Podcasts about mathematical institute

fWotD Episode 2964: Emmy Noether Welcome to Featured Wiki of the Day, your daily dose of knowledge from Wikipedia's finest articles.The featured article for Monday, 16 June 2025, is Emmy Noether.Amalie Emmy Noether (US: , UK: ; German: [ˈnøːtɐ]; 23 March 1882 – 14 April 1935) was a German mathematician who made many important contributions to abstract algebra. She also proved Noether's first and second theorems, which are fundamental in mathematical physics. Noether was described by Pavel Alexandrov, Albert Einstein, Jean Dieudonné, Hermann Weyl and Norbert Wiener as the most important woman in the history of mathematics. As one of the leading mathematicians of her time, she developed theories of rings, fields, and algebras. In physics, Noether's theorem explains the connection between symmetry and conservation laws.Noether was born to a Jewish family in the Franconian town of Erlangen; her father was the mathematician Max Noether. She originally planned to teach French and English after passing the required examinations, but instead studied mathematics at the University of Erlangen–Nuremberg, where her father lectured. After completing her doctorate in 1907 under the supervision of Paul Gordan, she worked at the Mathematical Institute of Erlangen without pay for seven years. At the time, women were largely excluded from academic positions. In 1915, she was invited by David Hilbert and Felix Klein to join the mathematics department at the University of Göttingen, a world-renowned center of mathematical research. The philosophical faculty objected, however, and she spent four years lecturing under Hilbert's name. Her habilitation was approved in 1919, allowing her to obtain the rank of Privatdozent.Noether remained a leading member of the Göttingen mathematics department until 1933; her students were sometimes called the "Noether Boys". In 1924, Dutch mathematician B. L. van der Waerden joined her circle and soon became the leading expositor of Noether's ideas; her work was the foundation for the second volume of his influential 1931 textbook, Moderne Algebra. By the time of her plenary address at the 1932 International Congress of Mathematicians in Zürich, her algebraic acumen was recognized around the world. The following year, Germany's Nazi government dismissed Jews from university positions, and Noether moved to the United States to take up a position at Bryn Mawr College in Pennsylvania. There, she taught graduate and post-doctoral women including Marie Johanna Weiss and Olga Taussky-Todd. At the same time, she lectured and performed research at the Institute for Advanced Study in Princeton, New Jersey.Noether's mathematical work has been divided into three "epochs". In the first (1908–1919), she made contributions to the theories of algebraic invariants and number fields. Her work on differential invariants in the calculus of variations, Noether's theorem, has been called "one of the most important mathematical theorems ever proved in guiding the development of modern physics". In the second epoch (1920–1926), she began work that "changed the face of [abstract] algebra". In her classic 1921 paper Idealtheorie in Ringbereichen (Theory of Ideals in Ring Domains), Noether developed the theory of ideals in commutative rings into a tool with wide-ranging applications. She made elegant use of the ascending chain condition, and objects satisfying it are named Noetherian in her honor. In the third epoch (1927–1935), she published works on noncommutative algebras and hypercomplex numbers and united the representation theory of groups with the theory of modules and ideals. In addition to her own publications, Noether was generous with her ideas and is credited with several lines of research published by other mathematicians, even in fields far removed from her main work, such as algebraic topology.This recording reflects the Wikipedia text as of 01:12 UTC on Monday, 16 June 2025.For the full current version of the article, see Emmy Noether on Wikipedia.This podcast uses content from Wikipedia under the Creative Commons Attribution-ShareAlike License.Visit our archives at wikioftheday.com and subscribe to stay updated on new episodes.Follow us on Mastodon at @wikioftheday@masto.ai.Also check out Curmudgeon's Corner, a current events podcast.Until next time, I'm standard Geraint.

