Experiments confirm the unique response of a quantum material to circularly polarized laser light
Newswise – When the COVID-19 pandemic ended experiments at the Department of Energy’s National SLAC Accelerator Lab early last year, Shambhu Ghimire’s research group was forced to find another way to study an intriguing research target: quantum materials known as topological insulators, or TIs, which conduct electric current on their surfaces but not through their interiors.
Denitsa Baykusheva, a member of the Swiss National Science Foundation, had joined her group at the Stanford PULSE Institute two years earlier with the goal of finding a way to generate high harmonic generation, or HHG, in these materials as a tool for probe their behavior. In HHG, laser light passing through a material travels to higher energies and frequencies, called harmonics, much like pressing a guitar string produces higher notes. If this could be done in IT, which are promising building blocks for technologies such as spintronics, quantum sensing, and quantum computing, it would give scientists a new tool to study these and other quantum materials. .
With the experiment stopped halfway, she and her colleagues turned to theory and computer simulations to find a new recipe for generating HHG in topological insulators. The results suggested that the circularly polarized light, which spirals along the direction of the laser beam, would produce clear and unique signals from both the conductive surfaces and the interior of the TI they were studying, bismuth selenide – and would actually improve the incoming signal. surfaces.
When the lab reopened for experiments with covid safety precautions in place, Baykusheva set out to test this recipe for the first time. In an article published today in Nano letters, the research team reports that these tests went exactly as expected, producing the first unique signature of the topological surface.
“This material is very different from any other material that we have tried,” said Ghimire, principal investigator at PULSE. “It’s really exciting to be able to find a new class of material that has a very different optical response than anything else.”
Over the past twelve years, Ghimire has performed a series of experiments with PULSE director David Reis, showing that HHG can be produced in ways that were previously considered unlikely, if not impossible: by projecting laser light into a crystal, a frozen argon gas or one atomically thin semiconductor Equipment. Another study described how to use HHG to generate attosecond laser pulses, which can be used to observe and control the movement of electrons, by shining a laser through ordinary glass.
But quantum materials had steadfastly resisted being analyzed in this way, and the divided personalities of topological insulators presented a particular problem.
“When we project laser light on a TI, the surface and the interior produce harmonics. The challenge is to separate them, ”said Ghimire.
The team’s key finding, he explained, was that circularly polarized light interacts with the surface and the interior in profoundly different ways, stimulating the generation of high harmonics from the surface and also gives it a distinctive signature. These interactions, in turn, are shaped by two fundamental differences between the surface and the interior: the degree of polarization of their electronic spins – oriented clockwise or counterclockwise, for example – and the types of symmetry found in their networks. atomic. .
Since the group published their recipe for achieving HHG in IT earlier this year, two other research groups in Germany and China have reported the creation of HHG in a topological insulator, Ghimire said. But both of these experiments were with linearly polarized light, so they didn’t see the enhanced signal generated by circularly polarized light. This signal, he said, is a unique feature of topological surface states.
Because intense laser light can turn electrons in a material into a soup of electrons – a plasma – the team had to find a way to shift the wavelength of their high-powered titanium sapphire laser. so that it is 10 times longer, and therefore 10 times less energetic. They also used very short laser pulses to minimize damage to the sample, which had the added benefit of allowing them to capture the behavior of the material with the equivalent of a shutter speed of millionths of a billionth of a. second.
“The advantage of using HHG is that it is an ultra-fast probe,” Ghimire said. “Now that we have identified this new approach to probing topological surface states, we can use it to study other interesting materials, including topological states induced by powerful lasers or by chemical means.”
Researchers from the Stanford Institute for Materials and Energy Sciences (SIMES) at SLAC, University of Michigan, Ann Arbor, and Pohang University of Science and Technology (POSTECH) in Korea contributed to this work. Main funding came from the DOE Office of Science, including an Early Career Research Program grant to Shambhu Ghimire, and the Swiss National Science Foundation.
SLAC is a dynamic multi-program lab that explores how the universe works at the largest, smallest and fastest scales and invents powerful tools used by scientists around the world. With research spanning particle physics, astrophysics and cosmology, materials, chemistry, biological and energy sciences, and scientific computing, we help solve real-world problems and advance the interests of science. nation.
SLAC is operated by Stanford University for the United States Department of Energy Science Office. The Office of Science is the largest supporter of basic research in the physical sciences in the United States and works to address some of the most pressing challenges of our time.