Abstract
Decoherence is all around us. Every quantum system that interacts with the environment is doomed to decohere. The preservation of quantum coherence is one of the major challenges faced in quantum technologies, but its use as a resource is very promising and can lead to various operational advantages, for example in quantum algorithms. Hence, much work has been devoted in recent years to quantify the coherence present in a system. In the present paper, we formulate the quantum resource theory of dynamical coherence. The underlying physical principle we follow is that the free dynamical objects are those that cannot preserve or distribute coherence. This leads us to identify classical channels as the free elements in this theory. Consequently, even the quantum identity channel is not free as all physical systems undergo decoherence and hence, the preservation of coherence should be considered a resource. In our work, we introduce four different types of free superchannels (analogous to MIO, DIO, IO, and SIO) and discuss in detail two of them, namely, dephasing-covariant incoherent superchannels (DISC), maximally incoherent superchannels (MISC). The latter consists of all superchannels that do not generate non-classical channels from classical ones. We quantify dynamical coherence using channel-divergence-based monotones for MISC and DISC. We show that some of these monotones have operational interpretations as the exact, the approximate, and the liberal coherence cost of a quantum channel. Moreover, we prove that the liberal asymptotic cost of a channel is equal to a new type of regularized relative entropy. Finally, we show that the conversion distance between two channels under MISC and DISC can be computed using a semi-definite program (SDP).
Highlights
Like maximally incoherent operations (MIO) in the Quantum resource theories (QRTs) of static coherence, we define as one class of free superchannels the set of maximally incoherent superchannels (MISC), which is the entirety of all superchannnels that do not generate nonclassical channels from classical ones
We find a complete set of monotones under the free superchannels MISC and dephasing-covariant incoherent superchannels (DISC), and show that for the dynamical resource theory of coherence, these functions can be computed using an semidefinite program (SDP)
We have developed the resource theory of dynamical coherence using the classical channels as free channels
Summary
Even the identity channel can be considered as a resource since all physical systems undergo decoherence, and the preservation of coherence in a quantum memory (for some given time or some specified distance [40]) should be considered a resource While both the T gate and the identity are detection incoherent, they are identified as dynamical resources when limiting the free channels to be classical. As argued above in the case of static coherence, a free implementation of the allowed operations should not necessarily be required to detect or learn about the resource contained in a state We apply this principle on the level of superchannels. Like MIO in the QRT of static coherence, we define as one class of free superchannels the set of maximally incoherent superchannels (MISC), which is the entirety of all superchannnels that do not generate nonclassical channels from classical ones. V E, we formulate the one-shot distillable dynamical coherence and compute its value for a few specific channels
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