Quantum physics is a bedrock of modern physics, and of modern life. And yet, it is profoundly mysterious. In the episode of Kainaati Chai, we chat with Dr. Muhammad Hamza Waseem. Apart from his research, he is devoted to teaching the principles of quantum physics in an accessible manner. Dr. Muhammad Hamza Waseem is a Research Scientist at Quantinuum. His current research focuses on quantum foundations, quantum science education, applied category theory, mathematical linguistics, and quantum natural language processing. Hamza completed his DPhil in Physics at the University of Oxford, which was funded by the Rhodes Trust and Magdalen College. His thesis explored applied process-relational philosophy and employed string diagrams to study interpretations of quantum theory, constructor theory, wave-based logic, quantum computing and natural language processing.During his undergraduate studies in electrical engineering at UET Lahore, Hamza helped establish Pakistan's first laboratory for single-photon quantum physics. He also co-authored the book Quantum Mechanics in the Single-Photon Laboratory, published by the Institute of Physics (IOP), UK, now in its second edition.Passionate about public engagement with science, Hamza has played a key role in organising the Lahore Science Mela, the largest annual science festival in Pakistan. He co-founded Spectra, an online magazine dedicated to training popular science writers in Pakistan. For his contributions to science popularisation, Hamza has been awarded the 2021 Diana Award, a High Commendation at the 2021 SEPnet Public Engagement Awards, and the 2024 MPLS Public Engagement with Research Impact Award.At Oxford, Hamza teaches mathematics and physics at Magdalen College, the Mathematical Institute, and the Department of Computer Science. He has also served as a Lecturer in Physics at Magdalen College. Additionally, he is a Senior Research Fellow at the Global Centre for Advanced Studies in Dublin.#physics #universe #quantumphysics #scienceexplained #blackholetheory #scienceexplained #astronomy #nasa #astronomyadventures #einstein #relativitytheory #oxford #quantummechanics Subscribe to our NEW Kids English Channel here: https://www.youtube.com/@UCdIRtt8-Og1q99bkK5XBhoQ Subscribe to our Kids Channel here: https://www.youtube.com/@KainaatKidsSubscribe to our English Channel here: https://www.youtube.com/@kainaatastronomyinenglish   For more information about Kainaat Studios:https://www.kainaatstudios.com/Sign up to our mailing list to get unseen content and hear special announcements! https://www.kainaatstudios.com/newsletterFollow us for more:Facebook https://www.facebook.com/kainaatstudiosTwitter https://twitter.com/KainaatStudiosInstagram https://www.instagram.com/kainaatstudios/TikTok https://www.tiktok.com/@kainaatstudiosLinkedIn https://www.linkedin.com/company/kainaatSalman Hameed has a PhD in astronomy and is Charles Taylor Chair and Professor of Integrated Science & Humanities at Hampshire College, and a member of the Five College Astronomy Department (FCAD) in Massachusetts, USA. He is also the CEO of the non-profit Kainaat Studios Credits: Written & Hosted by: Salman HameedGuest: Dr. Muhammad Hamza WaseemEdited by: Shehryar ShaikhMusic: Zohaib KaziSubtitles by: DigiCircleImages: NASA, Wikipedia, ESAThumbnail image: Corinne Reid for Quanta Magazine

