Podcasts about fermions

I read from fermata to ferocious.     Alcohol occurs naturally and animals these days consume it on occasion so the "drunk ape hypothesis" makes sense! https://en.wikipedia.org/wiki/Drunken_monkey_hypothesis https://www.technologynetworks.com/applied-sciences/news/drunken-monkey-hypothesis-sheds-light-on-our-taste-for-booze-360256     Fermions "include all quarks and leptons and all composite particles made of an odd number of these, such as all baryons and many atoms and nuclei." https://en.wikipedia.org/wiki/Fermion     Ferns are sometimes used for for remediating contaminated soil. https://en.wikipedia.org/wiki/Fern     So as far as I can tell, ancient people thought that fern seeds were invisible (in truth they're spores and too tiny for the human eye to see) and that started a whole thing through the ages of people thinking that the fern seed would make you invisible.  https://susanalbert.com/ferns-how-to-become-invisible-or-not/ https://britishfairies.wordpress.com/2018/02/18/fern-seed-and-invisibility/ https://www.blueridgebotanic.com/blog/ferns     The word of the episode is "fern bar".     Use my special link https://zen.ai/thedictionary to save 30% off your first month of any Zencastr paid plan.    Create your podcast today! #madeonzencastr     Theme music from Tom Maslowski https://zestysol.com/     Merchandising! https://www.teepublic.com/user/spejampar     "The Dictionary - Letter A" on YouTube   "The Dictionary - Letter B" on YouTube   "The Dictionary - Letter C" on YouTube   "The Dictionary - Letter D" on YouTube   "The Dictionary - Letter E" on YouTube   "The Dictionary - Letter F" on YouTube     Featured in a Top 10 Dictionary Podcasts list! https://blog.feedspot.com/dictionary_podcasts/     Backwards Talking on YouTube: https://www.youtube.com/playlist?list=PLmIujMwEDbgZUexyR90jaTEEVmAYcCzuq     https://linktr.ee/spejampar dictionarypod@gmail.com https://www.facebook.com/thedictionarypod/ https://www.threads.net/@dictionarypod https://twitter.com/dictionarypod https://www.instagram.com/dictionarypod/ https://www.patreon.com/spejampar https://www.tiktok.com/@spejampar 917-727-5757

EPISODE 100! In this milestone episode, Patrick and Ciprian are thrilled to welcome back Richard Campbell for a fascinating discussion that dives deep into the world of quantum advancements and scientific exploration. Together, they explore the mysterious Majorana Fermion, the allure of Cold Fusion, the lessons from refuted papers, and the solutions and innovations that have reshaped the industry. Join us as we celebrate 100 episodes of thought-provoking insights and look ahead to the future of quantum technology! Richard Campbell wrote his first line of code in 1977. His career has spanned the computing industry both on the hardware and software sides, development and operations. He was a co-founder of Strangeloop Networks, acquired by Radware in 2013, and was on the board of directors of Telerik that was acquired by Progress Software in 2014. Today he is a consultant and advisor to several successful technology firms and is the founder and chairman of Humanitarian Toolbox (www.htbox.org), a public charity that builds open-source software for disaster relief. Richard is the host of two podcasts: .NET Rocks! (www.dotnetrocks.com) the Internet Audio Talkshow for .NET developers and RunAs Radio (www.runasradio.com), a weekly show for IT Professionals. He also produces the DevIntersection (www.devintersection.com) series of conferences.

