The arrow of time is a staple of human perception. Every second of every minute of every hour of every day, you live it. If you spill a drink, you can鈥檛 reverse time and pull the liquid back into the cup.
But beneath the fabric of our perceived reality is a quantum realm, a world of subatomic particles that behave in ways baffling to our classical understanding of the universe. It鈥檚 a world of quantum superpositions, in which systems exist in multiple states until they鈥檙e measured.
鈥淨uantum physics doesn鈥檛 just tell one story; it tells many probabilities of different stories,鈥 said Distinguished Professor of Physics and Astronomy who directs the at 嘿嘿视频. 鈥淚n the cosmology world, there鈥檚 a question of how did the universe come to be such a thing that鈥檚 so good at hiding quantum physics?鈥
For Albrecht, the answer to that question may lie in investigating the relationship between quantum physics and the arrow of time.
In two papers appearing in Physical Review Research, Albrecht and his colleagues introduce a new model to explore the phenomenon of decoherence, which is when a system鈥檚 behavior shifts from being explainable by quantum mechanics to being explainable by classical mechanics.
鈥淒ecoherence is part of the reason why you and I experience a classical reality largely free from quantum 鈥榳eirdness,鈥欌 said Rose Baunach, a physics graduate student and the papers鈥 co-author. 鈥淚t鈥檚 the process by which quantum superpositions are reduced to classical states due to interactions with an environment.鈥
In their work, Albrecht, Baunach and Andrew Arrasmith, of Los Alamos National Laboratory, divorce the arrow of time from the go-to theoretical tool for understanding decoherence: the Caldeira-Leggett model.
Adapting the Caldeira-Leggett model
Since time is inherent to our perception of the universe, it鈥檚 often unthinkingly included in our theories about how the universe works. Albrecht referred to this phenomenon as 鈥渢emporal provincialism,鈥 a term popularized in the physics community by Leonard Susskind, the Felix Bloch Professor of Physics at Stanford University.
鈥淲e鈥檙e so used to the arrow of time being part of our world that we very naturally include it in our theories unquestioningly,鈥 Albrecht said. 鈥淲e鈥檙e so stuck in our little world, or our little universe, that we forget how things might actually be.鈥
The standard Caldeira-Leggett model, introduced in 1981, is temporally provincial with the arrow of time built into the math underlying the model. But the arrow of time, or rather our perception of it, isn鈥檛 necessarily an underlying component of the universe.
鈥淎s far as we know, the laws of physics don鈥檛 have an arrow of time and they respect both directions of time equally at sort of the fundamental level,鈥 said Albrecht, who used the classic force equation (Force = mass x acceleration) as an example. 鈥淚f I throw a ball, F=ma applies to that ball. If we show a video where the ball is coming back to me, it鈥檚 still F=ma.鈥
With this percolating in his mind, Albrecht sought to develop a way to divorce the arrow of time from the Caldeira-Legett model, eventually coming up with the
鈥淚 wanted to ask the questions: What would happen if we didn鈥檛 have an arrow of time?鈥 Albrecht said. 鈥淗ow would decoherence work? Would you be able to hide quantum physics the same way? Would quantum physics work the same way?鈥
鈥淲hat we learned is that quantum physics is so mercurial that you can have a universe without an arrow of time, but to a creature like us, it looks like it has an arrow of time,鈥 he added.
Copycats and decoherence
To develop the utility of the Adapted Caldeira-Leggett model, Albrecht tapped Baunach to test the model during the earliest stages of decoherence and einselection, the latter term describing a 鈥渟pecial type of decoherence where interactions between a system and its environment cause the system to evolve into a particularly stable state,鈥 according to Baunach.
鈥淭hese stable states are particularly resistant to further quantum disruption from the environment, and hence are very common in nature,鈥 she said.
The resulting paper, 鈥,鈥 investigates the space between the start of decoherence and complete einselection, identifying and mathematically describing a new phenomenon that occurs early during decoherence, which the team calls the 鈥渃opycat process.鈥
鈥淲e now know that immediately after a system is set up in a quantum superposition, it will go through the copycat process during the early stages of decoherence as it begins to interact with its environment,鈥 Baunach said. 鈥淭he copycat process gets its name from the fact that we found the two states describing the system at the onset of decoherence are mirror images of each other in the simplest examples we鈥檝e studied.鈥
Understanding the decoherence process at this granular level may be particularly important to developing successful quantum computing methods.
鈥淔or quantum computations to be possible, we need to preserve the quantum superposition capabilities of quantum bits 鈥 which means mitigating the effects of decoherence from their surrounding environment,鈥 Baunach said. 鈥淲e hope that the addition of the copycat process to the literature on decoherence will increase our field鈥檚 understanding of this important physical phenomenon.鈥
鈥淭oday, everyone is trying so hard to engineer quantum objects,鈥 Albrecht added. 鈥淥ur work provides a detailed understanding of how quantum objects behave in the very beginning of this decoherence.鈥
Media Resources
(ArXiv.org)
(ArXiv.org)
Greg Watry is a writer with the College of Letters and Science, where this article was (if you accept sequential time, of course).