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******Support the channel****** Patreon: https://www.patreon.com/thedissenter PayPal: paypal.me/thedissenter PayPal Subscription 3 Dollars: https://tinyurl.com/ybn6bg9l PayPal Subscription 5 Dollars: https://tinyurl.com/ycmr9gpz PayPal Subscription 10 Dollars: https://tinyurl.com/y9r3fc9m PayPal Subscription 20 Dollars: https://tinyurl.com/y95uvkao   ******Follow me on****** Website: https://www.thedissenter.net/ The Dissenter Goodreads list: https://shorturl.at/7BMoB Facebook: https://www.facebook.com/thedissenteryt/ Twitter: https://x.com/TheDissenterYT   This show is sponsored by Enlites, Learning & Development done differently. Check the website here: http://enlites.com/   Dr. J. Doyne Farmer is the Director of the Complexity Economics programme at the Institute for New Economic Thinking at the Oxford Martin School, Baillie Gifford Professor in the Mathematical Institute at the University of Oxford and an External Professor at the Santa Fe Institute. His current research is in economics, including agent-based modeling, financial instability and technological progress. His past research includes complex systems, dynamical systems theory, time series analysis and theoretical biology. He was an Oppenheimer Fellow and the founder of the Complex Systems Group at Los Alamos National Laboratory. He is the author of Making Sense of Chaos: A Better Economics for a Better World.   In this episode, we focus on Making Sense of Chaos. We talk about the economy as a complex system, business cycles, simulating the economy, and the housing bubble crises of the 2000s. We discuss the differences between standard economics and complexity economics. We talk about how we can understand inequality, market inefficiencies and crashes, and whether we can prevent financial crises. Finally, we discuss climate economics, how we can solve climate change, and whether we can tackle inequality. -- A HUGE THANK YOU TO MY PATRONS/SUPPORTERS: PER HELGE LARSEN, JERRY MULLER, BERNARDO SEIXAS, ADAM KESSEL, MATTHEW WHITINGBIRD, ARNAUD WOLFF, TIM HOLLOSY, HENRIK AHLENIUS, FILIP FORS CONNOLLY, DAN DEMETRIOU, ROBERT WINDHAGER, RUI INACIO, ZOOP, MARCO NEVES, COLIN HOLBROOK, PHIL KAVANAGH, SAMUEL ANDREEFF, FRANCIS FORDE, TIAGO NUNES, FERGAL CUSSEN, HAL HERZOG, NUNO MACHADO, JONATHAN LEIBRANT, JOÃO LINHARES, STANTON T, SAMUEL CORREA, ERIK HAINES, MARK SMITH, JOÃO EIRA, TOM HUMMEL, SARDUS FRANCE, DAVID SLOAN WILSON, YACILA DEZA-ARAUJO, ROMAIN ROCH, DIEGO LONDOÑO CORREA, YANICK PUNTER, CHARLOTTE BLEASE, NICOLE BARBARO, ADAM HUNT, PAWEL OSTASZEWSKI, NELLEKE BAK, GUY MADISON, GARY G HELLMANN, SAIMA AFZAL, ADRIAN JAEGGI, PAULO TOLENTINO, JOÃO BARBOSA, JULIAN PRICE, EDWARD HALL, HEDIN BRØNNER, DOUGLAS FRY, FRANCA BORTOLOTTI, GABRIEL PONS CORTÈS, URSULA LITZCKE, SCOTT, ZACHARY FISH, TIM DUFFY, SUNNY SMITH, JON WISMAN, WILLIAM BUCKNER, PAUL-GEORGE ARNAUD, LUKE GLOWACKI, GEORGIOS THEOPHANOUS, CHRIS WILLIAMSON, PETER WOLOSZYN, DAVID WILLIAMS, DIOGO COSTA, ALEX CHAU, AMAURI MARTÍNEZ, CORALIE CHEVALLIER, BANGALORE ATHEISTS, LARRY D. LEE JR., OLD HERRINGBONE, MICHAEL BAILEY, DAN SPERBER, ROBERT GRESSIS, IGOR N, JEFF MCMAHAN, JAKE ZUEHL, BARNABAS RADICS, MARK CAMPBELL, TOMAS DAUBNER, LUKE NISSEN, KIMBERLY JOHNSON, JESSICA NOWICKI, LINDA BRANDIN, NIKLAS CARLSSON, GEORGE CHORIATIS, VALENTIN STEINMANN, PER KRAULIS, ALEXANDER HUBBARD, BR, MASOUD ALIMOHAMMADI, JONAS HERTNER, URSULA GOODENOUGH, DAVID PINSOF, SEAN NELSON, MIKE LAVIGNE, JOS KNECHT, ERIK ENGMAN, LUCY, MANVIR SINGH, PETRA WEIMANN, CAROLA FEEST, STARRY, MAURO JÚNIOR, 航 豊川, TONY BARRETT, BENJAMIN GELBART, NIKOLAI VISHNEVSKY, AND STEVEN GANGESTAD! A SPECIAL THANKS TO MY PRODUCERS, YZAR WEHBE, JIM FRANK, ŁUKASZ STAFINIAK, TOM VANEGDOM, BERNARD HUGUENEY, CURTIS DIXON, BENEDIKT MUELLER, THOMAS TRUMBLE, KATHRINE AND PATRICK TOBIN, JONCARLO MONTENEGRO, AL NICK ORTIZ, NICK GOLDEN, AND CHRISTINE GLASS! AND TO MY EXECUTIVE PRODUCERS, MATTHEW LAVENDER, SERGIU CODREANU, BOGDAN KANIVETS, ROSEY, AND GREGORY HASTINGS!