Garrett Lisi is a theoretical physicist known for his work on the "Exceptionally Simple Theory of Everything," which proposes that the E8 Lie group can describe the fundamental forces and particles in the universe. Lisi is also an avid surfer and has gained attention for his unconventional approach to physics outside of academia. SPONSOR (THE ECONOMIST): As a listener of TOE, you can now enjoy full digital access to The Economist. Get a 20% off discount by visiting: https://www.economist.com/toe LINKED MENTIONED: •⁠ ⁠Garrett Lisi's TED talk on his theory of everything: https://www.youtube.com/watch?v=y-Gk_Ddhr0M •⁠ ⁠Garrett Lisi's website: https://li.si/ •⁠ ⁠Garrett Lisi's papers: https://li.si/Physics/CV.html •⁠ ⁠Peter Woit on TOE: https://www.youtube.com/watch?v=9z3JYb_g2Qs •⁠ ⁠Garrett Lisi's paper on triality: https://arxiv.org/pdf/2407.02497 TOE'S TOP LINKS: - Support TOE on Patreon: https://patreon.com/curtjaimungal (early access to ad-free audio episodes!) - Listen to TOE on Spotify: https://open.spotify.com/show/4gL14b92xAErofYQA7bU4e - Become a YouTube Member Here: https://www.youtube.com/channel/UCdWIQh9DGG6uhJk8eyIFl1w/join - Join TOE's Newsletter 'TOEmail' at https://www.curtjaimungal.org SPONSORS (please check them out to support TOE): - THE ECONOMIST: As a listener of TOE, you can now enjoy full digital access to The Economist. Get a 20% off discount by visiting: https://www.economist.com/toe - INDEED: Get your jobs more visibility at https://indeed.com/theories ($75 credit to book your job visibility) - HELLOFRESH: For FREE breakfast for life go to https://www.HelloFresh.com/freetheoriesofeverything - PLANET WILD: Want to restore the planet's ecosystems and see your impact in monthly videos? The first 150 people to join Planet Wild will get the first month for free at https://planetwild.com/r/theoriesofeverything/join or use my code EVERYTHING9 later. TIMESTAMPS: 00:00 - Intro 01:24 - Garrett's Ted Talk and Background 08:36 - Mystery of Spinors 10:13 - Garrett Poses a Physical Problem 12:22 - String Theorists 23:48 - Triality 26:13 - Garrett's Top Points in His Talk 28:42 - “String Theory's the Only Game in Town” 32:10 - Garrett's Presentation Begins: Unification 38:22 - Spinors vs. Fermions 45:56 - More Particles in Higher Gauge Groups 48:42 - Threefold Symmetry 54:00- Group Theory Overview 59:37 - Quaternion Group 01:04:14 - Pin Group 01:10:25 - Spin Eigenvalues 01:14:45 - C, P, and T 01:22:12 - Biquaternionic Spinors 01:25:55 - Quaternion Triality and the CPTt Group 01:34:14 - Multi-Generational Fermion States 01:37:20 - Fermions in Exceptional Unification 01:42:12 - Exceptional Magic Square 01:44:22 - Outro / Support TOE Other Links: - Twitter: https://twitter.com/TOEwithCurt - Discord Invite: https://discord.com/invite/kBcnfNVwqs - iTunes: https://podcasts.apple.com/ca/podcast/better-left-unsaid-with-curt-jaimungal/id1521758802 - Subreddit r/TheoriesOfEverything: https://reddit.com/r/theoriesofeverything #science #sciencepodcast #physics #theoreticalphysics Learn more about your ad choices. Visit megaphone.fm/adchoices

Today's episode features Jason Padgett, a physicist and artist whose path to a mathematical conception of reality began with a violent attack in his early 30s. We discuss this transformation after brain injury. How with zero mathematical background he found himself reinventing calculus. We discuss his attempts to bring himself into line with peers who had a very different formal training. Then we discuss his particular theoretical projects in physics. In particular he has developed a theory of informational constants of nature, which he calls holographic quantum information theory in an effort to unify quantum mechanics and Einsteinian relativity. To make sense of that we unpack concepts like cubits, hidden information, and quantum vector spin models. We close with a discussion of probabilistic reality and the nature of material reality versus mathematical models. Sign up for our Patreon and get episodes early + join our weekly Patron Chat https://bit.ly/3lcAasB AND rock some Demystify Gear to spread the word! https://demystifysci.myspreadshop.com/ Jason's latest AI conversation about his model: https://chatgpt.com/share/a32bc04b-b811-408f-9ea1-6489c23c55eb Jason's artwork: https://jason-padgett.pixels.com/ 00:00 Go! 00:05:59 Ideas in different languages 00:10:58 Before the attack 00:14:25 The attack 00:27:00 My mind starts changing overnight 00:35:52 Reinventing calculus with no formal training 00:49:05 Savantism 00:57:56 Informational constant of nature 01:02:33 Cubits? 01:06:56 Hidden information between Planck times 01:14:03 Reconciling probabilistic reality 01:21:32 Everything is light, QS vectors 01:26:15 Quantum Vector Spin models Einstein's time dilation 01:37:37 Material reality v. math 01:59:58 Hawking radiation 02:08:48 Translation through free education 02:17:36 Using AI to translate your math into words 02:25:51 Eternal recurrence #sciencepodcast #longformpodcast #PhysicsInjuryRecovery, #MathematicalSavant, #QuantumTheory, #BrainInjurySurvivor, #MathematicalGenius, #ArtisticTransformation, #NeuroscienceDiscovery, #SavantSyndrome, #BrainInjuryRecovery, #MathematicalInsights, #QuantumPhysics, #GeniusAfterInjury, #PhysicistStory, #NeuroscienceResearch, #MathematicalIntuition, #QuantumMechanics, #BrainDamageRecovery, #SavantAbilities, #MathematicalDiscovery, #QuantumMind. Check our short-films channel, @DemystifySci: https://www.youtube.com/c/DemystifyingScience AND our material science investigations of atomics, @MaterialAtomics https://www.youtube.com/@MaterialAtomics Join our mailing list https://bit.ly/3v3kz2S PODCAST INFO: Anastasia completed her PhD studying bioelectricity at Columbia University. When not talking to brilliant people or making movies, she spends her time painting, reading, and guiding backcountry excursions. Shilo also did his PhD at Columbia studying the elastic properties of molecular water. When he's not in the film studio, he's exploring sound in music. They are both freelance professors at various universities. - Blog: http://DemystifySci.com/blog - RSS: https://anchor.fm/s/2be66934/podcast/rss - Donate: https://bit.ly/3wkPqaD - Swag: https://bit.ly/2PXdC2y SOCIAL: - Discord: https://discord.gg/MJzKT8CQub - Facebook: https://www.facebook.com/groups/DemystifySci - Instagram: https://www.instagram.com/DemystifySci/ - Twitter: https://twitter.com/DemystifySci MUSIC: -Shilo Delay: https://g.co/kgs/oty671

