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  • One of the most exciting materials developments of the last few years is totally twisted.

  • A closer look at graphene has revealed even more of its magical glory,

  • and taken it a step furtherusing SQUIDs.

  • And no, probably not the squids you're thinking of, I'll explain later.

  • We're talking, of course, aboutmagic angle" graphene.

  • First discovered back in 2018, it involves taking graphene, which is just a single sheet of carbon atoms,

  • and stacking two of those sheets on top of one another.

  • The twist?

  • The sheets are ever so slightly offset from each other, about 1.1 degrees.

  • And thismagic angle" gives the twisted graphene some really exciting properties.

  • The twist makes the graphene bilayer able to become either an insulator, blocking electricity flow,

  • or a superconductor, letting electricity flow with minimal loss of energy to resistance.

  • The discovery was huge news when it broke—I actually covered it a while back.

  • It started a whole new field called 'twistronics' (which is really fun to say),

  • that explores how the structure of 2D materials influences their electronic behavior.

  • And now, that same research team who twisted that "magic angle" into a graphene bilayer in the first place

  • has mapped the entire structure of "magic angle" graphene for the first time.

  • Some research has previously tried to get an up close look at "magic angle "structures like this

  • using a scanning tunneling microscope, but could only look at little chunks at a time

  • like a few hundred square nanometers at most.

  • The scanning tunneling microscope approach just takes way too long

  • it's kinda like trying to use a flashlight to count each of the seats in a really huge, dark sports arena.

  • See, in a magic angle graphene structure, there will be minute differences in how twisted it actually is

  • at any point in the structureit won't always be exactly 1.1 degrees at every single point.

  • So, here's where the squids come in.

  • This team used a technique called a “scanning nano-SQUID.”

  • SQUID stands for Superconducting Quantum Interference Device,

  • which definitely takes the cake for most science-fiction-like name with the coolest acronym.

  • It's kinda complicated, but essentially, it works like this:

  • the nano-SQUID is made of two half circles of superconducting material

  • attached to the tip of scanning electron microscope.

  • When the "magic angle" graphene structure is exposed to a small magnetic field, currents ripple across it.

  • The structure itself, including the degree of its twist, determines how those currents behave.

  • The SQUID can measure those subtle changes in the currents and in this way,

  • map the exact angle of the graphene structure at any given point...

  • down to variations of .0002 degrees.

  • That's uhhhh...pretty precise!

  • So, the team used the nano-SQUID technique to map two different twisted graphene bilayers

  • one with a smaller range of variation in its twists, and one with a larger range of variation.

  • The structure with the smaller range of variation showed more intense exotic physics properties

  • than the one with the broader range.

  • This observation is a key step to understanding how different twist structures

  • may change graphene bilayer behavior.

  • And if that weren't cool enough, the team also added another bilayer,

  • for a total of four "magic angle" layers.

  • Twists on twists!

  • This totally novel four-layer structure exhibited the same awesome versatility as just two layers

  • the ability to alternate between insulating and superconducting.

  • But this time, the researchers were able to tune those capabilities

  • by turning an electric field up or down, they could control what state the structure was in,

  • making it what we call 'highly tunable'.

  • Y'know, kinda like tuning a radio between stations,

  • but instead with "magic angle "superconducting graphene that exhibits exotic physics. Casual.

  • While twistronics is still a very new field, pretty far from being implemented in any real-world applications,

  • it's cool to fantasize about the devices that it might enable,

  • like superconductors that could function at high temperatures.

  • And lots of research is going into twisted graphene's "magic" properties,

  • and I'm pretty excited to see what comes next.

  • If you have no idea what I've been talking about for this whole video,

  • then you should check out the video we first made on this discovery when it came out.

  • If you have more materials science breakthroughs you want us to cover,

  • let us know down in the comments below, and subscribe to Seeker for all your exotic physics news.

  • As always, thank you so much for watching, and I'll see ya next time.

One of the most exciting materials developments of the last few years is totally twisted.

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"魔幻 "角度石墨烯的祕密現已完全揭開 (The Secrets of ‘Magic’ Angle Graphene Are Now Fully Revealed)

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    Summer 發佈於 2021 年 01 月 14 日
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