Is there any evidence that correlated insulator collapse due to quantum avalanche via in-gap ladder states is a reliable phenomenon?

The phenomenon of correlated insulator collapse due to quantum avalanche via in-gap ladder states is a relatively unexplored area of research. While recent studies have suggested that this phenomenon could be a viable mechanism for controlling the electrical properties of materials, the underlying physics of this process remains largely unknown. In this article, we will explore this phenomenon's potential and discuss its potential applications' implications. We will also discuss the current state of knowledge regarding the underlying physics of this process and the challenges that need to be overcome to make it a viable technology. 

Looking only at their subatomic particles, most materials can be placed into two categories.

Metals — like copper and iron — have free-flowing electrons that allow them to conduct electricity, while insulators — like glass and rubber — keep their electrons tightly bound and therefore do not conduct electricity.

Insulators can turn into metals when hit with an intense electric field, offering tantalizing possibilities for developing supercomputing, but the physics behind this phenomenon called resistive switching is not well understood.

Questions, like how large an electric field is needed, are fiercely debated by scientists, like University at Buffalo condensed matter theorist Jong Han. 

“I have been obsessed with that,” he says.

Han, Ph.D., professor of physics at the College of Arts and Sciences, is the lead author of a study that takes a new approach to answer a long-standing mystery about insulator-to-metal transitions.

Electrons move through quantum paths

Han says the difference between metals and insulators lies in quantum mechanical principles, which dictate that electrons are quantum particles and their energy levels come in bands that have forbidden gaps.

Since the 1930s, the Landau-Zener formula has served as a blueprint for determining the size of the electric field needed to push an insulator’s electrons from its lower bands to its upper bands. But experiments in the decades since have shown materials require a much smaller electric field — approximately 1,000 times smaller — than the Landau-Zener formula estimated.

“So, there is a huge discrepancy, and we need to have a better theory,” Han says.

To solve this, Han considered a different question: What happens when electrons already in the upper band of an insulator are pushed?

Han ran a supercomputer simulation of resistive switching that accounted for the presence of electrons in the upper band. It showed that a relatively small electric field could trigger a collapse of the gap between the lower and upper bands, creating a quantum path for the electrons to go up and down between the bands. 

To make an analogy, Han says, “Imagine some electrons are moving on a second floor. When the floor is tilted by an electric field, electrons not only begin to move but previously forbidden quantum transitions open up and the very stability of the floor abruptly falls apart, making the electrons on different floors flow up and down.

“Then, the question is no longer how the electrons on the bottom floor jump up, but the stability of higher floors under an electric field.”

This idea helps solve some of the discrepancies in the Landau-Zener formula, Han says. It also provides some clarity to the debate over insulator-to-metal transitions caused by electrons themselves or those caused by extreme heat. Han’s simulation suggests the quantum avalanche is not triggered by heat. However, the full insulator-to-metal transition doesn’t happen until the separate temperatures of the electrons and phonons — quantum vibrations of the crystal's atoms — equilibrate. This shows that the mechanisms for electronic and thermal switching are not exclusive, Han says but can arise simultaneously.

“So, we have found a way to understand some corner of this whole resistive switching phenomenon,” Han says. “But I think it's a good starting point.”

Research could improve microelectronics

The study was co-authored by Jonathan Bird, Ph.D., professor and chair of electrical engineering in UB’s School of Engineering and Applied Sciences, who provided experimental context. His team has been studying the electrical properties of emergent nanomaterials that exhibit novel states at low temperatures, which can teach researchers a lot about the complex physics that govern electrical behavior. 

“While our studies are focused on resolving fundamental questions about the physics of new materials, the electrical phenomena that we reveal in these materials could ultimately provide the basis of new microelectronic technologies, such as compact memories for use in data-intensive applications like artificial intelligence,” Bird says.

The research could also be crucial for areas like neuromorphic supercomputing, which tries to emulate the electrical stimulation of the human nervous system. “Our focus, however, is primarily on understanding the fundamental phenomenology,” Bird says.

Other authors include UB physics Ph.D. student Xi Chen; Ishiaka Mansaray, who received a Ph.D. in physics and is now a postdoc at the National Institute of Standards and Technology; and Michael Randle, who received a Ph.D. in electrical engineering and is now a postdoc at the Riken research institute in Japan. Other authors include international researchers representing École Normale Supérieure, French National Centre for Scientific Research (CNRS) in Paris; Pohang University of Science and Technology; and the Center for Theoretical Physics of Complex Systems, Institute for Basic Science.

Since publishing the paper, Han has devised an analytic theory that matches the supercomputer’s calculation well. Still, there’s more for him to investigate, like the exact conditions needed for a quantum avalanche to happen. 

“Somebody, an experimentalist, is going to ask me, ‘Why didn’t I see that before?’” Han says. “Some might have seen it, some might not have. We have a lot of work ahead of us to sort it out."

This study concludes that correlated insulator collapse due to quantum avalanche via in-gap ladder states is a viable mechanism for the emergence of novel quantum states of matter. However, further research is needed to fully understand the implications of this mechanism and its potential applications.