In this episode of Passion Struck, host John R. Miles interviews Amy Leigh Mercree, a holistic health expert and author of "Aura Alchemy." Amy discusses the concept of auras as biologically generated electromagnetic fields and explains their significance in holistic health and spiritual practices. She shares personal experiences of seeing auras and provides practical tips for developing the ability to perceive auras. Amy emphasizes the importance of mastering one's aura to take control of one's life and enhance intuition. The episode delves into various practices for cleansing electromagnetic fields, including shamanic oral work and medical intuitive healing techniques. Order a copy of my book, "Passion Struck: Twelve Powerful Principles to Unlock Your Purpose and Ignite Your Most Intentional Life," today! This book, a 2024 must-read chosen by the Next Big Idea Club, has garnered multiple accolades, including the Business Minds Best Book Award, the Eric Hoffer Award, and the Non-Fiction Book Awards Gold Medal. Don't miss out on the opportunity to transform your life with these powerful principles!Full show notes and resources can be found here: https://passionstruck.com/amy-leigh-mercree-master-your-aura-master-life/In this episode, you will learn:What auras are and their significance in holistic health and spiritual practicesHow to start developing the ability to see aurasPractical examples of using understanding of auras to make better decisions or navigate challengesVarious practices for cleansing electromagnetic fields, including shamanic oral work, medical intuitive healing, and specific energy clearing techniquesThe concept of neutrino aura manifestation and how it can be used to influence physical reality through intentionAll things Amy Leigh Mercree: https://amyleighmercree.com/SponsorsBrought to you by Clariton, fast and powerful relief is just a quick trip away. Ask for Claritin-D at your local pharmacy counter. You don't even need a prescription! Go to “CLARITIN DOT COM” right now for a discount so you can Live Claritin Clear.--► For information about advertisers and promo codes, go to:https://passionstruck.com/deals/Catch More of Passion StruckCan't miss my episode withDr. Jenny Taitz on How You Live Bigger for True FulfillmentListen to my interview withJason Redman on How You Confront the Dragon in Your MindWatch my episode with Gabby Bernstein on finding profound freedom and inner peaceListen to my solo episode on Find Your Matter Meter: Create Belief in Why You MatterSee my episode with Bronnie Ware on Harnessing Joy in the Little ThingsLike this show? Please leave us a review here-- even one sentence helps! Consider including your Twitter or Instagram handle so we can thank you personally!

Welcome to another episode of Quirkcast, where we take a look at the dichotomy of two types of fundamental particles: bosons vs fermions. Today, we'll explore how these particles types play a crucial role in shaping the stability of matter, influencing the dynamics of chemistry, and the complexities of nuclear physics. It's not just theoretical—these categories have tangible effects on the world around us. As we delve into the subject, we'll uncover interesting quirks of bosons vs fermions, such as their ability to switch roles and create intriguing materials like superfluids and superconductors. It's a journey into the unexpected side of physics, where small changes in particle behavior lead to some surprising outcomes. Additionally, we'll touch on some cutting-edge theories proposing that bosons and fermions could be different expressions of the same underlying concept. These are fascinating concepts that might reshape our understanding of the quantum universe. So join us on Quirkcast as we explore the practical and thought-provoking aspects of bosons and fermions in the world of particle physics. Discord: ⁠⁠⁠⁠⁠⁠⁠⁠https://discord.gg/GEvBX4N2

This episode dives into the fascinating world of Fermions and Bosons, the fundamental building blocks of everything. We explore their unique personalities, from the solitary Fermions to the social Bosons who love to clump together. Discover how Fermions create the matter around us, and how Bosons govern the forces that hold it all together. We'll even explore the mind-bending world of Bose-Einstein condensates, where particles become superfluid and defy the laws of physics as we know them! Join us on a journey to decode the mysterious recipe of our universe!

