainty of the client side decreases with the square root of the repetition number $M$ for small $M$, which is the same scaling as the standard quantum metrology. On the other hand, for large $M$, the state preparation error becomes as relevant as the dephasing, and the uncertainty decreases logarithmically with $M$. We compare the information gain between the client and Eve. This leads us to obtain the conditions for the asymmetric gain to be maintained even under the effect of dephasing.

[1]  Philip Walther,et al.  Demonstration of measurement-only blind quantum computing , 2016, 1601.02451.

[2]  Jacob M. Taylor,et al.  Nanoscale magnetic sensing with an individual electronic spin in diamond , 2008, Nature.

[3]  Tomoyuki Morimae,et al.  Resource-efficient verification of quantum computing using Serfling’s bound , 2018, npj Quantum Information.

[4]  G. G. Stokes "J." , 1890, The New Yale Book of Quotations.

[5]  P. Alam ‘A’ , 2021, Composites Engineering: An A–Z Guide.

[6]  A. Yacoby,et al.  A robust, scanning quantum system for nanoscale sensing and imaging , 2011, 1108.4437.

[7]  Jianyong Chen,et al.  High-dimensional cryptographic quantum parameter estimation , 2017, Quantum Information Processing.

[8]  Seth Lloyd,et al.  Quantum cryptographic ranging , 2002 .

[9]  Srihari Keshavamurthy,et al.  Annual Review of Physical Chemistry, 2015 , 2016 .

[10]  Elham Kashefi,et al.  Demonstration of Blind Quantum Computing , 2011, Science.

[11]  R. Schirhagl,et al.  Nitrogen-vacancy centers in diamond: nanoscale sensors for physics and biology. , 2014, Annual review of physical chemistry.

[12]  Margarita A. Man’ko,et al.  Journal of Optics B: Quantum and Semiclassical Optics , 2003 .

[13]  I. Chuang,et al.  Quantum Computation and Quantum Information: Introduction to the Tenth Anniversary Edition , 2010 .

[14]  Gilles Brassard,et al.  Quantum cryptography: Public key distribution and coin tossing , 2014, Theor. Comput. Sci..

[15]  D Budker,et al.  Solid-state electronic spin coherence time approaching one second , 2012, Nature Communications.

[16]  Proceedings of the Royal Society (London) , 1906, Science.

[17]  D. Berry,et al.  Entanglement-free Heisenberg-limited phase estimation , 2007, Nature.

[18]  S. Lloyd,et al.  Quantum-enhanced positioning and clock synchronization , 2001, Nature.

[19]  I. Chuang,et al.  Experimental realization of Shor's quantum factoring algorithm using nuclear magnetic resonance , 2001, Nature.

[20]  R Hanson,et al.  Universal Dynamical Decoupling of a Single Solid-State Spin from a Spin Bath , 2010, Science.

[21]  Jieping Ye,et al.  A quantum network of clocks , 2013, Nature Physics.

[22]  L. Hollenberg,et al.  Sensing electric fields using single diamond spins , 2011, 1103.3432.

[23]  L. Jiang,et al.  Quantum entanglement between an optical photon and a solid-state spin qubit , 2010, Nature.

[24]  Alfred Leitenstorfer,et al.  Nanoscale imaging magnetometry with diamond spins under ambient conditions , 2008, Nature.

[25]  D. Suter,et al.  High-precision nanoscale temperature sensing using single defects in diamond. , 2013, Nano letters.

[26]  Artur Ekert,et al.  Quantum computers and dissipation , 1996, Proceedings of the Royal Society of London. Series A: Mathematical, Physical and Engineering Sciences.

[27]  Jonathan A. Jones,et al.  Magnetic Field Sensing Beyond the Standard Quantum Limit Using 10-Spin NOON States , 2008, Science.

[28]  장윤희,et al.  Y. , 2003, Industrial and Labor Relations Terms.

[29]  D. Budker,et al.  Optical magnetometry - eScholarship , 2006, physics/0611246.

[30]  J Wrachtrup,et al.  High-dynamic-range magnetometry with a single nuclear spin in diamond. , 2012, Nature nanotechnology.