#quantum materials

Ultracold atoms could provide 2-D window to exotic 1-D physics

Rice University physicists Matthew Foster and Seth Davis want to view a vexing quantum puzzle from an entirely new perspective. They just need the right vantage point and a place colder than deep space.

"There's a process in strongly interacting physics where fundamental particles, like electrons, can come together and behave as if they were a fraction of an electron," said Davis, a graduate student in Foster's research group. "It's called fractionalization. It's a really exotic, fundamental process that shows up theoretically in many places. It may have something to do with high-temperature superconductivity, and it could be useful for building quantum computers. But it's very hard to understand and even harder to measure."

In a recent paper in Physical Review Letters, Foster and Davis, both theoretical physicists, proposed an experiment to measure fractionalization not in electrons but in atoms so cold they follow the same quantum rules that dictate how electrons behave in quantum materials, a growing class of materials with exotic electronic and physical properties that governments and industry are eying for next-generation computers and electronic devices.

Image – Elias Levy, flickr.

Research out of Purdue University, USA, has shown that a sensor designed to mimic a shark’s ability to detect the minute electric fields of small prey could be used for defence or marine biology applications.

Shriram Ramanathan, a professor of materials engineering at Purdue, told of how the device maintains stability and does not corrode in saltwater. 

‘We have been working on this for a few years,’ added Ramanathan. ‘We show that these sensors can detect electrical potentials well below one volt, on the order of millivolts, which is comparable to electric potentials emanated by marine organisms. 

‘The material is very sensitive. We calculated the detection distance of our device and find a similar length scale to what has been reported for electroreceptors in sharks.’

Purdue’s sensor was inspired by the ampullae of Lorenzini, an organ near a shark’s mouth, which can detect small electric fields from prey animals. The organ contains a jelly to conduct ions from seawater to a membrane located at the bottom of the ampulla. This, added postdoctoral research associate Zhen Zhang, means it can ‘interact with its environment by exchanging ions from seawater, imparting the so-called sixth sense to sharks’.

The sensor is made of a material called samarium nickelate, which is a quantum material, meaning its performance taps into quantum mechanical interactions.

Meet Madelynn Nayga:

1) What do you do?

I am currently a diploma student in condensed matter and statistical physics. For my short project, I am focusing on theoretical models of quantum magnets in low dimension. In particular, I will be investigating whether phase transitions occur at zero temperature.

2) Where do you work?

I am a student in the Diploma Programme at the International Centre for Theoretical Physics (ICTP) in Trieste, Italy.

3) Tell us about the photos!

[Left:] This is a photo of me during my master's thesis defense at the National Institute of Physics, UP Diliman. My work focused on mathematical techniques for solving the fractional Schrödinger equation, which contains fractional derivative operators.

[Right:] When I have time (and extra money), I love to go on trips and explore cities. This photo was taken in Venice, Italy, one of my favorite cities. This trip was actually a reward to myself for getting a PhD position.

4) Tell us about your academic career path so far.

I completed my high school education at the Central Visayan Institute Foundation in Jagna, Bohol. It was in this school where I first dreamed of becoming a physicist. I was greatly inspired by our school's administrators, Dr. Christopher Bernido and Dr. Maria Victoria Carpio-Bernido, who are both physicists.

I wasn't confident enough to take physics that's why I didn't choose BS Physics when I took the UPCAT. As I have always loved mathematics since grade school, I entered UP Los Baños as a BS Applied Mathematics student. However, I knew that I will always have my "what ifs" had I not pursued for what I really wanted. So after one year, I transferred to UP Diliman and took BS Physics. I then pursued MS Physics while being employed as a Physics instructor at the same university.

I am currently a diploma student in ICTP and I will soon start my PhD at the International Max Planck Research School for Chemistry and Physics of Quantum Materials in Dresden, Germany.

5) Anything else you’d like to share?

Image request: A split image: one side shows an old, dusty textbook open to a page describing ferroelectric materials; the other side depicts a futuristic, stylized visualization of a quantum computer’s internal workings. Color palette leans towards vintage sepia tones on the left, vibrant blues and greens on the right. Subtle light rays connect both sides symbolizing potential connection between…

A Quantum Breakthrough brings a technique from Astronomy to the Nano-scale – UC San Diego and Columbia University

IMAGE: THE DISCOVERY OF MULTI-MESSENGER NANOPROBES ALLOWS SCIENTISTS TO SIMULTANEOUSLY PROBE MULTIPLE PROPERTIES OF QUANTUM MATERIALS AT NANOMETER-SCALE SPATIAL RESOLUTIONS. view more  CREDIT: ELLA MARU STUDIO

Researchers at Columbia University and University of California, San Diego,have introduced a novel “multi-messenger” approach to quantum physics that signifies a technological leap in…

Scientists Finally Find Superconductivity in Exactly the Place They’ve Been Looking for Decades

Researchers at Stanford University and the Department of Energy’s SLAC National Accelerator Laboratory say they have found the first, long-sought proof that a decades-old scientific model of material behavior can be used to simulate and understand high-temperature superconductivity ­– an important step toward producing and controlling this puzzling phenomenon at will.

The simulations they ran, 

Quantum Leap: DOE Grant aims to Speed Software Development for Quantum Materials

Better understanding quantum materials and translating that knowledge to practical technologies is the focus of a new $2.75 million Penn State-led project funded by the U.S. Department of Energy.

A team of researchers, led by Long-Qing Chen, Donald W. Hamer Professor of Materials Science and Engineering in the College of Earth and Mineral Sciences, received a four-year grant to advance the…

Novel Process for Structuring Quantum Materials

Implementing quantum materials in computer chips provides access to fundamentally new technologies. To build high-performance quantum computers, for example, topological insulators have to be combined with superconductors. This fabrication step is associated with a number of challenges that have now been solved by researchers from Jülich.

Already the Incas used knots in cords in their ancient…