J. Doyne Farmer is director of the Complexity Economics program at the Institute for New Economic Thinking at the Oxford Martin School, Baillie Gifford Professor in the Mathematical Institute at the University of Oxford, and an external professor at the Santa Fe Institute. He is a renowned physicist and complex systems scientist with a career spanning more than four decades. As a pioneer in chaos theory and complexity science, he has made significant contributions to understanding dynamic systems and their applications in various fields, including economics and financial markets.In this conversation with Dave Young, the Global Leader of the BCG Henderson Institute's Center for Climate & Sustainability, Doyne discusses his journey from astrophysics to pioneering work in chaos theory and complex systems. He explains how modern computational power and big data are revolutionizing economic modeling, sharing insights from his team's accurate prediction of COVID-19's economic impact in the U.K. Farmer argues for a shift from traditional macroeconomic models to more dynamic, data-driven approaches that can capture the intricacies of our complex economic systems.This podcast uses the following third-party services for analysis: Chartable - https://chartable.com/privacy

Álvaro Cartea is Professor of  Mathematical Finance in the Mathematical Institute, University of Oxford, and director of the Oxford-Man Institute of Quantitative Finance. He is a founding member and deputy chairman of the Commodities & Energy Markets Association (CEMA). Before coming to Oxford, Álvaro was Reader in Mathematical Finance at University College London. He was also previously JP Morgan Lecturer in Financial Mathematics, Exeter College, University of Oxford. Álvaro obtained his doctorate from the University of Oxford in 2003. This podcast covers the evolution of AI trading strategies, the unintented consequences of AI market makers, and the regulatory aspects of AI in finance.

Eric Weinstein is a mathematician, economist, science policy expert and a frequent public speaker on a variety of subjects within the sciences. Dr Weinstein was formerly a co-founder of the Sloan Sponsored Science and Engineering Workforce Project at Harvard and the National Bureau of Economic Research, a co-founder and principal of the Natron Group in Manhattan as well as a visiting research fellow at Oxford University in the Mathematical Institute. Since completing a PhD dissertation in the Mathematics Department at Harvard in 1992, he has held research positions in Mathematics, Physics, and Economics departments (at MIT, Hebrew University, and Harvard respectively). He delivered the Special Simonyi Lectures at Oxford University in 2013 putting forth a theory he termed “Geometric Unity” to unify the twin geometries (Riemannian and Ehresmannian) thought to ground the two most fundamental physical theories (General Relativity and the so-called Standard Model of particle theory, respectively). He has been asked to address the National Academy of Sciences on five occasions on the future of scientific and academic research at elite institutions within the United States.

J. Doyne Farmer is the Director of the Complexity Economics programme at the Institute for New Economic Thinking at the Oxford Martin School, a Professor at the Mathematical Institute of Oxford University, and an External Professor at the Santa Fe Institute. In this episode, we explore Doyne's latest book, “Making Sense of Chaos.” We focus on the relationship between chaos and scaling theory, and more specifically, how chaos can be factored into scaling theory. By the end of this conversation, you will learn why it might be easier to predict the long distant future than predicting tomorrow, how Moore's Law conflicts with other scaling laws that underpin technological progress, how agent-based modeling can help all scientists and policymakers, how to dominate the world with your theories (...), and even how to trick casinos. I hope you enjoy the conversation. Find me on X at @⁠⁠ProfSchrepel⁠⁠. Also, be sure to subscribe to the Scaling Theory podcast; it helps its growth. ***

