Latest research findings on LK99 and the existence of extraterrestrial super islands

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Hello, everybody. How are you?
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I'm Sun Yue from the Physics Department at Southeast University.
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I'm here today to report on the group we're working on.
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The latest research on LK99
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Recently, the topic of the Outer Space Islands has been very hot.
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We all see a lot of reports.
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We are happy to be working on Super Island.
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We have a lot of people interested in our work.
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But we also see a lot of media or self-media.
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They overreport or distort some of the results.
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So I'd like to use this video to introduce you to the world of the Internet.
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Our Results
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Our work has been written and posted on our account.
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So you may soon see our original.
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First, let's talk about the most important thing.
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We have not confirmed or found any extraterrestrial islands.
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But we're below 110K.
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Successful observation of zero resistance
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This could be a very important piece of evidence of its existence.
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So, we'll just take the paper out right here.
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Read the full article.
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We are the Supersular Research Team of the School of Physics at Southeastern University.
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We're working with three students.
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The first time I saw you, I was so happy.
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And the one that I did with Professor Xiao.
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So let's look at the graph of our article.
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We're looking to talk to you about our article.
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OK, the first one is our X-ray projection.
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And we have the first two on the left.
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So this is the result of XRD of our two predecessors.
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And then on the right is what we synthesized.
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We made several batches of samples.
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Here are the x-ray results from four samples.
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And then we took the X-ray results and the Korean team and they reported that
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X-rays of this material were compared.
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We can see the X-rays of our samples and report
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X-rays are a very good match.
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And even we are a little bit more pure than their samples.
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Because we can basically see that over here.
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The top of the Willow Child is so small
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We're a little bit more pure than their samples.
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Okay, here's the most important thing.
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So this is our zero-point impedance.
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So we can look at this measurement.
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It's been going from this 300K to the cold temperature.
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And then we have a current of one milliamp.
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And then this is what the sample we measured looked like.
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Because this sample is a little bit crispy.
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It's hard to make it into one.
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The shape of the rule.
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It's also to save time.
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We just kind of shifted it to an irregular sample.
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This resistance measurement is performed using the four-shade method.
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We can see that under a millimeter current
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So we have this resistance.
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It actually acts a little bit like a semiconductor at high temperatures.
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And then as the temperature decreases, it decreases.
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And the most important thing is that we're at this 110K.
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And we see that its resistance is basically zero.
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Why do we say it's going to go to 0.
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Because you can see the quality of the resistor on this side of us.
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So it's going to be about 10 to the minus 5 to the minus 6th power of ohms.
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And then we have a current of one milliamp.
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So that means that at this point, we have a voltage of 10.
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-8 or -9 times.
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What's wrong?
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So this is the PBMS of our measuring instrument.
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The line is up.
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So we think we're looking at 0 resistors.
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This is us.
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We had one last time, about 250K.
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And then there's this weird resistance drop.
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We don't know why.
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Maybe this motor is doing something that's not very clean.
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We're not sure yet.
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And when we add the magnetic field to this
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Superconducting transitions in the sample were measured
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We see that its superconducting transition is relatively stable under the magnetic field.
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So basically, maybe TC0 is a little bit different.
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But the superconducting shift in its magnetic field is also a
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A little weird.
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We can see that in the low-end
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So let's say that 0 Tesla 135 is the same as 0 Tesla 135.
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We're going to increase with this magnetic field.
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Its superconducting transition
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So we're going to have a little bit of a shift in the temperature, and we're going to have a little bit of a shift in the temperature.
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But by the time the 9 and the 7 came out,
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I don't know why it seems to come back.
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We don't know why.
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What's the last thing you want to say?
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We actually saw it on the afternoon of August 1.
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Behavior similar to the drop in resistance of a superconductor transform
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But then we have less than zero resistance.
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It has a very small quality.
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So we then intensified the sampling.
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We actually tested six samples.
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But we only observed zero resistance in one sample.
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In other samples it mostly produces the behavior of the semiconductor
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And we also have zero resistance samples on this piece of the spectrum.
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Measurements of the Messner effect
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So, the first thing we're going to do is we're going to measure
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But we didn't see this completely antimagnetic on the magnetic measurements.
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So we guess that in our sample
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So this zero resistor is a superconductor.
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Its superconducting component should be still relatively low.
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So this is our main work.
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And thank you very much to the three students who worked on our star cluster.
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We also want to reiterate our most important points.
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We have succeeded in observing zero resistance below 110K under this LK99 material.
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But this is not evidence of room temperature superconductivity.
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We have yet to explore and measure whether it has a superconductive room temperature.
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Our team will continue to work on this.
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I hope to report better results.
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Thank you.

Sun Yuyue from the Physics Department of Southeast University reports on the team's latest research on LK99. They have observed zero resistance below 110K, which could be crucial evidence for the existence of super island electronics. The research paper will be published soon.

This video in Chinese was translated to English, 中文 on August 02, 2023, using Targum.video AI translation service.

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