Quantum Brain
← Back to papers

Markovianization with approximate unitary designs

Pedro Figueroa–Romero, F. A. Pollock, K. Modi·April 16, 2020·DOI: 10.1038/s42005-021-00629-w
Physics

AI Breakdown

Get a structured breakdown of this paper — what it's about, the core idea, and key takeaways for the field.

Abstract

Memoryless processes are ubiquitous in nature, in contrast with the mathematics of open systems theory, which states that non-Markovian processes should be the norm. This discrepancy is usually addressed by subjectively making the environment forgetful. Here we prove that there are physical non-Markovian processes that with high probability look highly Markovian for all orders of correlations; we call this phenomenon Markovianization. Formally, we show that when a quantum process has dynamics given by an approximate unitary design, a large deviation bound on the size of non-Markovian memory is implied. We exemplify our result employing an efficient construction of an approximate unitary circuit design using two-qubit interactions only, showing how seemingly simple systems can speedily become forgetful. Conversely, since the process is closed, it should be possible to detect the underlying non-Markovian effects. However, for these processes, observing non-Markovian signatures would require highly entangling resources and hence be a difficult task. A question of foundational importance is ‘ w h y   i s   n a t u r e   f o r g e t f u l ?’, playing an important role in our understanding of thermodynamics. Here, the authors study a class of quantum processes, called approximate unitary designs, to show that these processes are highly forgetful - i.e. Markovian.

Related Research

Quantum Intelligence

Ask about quantum research, companies, or market developments.