糖心vlog

Electricity powers our lives, including our cars, phones, computers and more, through the movement of electrons within a circuit. While we can鈥檛 see these electrons, electric currents moving through a conductor flow like water through a pipe to produce electricity.

Certain materials, however, allow that electron flow to 鈥渇reeze鈥� into crystallized shapes, triggering a transition in the state of matter that the electrons collectively form. This turns the material from a conductor to an insulator, stopping the flow of electrons and providing a unique window into their complex behavior. This phenomenon makes possible new technologies in quantum computing, advanced superconductivity for energy and medical imaging, lighting, and highly precise atomic clocks. 

A team of 糖心vlog-based physicists, including  Dirac Postdoctoral Fellow Aman Kumar, Associate Professor Hitesh Changlani and Assistant Professor Cyprian Lewandowski, have shown the conditions necessary to stabilize a phase of matter in which electrons exist in a solid crystalline lattice but can 鈥渕elt鈥� into a liquid state, known as a generalized Wigner crystal. Their work was published in , a Nature publication. 

HOW IT WORKS

At certain densities, electrons in two-dimensional systems are expected to form Wigner crystals, which were first theorized in 1934. These crystals have been identified in several recent experiments, but it wasn鈥檛 clear how these unique states come about when accounting for additional quantum mechanical effects. 

鈥淚n our study, we determined which 鈥榪uantum knobs鈥� to turn to trigger this phase transition and achieve a generalized Wigner crystal, which uses a 2D moir茅 system and allows different crystalline shapes to form, like stripes or honeycomb crystals, unlike traditional Wigner crystals that only show a triangular lattice crystal,鈥� Changlani said. 

The researchers used FSU鈥檚 Research Computing Center, an academic service unit of Information Technology Services, and the National Science Foundation鈥檚 ACCESS, an advanced computing and data resource program under the Office of Advanced Cyberinfrastructure, to conduct calculations and run large-scale simulations using numerical techniques like exact diagonalization, density matrix renormalization group and Monte Carlo simulations. 

In quantum mechanics, there are two pieces of quantum information for every electron. When dealing with hundreds and thousands of electrons, the amount of information becomes overwhelming. The algorithms and numerical techniques used by the team actively simplify this vast amount of information into digestible networks, allowing researchers to draw insights from it. 

鈥淲e鈥檙e able to mimic experimental findings via our theoretical understanding of the state of matter,鈥� Kumar said. 鈥淲e conduct precise theoretical calculations using state-of-the-art tensor network calculations and exact diagonalization, a powerful numerical technique used in physics to collect details about a quantum Hamiltonian, which represents the total quantum energy in a system. Through this, we can provide a picture for how the crystal states came about and why they鈥檙e favored in comparison to other energetically competitive states.鈥� 

QUANTUM PINBALLS

The team also discovered a new state of matter in which conducting and insulating properties coexist due to unusual electron behaviors. They found that the generalized Wigner crystal can partially 鈥渕elt鈥� 鈥� while some electrons remained frozen, other electrons delocalized and began moving around the system, similar to a ball zooming around fixed pins in a pinball machine. 

鈥淭his pinball phase is a very exciting phase of matter that we observed while researching the generalized Wigner crystal,鈥� Lewandowski said. 鈥淪ome electrons want to freeze and others want to float around, which means that some are insulating and some are conducting electricity. This is the first time this unique quantum mechanical effect has been observed and reported for the electron density we studied in our work.鈥� 

WHY IT MATTERS

The research gives scientists a greater understanding of how to manipulate states of matter. 

鈥淲hat causes something to be insulating, conducting or magnetic? Can we transmute something into a different state?鈥� Lewandowski said. 鈥淲e鈥檙e looking to predict where certain phases of matter exist and how one state can transition to another 鈥� when you think of turning a liquid into gas, you picture turning up a heat knob to get water to boil into steam. Here, it turns out there are other quantum knobs we can play with to manipulate states of matter, which can lead to impressive advances in experimental research.鈥� 

Tuning these knobs, or energy scales, can drive phase transitions in electrons from solid to liquid. Studying Wigner crystals offers unique insights into quantum phases of matter and has potential applications in powerful quantum computing and in spintronics 鈥� a revolutionary new field in condensed-matter physics that can increase the memory and logic processing capability of nano-electronic devices while reducing power consumption and production costs. 

The research team hopes to better understand the cooperative behavior of electrons and address theoretical questions that can lead to breakthrough applications in quantum, superconducting and atomic technologies. 

To learn more about research conducted in FSU鈥檚 Department of Physics, visit . For more on the FSU-headquartered National High Magnetic Field laboratory, visit .