J. Doyne Farmer is Director of the Complexity Economics programme at the Institute for New Economic Thinking at the Oxford Martin School, Baillie Gifford Professor in the Mathematical Institute at the University of Oxford and an External Professor at the Santa Fe Institute.In this episode, Doyne discusses his journey from chaos theory to complexity economics. He shares his experience developing agent-based models for the economy and talks about the importance of multidisciplinary work and applying complexity science principles to economics and climate change.   Resources: Purchase ‘Making Sense of Chaos: A Better Economics for a Better World' here   Connect: Simplifying Complexity on Twitter Sean Brady on Twitter Sean Brady on LinkedIn Brady Heywood website This show is produced in collaboration with Wavelength Creative. Visit wavelengthcreative.com for more information.

Emilio Carrizosa is Full Professor of Statistics and Operations Research in the University of Seville, Spain. His research interests include: Industrial and Applied Mathematics; Data Science (Explainable and Fair Machine Learning, Supervised Classification and Regression), Mathematical Optimization and Operations Research (Mixed Integer Nonlinear Programming, Global Optimization, Vector Optimization). He is President of math-in, the Spanish Network of Industrial Mathematics (2021-), President of PET MSO-ED, the Spanish Platform for Technologies of Modelling, Simulation and Optimization in a Digital Environment (2023-), and has served as Director of IMUS, the Mathematical Institute of the University of Seville, President of SEIO, the Spanish Statistics and OR Society, and Editor-in-Chief of TOP, the Spanish OR journal. He has (Scopus: 18.10.23) 147 publications with 1,848 citations (819 in the period 2019-2023), yielding an h-index: 25. He has papers in top journals in the area Operations Research and Management Science: Operations Research (2), Mathematical Programming (6), Management Science (1), Mathematics of Operations Research (4), Omega (4), European Journal of Operational Research (25), Computers & OR (21). Due to his interdisciplinary research, he has also published indisciplines beyond OR: Statistics and Probability (Biostatistics, ADAC, CSDA, J Multivariate Analysis, J of Applied Probability), Energy (Applied Energy, Solar Energy, International Journal of Energy Research), Chemical Engineering (Computers & Chemical Engineering, Industrial & Engineering Chemistry Research), Hydrology (J of Hydrology). The Spanish Research Agency has acknowledged 5 research periods (5 sexenios de investigación): 1990-95, 1996-01, 2002-07, 2008-13, 2014-19. He has supervised 14 PhD Theses (plus 4 ongoing in the University of Seville), three of them have been awarded various national and international prizes: Vanesa Guerrero (Premio Extraordinario de Doctorado Universidad de Sevilla, Research Award Vicent Caselles RSME-FBBVA, Research Award Ramiro Melendreras SEIO 2018), M. Asunción Jiménez-Cordero (Premio Extraordinario de Doctorado Universidad de Sevilla), Cristina Molero-Rı́o (Classification Society Distinguished Dissertation Award 2022). For his research activity, he has received awards such as the Excellence FAMA Award 2020 (branch: Sciences) in the University of Seville, the Award Academia Sevillana de Ciencias for young researchers (1998) and the Doc2toral Award in the PhD in Mathematics in the University of Seville (1993). He is involved in Transfer of Knowledge activities. He has been leading researcher in industrial projects and contracts in applications of OR to different sectors: Energy (Repsol, Abengoa, TSK Flagsol), Health (UDX), Logistics (Azur Global Business SL), Information Technologies (Junta de Andalucı́a), and also participating in contracts on Environment (Junta de Andalucı́a), Smart cities (IMESAPI), Logistics (Portel). Since 2022 he is Scientific Advisor of the OR-IA company OGA. The Spanish Research Agency has acknowledged 1 transfer of knowledge period (1 sexenio de transferencia): -2013. He has an intense activity of outreach, participating in debates and interviews in tv, radio and newspapers on industrial mathematics and teaching mathematics.

