Archak Purkayastha, Giacomo Guarnieri, Janet Anders, Marco Merkli
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引用次数: 0
Abstract
Thermalization of isolated and open quantum systems has been studied
extensively. However, being the subject of investigation by different
scientific communities and being analysed using different mathematical tools,
the connection between the isolated (IQS) and open (OQS) approaches to
thermalization has remained opaque. Here we demonstrate that the fundamental
difference between the two paradigms is the order in which the long time and
the thermodynamic limits are taken. This difference implies that they describe
physics on widely different time and length scales. Our analysis is carried out
numerically for the case of a double quantum dot (DQD) coupled to a fermionic
lead. We show how both OQS and IQS thermalization can be explored in this model
on equal footing, allowing a fair comparison between the two. We find that
while the quadratically coupled (free) DQD experiences no isolated
thermalization, it of course does experience open thermalization. For the
non-linearly interacting DQD coupled to fermionic lead, we show by
characterizing its spectral form factor and level spacing distribution, that
the system falls in the twilight zone between integrable and non-integrable
regimes, which we call partially non-integrable. We further evidence that,
despite being only partially non-integrable and thereby falling outside the
remit of the standard eigenstate thermalization hypothesis, it nevertheless
experiences IQS as well as OQS thermalization.
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