TY - JOUR
T1 - Using and reusing coherence to realize quantum processes
AU - Díaz, María García
AU - Fang, Kun
AU - Wang, Xin
AU - Rosati, Matteo
AU - Skotiniotis, Michalis
AU - Calsamiglia, John
AU - Winter, Andreas
N1 - Funding Information:
The authors thank Bartosz Regula, Zi-Wen Liu, Nilanjana Datta and Andrea R. Blanco for interesting discussions on various aspects of the present work. The authors acknowledge support from Spanish MINECO, project FIS2016-80681-P with the support of AEI/FEDER funds; the Generalitat de Catalunya, project CIRIT 2017-SGR-1127. MGD is supported by a doctoral studies fellowship of the Fundación “la Caixa”. MS is supported by the Spanish MINECO, project IJCI-2015-24643.
Publisher Copyright:
© Verein zur Forderung des Open Access Publizierens in den Quantenwissenschaften.
Copyright:
Copyright 2020 Elsevier B.V., All rights reserved.
PY - 2018/10/19
Y1 - 2018/10/19
N2 - Coherent superposition is a key feature of quantum mechanics that underlies the advantage of quantum technologies over their classical counterparts. Recently, coherence has been recast as a resource theory in an attempt to identify and quantify it in an operationally well-defined manner. Here we study how the coherence present in a state can be used to implement a quantum channel via incoherent operations and, in turn, to assess its degree of coherence. We introduce the robustness of coherence of a quantum channel-which reduces to the homonymous measure for states when computed on constant-output channels-and prove that: I) it quantifies the minimal rank of a maximally coherent state required to implement the channel; ii) its logarithm quantifies the amortized cost of implementing the channel provided some coherence is recovered at the output; iii) its logarithm also quantifies the zeroerror asymptotic cost of implementation of many independent copies of a channel. We also consider the generalized problem of imperfect implementation with arbitrary resource states. Using the robustness of coherence, we find that in general a quantum channel can be implemented without employing a maximally coherent resource state. In fact, we prove that every pure coherent state in dimension larger than 2, however weakly so, turns out to be a valuable resource to implement some coherent unitary channel. We illustrate our findings for the case of single-qubit unitary channels.
AB - Coherent superposition is a key feature of quantum mechanics that underlies the advantage of quantum technologies over their classical counterparts. Recently, coherence has been recast as a resource theory in an attempt to identify and quantify it in an operationally well-defined manner. Here we study how the coherence present in a state can be used to implement a quantum channel via incoherent operations and, in turn, to assess its degree of coherence. We introduce the robustness of coherence of a quantum channel-which reduces to the homonymous measure for states when computed on constant-output channels-and prove that: I) it quantifies the minimal rank of a maximally coherent state required to implement the channel; ii) its logarithm quantifies the amortized cost of implementing the channel provided some coherence is recovered at the output; iii) its logarithm also quantifies the zeroerror asymptotic cost of implementation of many independent copies of a channel. We also consider the generalized problem of imperfect implementation with arbitrary resource states. Using the robustness of coherence, we find that in general a quantum channel can be implemented without employing a maximally coherent resource state. In fact, we prove that every pure coherent state in dimension larger than 2, however weakly so, turns out to be a valuable resource to implement some coherent unitary channel. We illustrate our findings for the case of single-qubit unitary channels.
UR - http://www.scopus.com/inward/record.url?scp=85093862192&partnerID=8YFLogxK
U2 - 10.22331/q-2018-10-19-100
DO - 10.22331/q-2018-10-19-100
M3 - Article
AN - SCOPUS:85093862192
SN - 2521-327X
VL - 2
JO - Quantum
JF - Quantum
ER -