In this episode, I talk about how quantum spin and how bosons and fermions differ from their wave functions and their rotational properties, and how this results in the existence of matter.

Stephen Wolfram answers general questions from his viewers about science and technology as part of an unscripted livestream series, also available on YouTube here: https://wolfr.am/youtube-sw-qa Questions include: There was a study where they saw helices in superconducting materials. What properties make helices common in nature, from DNA to whirlpools to EMR? - Can you tell us why electrons in the atoms of the Sun do not burn due to the heat? - How does superconducting magnet levitation work? - Fermions and bosons... Are hadrons the intersection between them? - Is there much use for superconductivity in space where the temp is already close to 0 K? - Especially in places without an insulating atmosphere around, superconductors should be a serious option. Much easier to dissipate heat! - Aren't there Japanese maglev trains on which there are cooling systems? - I believe these flux tubes also show up in gravity, leading to dark matter and dark energy effects. - What do you think has the most potential for changing the energy crisis, and what field do you think we need to focus on to get there? - As long as the nuke plant isn't dual-use for producing plutonium, then I think it's safe. - Thermovoltaic cells are a new thing that seem interesting for the efficiency of steam turbines.

In this episode, I explain the basic information of bosons and fermions and relate it to statistical mechanics.

Bernard DerridaPhysique statistiqueCollège de FranceAnnée 2022-2023Conférencier invitéLeonid Pastur – Entanglement Entropy of Disordered FermionsSérie de quatre conférences en anglais.Entanglement is a fundamental intrinsic property of quantum systems manifesting strong non-local and non-classical correlations in them. In its simplest form entanglement causes two quantum particles to share a common pure state in which the particle do not have pure states of their own. Various aspects of entanglement proved to be of great interest and importance for a number of branches of modern physics and adjacent sciences both fundamental and applied, cosmology and quantum information science between them. Being a quite multifaceted phenomenon, entanglement requires a variety of numerical characteristics (quantifiers, entanglement measures, entanglement witnesses) to be analyzed and measured. The problem is quite non-trivial already in the simplest case of bipartite systems, where one party (central) is that we are interested in and the second ("environment") is connected with the central party in a certain way and affects its properties, destroying, quite often, quantum correlations in it.Most of obtained results of the field concern deterministic (ideal) systems where no imperfections (impurities) are present either in the central system nor it the environment. On the other hand, modern physics deals with a wide variety of problems where the randomness ("nonideality") of the quantum system under consideration is indispensable. It suffices to recall the transport properties of quantum condensed systems, e.g. their electrical and thermal conductivity, where physically consistent properties arise only when scattering by impurities is taken into account, manifesting a rather subtle interplay between quantum coherence and disorder. One more situation where randomness is widely used is that with the lack of knowledge on the systems, which makes it worthwhile to consider their typical and/or generic properties.In the view of the above, the course focuses on two problems motivated by quantum optics, quantum informatics and quantum statistical mechanics. The first is the time evolution of the entanglement characteristics (quantifiers) of two qubits embedded into a random environment. The environment is modelled by random matrices of large size. Several dynamic regimes are discussed, including the disappearance and subsequent appearance of entanglement at finite times (in contrast to the standard regime of exponential decay at long times).The second problem is on the spatial asymptotic behaviour of the entanglement entropy of large blocks of the macroscopic (extended) system of free disordered fermions. It is shown that, unlike the translation invariant case, where the entanglement entropy is known to obey either the so-called area law or the logarithmic enhanced area law, in the disordered case, where the Anderson localization is present, the logarithmic enhanced area law is absent.Leonid Pastur est invité par l'Assemblée du Collège de France, sur proposition du Pr Bernard Derrida.

In this episode, the team discusses primuses, aboideaux, stewings, and fermions. They also ponder the implications of these terms on society, and discuss whether they're suitable terms to use in scientific discourse. Andrew Ng joins the discussion to provide his perspective on the terminology.

This is my interview with Nicetu Tibau Vidal, a DPhil student at Oxford University. We discuss his research, which includes demonstrating that fermions conform to Einstein's principle of locality. We also discuss his ongoing research project of formalizing constructor theory. Video Version, Part One - https://www.youtube.com/watch?v=5IKbA9AzPv0&t=16s Video Version, Part Two - https://www.youtube.com/watch?v=fJiiteXFG7g&t=2s --- Support this podcast: https://anchor.fm/logan-chipkin/support

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine GeorgesPhysique de la matière condenséeAnnée 2018-2019Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine GeorgesPhysique de la matière condenséeAnnée 2018-2019Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine Georges Physique de la matière condensée Année 2018-2019 Fermions en interaction : Introduction à la théorie du champ moyen dynamique

Antoine GeorgesPhysique de la matière condenséeAnnée 2018-2019Fermions en interaction : Introduction à la théorie du champ moyen dynamique