Running Chemical Reactions In Liquid Metal Makes Atomically Thin Materials

Running Chemical Reactions In Liquid Metal Makes Atomically Thin Materials - Electronics Featured Graphene
Enlarge/ Droplets of a gallium/indium alloy. Collin Ladd, NC State University

The discovery of graphene—a one-atom-thick sheet of covalently bonded carbon atoms—inspired the community to generate a variety of 2D materials. , MoS2, the silicon equivalent of graphene, and more all have distinct properties based on the chemical bonding among their component atoms. And it’s possible to leverage these properties to create commonplace devices on an unprecedentedly small scale, like a three-atom-thick LED.

Obviously, the more materials we have to work with, the better we can fine-tune one of these devices to our needs. But producing 2D materials is a challenge, as there are a limited number of substances that lend themselves to the chemically bonded layers we know how to work with. Now, an Australian-US team (writing in Science) has devised a way to make a broad class of atomically thin metal oxides, including 2D versions of materials already in use by the industry. Their secret? A room temperature liquid metal.

Selective

This is one of those cases where a series of simple observations led to a major development. In many cases, pure metals will react with oxygen in the air to form a thin oxide layer on their surface. This, it turns out, is true for one of the metals that is liquid near room temperature: gallium, which melts at 30 degrees Celsius. Leave some liquid gallium exposed to the air, and it’ll form a thin film of gallium oxide on its surface.

The key observation came when the researchers looked into a gallium alloy, galinstan, composed of gallium, indium, and tin. Even though the two other metals could comprise as much as 40 percent of the alloy, the surface oxide ended up being pure gallium oxide. The liquid metal turns out to be key here. In a solid chunk of metal, oxygen will only be able to react with whatever metals are on the surface, whether they’re the most energetically favorable or not. But a liquid allows all its components to cycle up to the surface, producing a chemically uniform film. That film then prevents oxygen from reacting with anything underneath it.

The full story is available below.

Sourcears technica

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