Stanford Professor Gary Nolan explains that metamaterials appear to be normal matter that contains properties we don’t fully appreciate yet

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Gary Nolan, Ph.D. in genetics from Stanford. He is a professor of microbiology and immunology at Baxter Laboratory.

Frank Stalter. (2017). The Science Behind the Pentagon UFO Study. UFO Partisan.

Dr. Gary Nolan is a Professor of Microbiology & Immunology at Stanford University as well as being a member of the advisory board for the To the Starts Academy,  a private sector follow up to the 2007-2012 Pentagon UFO study involving many of the same people including Luis Elizondo, who headed up the Pentagon study and acts as Director of Global Security & Special Programs for TTS.

Over the last several days, Dr. Nolan has been nice enough to answer several questions regarding what we might look for going forward regarding the scientific research taking place as part of that follow up.

The following material, while presented in a standard interview format, was compiled from a series of private messages and open conversations at my UFO Facebook group. Obviously, more questions will come up as time goes on and this article will be updated accordingly.

Q: Can you give us a little background on the nature of the recovered materials mentioned in the New York Times story?

One way to think about metamaterials is that is, basically, quantum engineering—working with “normal” matter in a way that takes advantage of properties we don’t fully appreciate yet.

DR. NOLAN: These are not your grandma’s alloys. If these materials truly exist– they are going to be found to be metamaterials. Though I call them metamaterials– it’s really for lack of a better term. They are probably even more engineered and subtle than that. The science of metamaterials is only a few decades old, but there is a whole ecosystem of new journals growing up around their unexpected and wondrous properties. One way to think about metamaterials is that is, basically, quantum engineering—working with “normal” matter in a way that takes advantage of properties we don’t fully appreciate yet. We draw the physical universe with only 80 elements. I would guess—just hypothesis– that “they” (an advanced civilization) that we might infer can accomplish some of the feats observed by the pilots understand the subtleties of isotopes and design with all 253 stable isotopes. The metamaterials “they” could design would be more subtle and likely encompass a greater understanding of reality and physics than we know now.

Remember, isotopes of a given element have the same electronic configuration, so they form covalent bonds similar to their sister isotopes (though with subtle differences in bond strengths). However, their nuclei have different spins for instance with, at times, unpaired neutrons. The various nuclear configurations gives rise to multiple fascinating opportunities in designing metamaterials. Want to know what your children should be studying in school? Physics, metallurgy, and advanced composite materials.

People interested in understanding the reality of what’s going on with these metamaterials (so-called alloys) need to understand this: There are 253 isotopes that do not undergo radioactive decay in any reasonable time frame.  Some elements, such aluminum, have only 1 stable isotope. Titanium and nickel each have 5 stable isotopes. Tin (Sn) has eight! There are natural ratios of these isotopes that are largely governed by stellar decay processes, centrifugal forces (solar and other) during planetary formation, and proximity to gamma and other radiation sources. The ratios vary only slightly (maximum a couple percent) across a solar system. Significant variations in isotope ratios imply either engineering of the ratios for a purpose, or that the materials came from somewhere that does not “play by our rules”.

My suspicion is that a foundational difference is the nuclear spin of these isotopes (and other quantum features associated with different arrangements of the nuclear shells in the different isotopes) that affects how they behave/contribute in these composites or metamaterial structures.

We use a lot of these isotopes in my lab at Stanford —purely as tags in biology experiments. We don’t come close to using them in the way I am suggesting above.

Q: Do any of these metamaterials have shape memory properties?

DR. NOLAN: They might, but I have not been following that area. My main interest is in quantum microscopes and how they might manage properties of electromagnetism and entanglement. I am particularly interested, and on record at several conferences, stating that entanglement might offer a whole new way to measure events at a distance for biological and clinical purposes.

Q: Is there any sense on what the function of these metamaterials is? Are they part of a vehicle structure or do they have an avionics or propulsion (for lack of better words) application?

DR. NOLAN: If I knew the answer to that I’d be filing patents right now.

Q: Jacques Vallée has been discussing these materials lately. Have you been working with him at all?

DR. NOLAN: Yes, Jacques and I have worked together on many projects. Including his recent discussions on the isotope ratios. Jacques previously worked with Peter Sturrock (Emeritus Professor of Astrophysics here at Stanford) a couple of decades ago on composition of materials from UAP.

Q: Would it be fair to say a lot of the “portal” talk surrounding TTS and other efforts is more akin to stable wormholes/ Einstein-Rosen bridges?    

DR. NOLAN: While I don’t officially speak for TTS, as I am on “just” the advisory board…. My personal opinion is… Yes.

Q: Are you familiar with Aron Wall’s work?  He’s apparently working on some sort of portal/traversable wormhole.

DR. NOLAN: I don’t know Aron’s work, but there are two physicists on the TTS team who might. One of them is a specialist in space time metrics (engineering of space/time).

UPDATE JUNE 12

Hal Puthoff addressed the SSE/IRVA conference a few nights back and went into some detail about UFOs and metamaterials. The full transcript of his talk is here. Here’s what he had to say about the materials:

“So let me give you an example of, how this stuff helps people who are chasing these really difficult problems. I’m choosing one here: metamaterials for aerospace use. I’d love to talk about really fancy materials, but they’re classified. However, there’s a lot of materials that have been picked up or provided even in the public domain. I’m going to give an example because it shows exactly what the structure is for how to deal with this. This is an open source sample. It was sent anonymously to talk show host Art Bell. The fellow claimed to be in the military. He said that this sample was picked up in a crash retrieval, and so he sent it by email. So what does that mean? Chain of custody non-existent. Provenance questionable. Could be a hoax. Could be some slag off of some foundry floor or whatever. However, it was an unusual sample, so we decided to take a look at it.”

It was a multilayered bismuth and magnesium sample. Bismuth layers are less than a human hair. Magnesium samples about ten-times the size of a human hair. Supposedly picked up in the crash retrieval of an Advanced Aerospace Vehicle. It looks like it’s been in a crash. The white lines are the bismuth; the darker areas are the magnesium separations. So the question was what about this material, so naturally we looked in all the national labs, we talked to metallurgists, we combed the entire structure of published papers. Nowhere could we find any evidence that anybody ever made one of these.

Secondly, some attempts were made to try to reproduce this material, but they couldn’t get the bismuth and magnesium layers to bond.

Thirdly, when we talked to people in the materials field who should know, they said we don’t know why anybody would want to make anything like this. It’s not obvious that it has any function.

Want to know what your children should be studying in school? Physics, metallurgy, and advanced composite materials.

Well, years later, decades later actually, finally our own science moves along. We move into an area called metamaterials, and it turns out exactly this combination of materials at exactly those dimensions turn out to be an excellent microscopic waveguide for very high frequency electromagnetic radiation terahertz frequencies. So, the wavelength is 60 microns, which is a pretty small size. But it turns out because of the metamaterial aspect of this material, those bismuth layers that act as waveguides can be one twentieth the size of the wavelength, and usually when you make a waveguide it’s gotta be about the size of the wavelength. So, in fact this turned out to be a material that would propagate sub-wavelength waveguide effects. Why somebody wants to do that we still don’t know the answer to that.

“But anyway, it’s amazing we’ve gone through this and this is the kind of structure we go through a lot. You get a material sample with unusual characteristics to be evaluated, the method of manufacture is difficult to assess or reproduce, the purpose of the function is not readily apparent – as with our sample here, and then as our own technical knowledge moves forward we finally see a possible purpose or function comes to light. That sequence is repeated over and over in this particular area.”


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