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Physicists image electrons flowing like water

Physicists at the Weizmann Institute of Science in Israel have imaged electrons flowing viscously through a nanodevice, just like water flowing through a pipe. Long predicted but only now visualized for the first time, this curious new behavior for electrons has important implications for future electronic devices.

From roaring waves to swirling whirlpools, the flow of a liquid can be extremely rich. Such varied phenomena are the result of the many collisions that occur between the particles that make up a liquid, and is described by the physics of hydrodynamics. However, despite being negatively charged, electrons usually flow through a conductor like a gas in a randomized fashion essentially without repelling each other. This is because most conductors are made from materials that are highly disordered, and the electrons flowing inside collide more frequently with the many impurities and imperfections. To make electrons flow like a liquid, one needs a more advanced conductor, for example, graphene -- a one atom-thick sheet of carbon, which can be made exceptionally clean. "Theories suggest that liquid electrons can perform cool feats that their ballistic or diffusive counterparts cannot. But to get a clear-cut proof that electrons can indeed form a liquid state, we wanted to directly visualize their flow," said Prof. Shahal Ilani, head of the Weizmann team in the Department of Condensed Matter Physics.

Visualizing hydrodynamic electron flow in a material like graphene isn't straightforward, though, as it requires a special technique that is simultaneously powerful enough to peer inside a material, yet gentle enough to avoid disrupting the electron flow. The Weizmann team created such a technique, which they published recently in Nature Nanotechnology. They produced a nanoscale detector built from a carbon nanotube transistor that can image the properties of flowing electrons with unprecedented sensitivity. "Our technique is at least 1000 times more sensitive than alternative methods, which enables us to image phenomena that previously could only be studied indirectly," said Dr. Joseph Sulpizio, from Weizmann.

In their new paper, now published in Nature, the Weizmann researchers applied their novel imaging technique to state-of-the-art graphene devices produced by the group of Prof. Andre Geim at the University of Manchester. These devices are shaped into channels that guide the flowing electrons, similar to the way a pipe guides the flow of water. And just as water flows through a pipe, the electrons in the graphene were observed flowing faster in the center of the channels and slower at the walls, which is the hallmark of hydrodynamic flow.

This work demonstrates that the patterns of a conventional fluid can be mimicked by electrons. This may prove beneficial for creating new types of electronic devices, including low-power devices in which the hydrodynamic flow lowers the electrical resistance. "Computing centers and consumer electronics are devouring an ever-increasing amount of energy, and in light of climate change, it's imperative to find ways to make electrons flow with less resistance," said Dr. Lior Ella from Weizmann.

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Materials provided by Weizmann Institute of Science. Note: Content may be edited for style and length.

Journal References:

  1. Joseph A. Sulpizio, Lior Ella, Asaf Rozen, John Birkbeck, David J. Perello, Debarghya Dutta, Moshe Ben-Shalom, Takashi Taniguchi, Kenji Watanabe, Tobias Holder, Raquel Queiroz, Alessandro Principi, Ady Stern, Thomas Scaffidi, Andre K. Geim, Shahal Ilani. Visualizing Poiseuille flow of hydrodynamic electrons. Nature, 2019; 576 (7785): 75 DOI: 10.1038/s41586-019-1788-9
  2. Lior Ella, Asaf Rozen, John Birkbeck, Moshe Ben-Shalom, David Perello, Johanna Zultak, Takashi Taniguchi, Kenji Watanabe, Andre K. Geim, Shahal Ilani, Joseph A. Sulpizio. Simultaneous voltage and current density imaging of flowing electrons in two dimensions. Nature Nanotechnology, 2019; 14 (5): 480 DOI: 10.1038/s41565-019-0398-x
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(Source: sciencedaily.com; December 11, 2019; http://bit.ly/2YETD9k)
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