Episode 52 of ‘All About Art': Curating Frieze Sculpture with Fatos Üstek In this episode, I sat down with Fatos Üstek. It was announced earlier this year that Fatos would be curating the 2023 Frieze Sculpture Park, a major annual public art exhibition that places monumental works by leading artists throughout London's The Regent's Park during Frieze Art Fair, one of the biggest art fairs in the world. Listen in to hear me ask Fatos about her background in Mathematics and how it influences her curatorial approach. We of course talk about Frieze Sculpture 2023, as well as other projects such as FRANK Fair Artists Pay, an initiative she launched this year with two artists. We delve into her ideas for new structures for arts organizations and what Fatos envisions for the future of the arts sector. I also ask her about the experiences she's accrued being on the jury and in advisory roles for the Turner Prize, The Fourth Plinth, Jarman Film Award, and New Contemporaries (to name just a few!). Thank you Fatos for coming on the podcast and having such an amazing conversation with me. Fatos's website: www.fatosustek.com/ You can follow Fatos on Instagram here: www.instagram.com/fatosustek/ Further links to topics we discuss during the episode: FRANK Fair Artists Pay: ⁠frankfairartistpay.com/about⁠ Cascading Principles Exhibition at the Mathematical Institute at Oxford University: www.fatosustek.com/cascading-principles The Art Institution of Tomorrow by Fatos Üstek (to be published in 2024): www.lundhumphries.com/products/the-art-institution-of-tomorrow Frieze Sculpture: www.frieze.com/fairs/friezesculpture You can support All About Art on Patreon here: https://www.patreon.com/allaboutart ABOUT THE HOST: I am an Austrian-American art historian, curator, and writer. I obtained my BA in History of Art at University College London and my MA in Arts Administration and Cultural Policy at Goldsmiths, University of London. My specializations include contemporary art, specifically feminism and artificial intelligence in artistic practice, as well as museum policies and arts engagement. Here are links to my social media, feel free to reach out: Instagram @alexandrasteinacker Twitter @alex_steinacker and LinkedIn at Alexandra Steinacker-Clark COVER ART: Lisa Schrofner a.k.a Liser www.liser-art.com Assistant Producer: Leanne Dennis This episode is supported and sponsored by Synergy https://synergy.tech/the-clubhouse/

Dr Ali El Kaafarani, founder and CEO of PQShield, explains how quantum computers will one day crack today's encryption to expose our data, discusses the race to create cryptography that can fend off quantum attacks, and why “strengthening the startup position in the UK should be a top priority for the UK government to excel at quantum computing”. Oxford-headquartered PQShield is a cybersecurity spinout founded by researchers to develop post-quantum cryptography tools. The company, which has raised nearly $27m in funding, has contributed to developing the first cryptography standards designed to block cyberattacks powered by quantum machines. Its software and hardware products are already being adopted by companies such as Bosch and Collins Aerospace. Kaafarani is also a researcher at the Mathematical Institute at the University of Oxford and has previous experience at HP Labs.  

Doyne Farmer is Director of the Complexity Economics programme at the Institute for New Economic Thinking at the Oxford Martin School, Baillie Gifford Professor in the Mathematical Institute at the University of Oxford, and an External Professor at the Santa Fe Institute. His current research is in economics, including agent-based modeling, financial instability and technological progress. He was a founder of Prediction Company, a quantitative automated trading firm that was sold to UBS in 2006. His past research includes complex systems, dynamical systems theory, time series analysis and theoretical biology.

As machine learning and AI mature and adapt to the humans that created them, it's important we think carefully about not only what is creativity, but what is uniquely human about creativity.Marcus du Sautoy is the Charles Simonyi Professor for the Public Understanding of Science at the Oxford University, a chair he holds jointly at the Department of Continuing Education and the Mathematical Institute, as well as a Professor of Mathematics and a Fellow of New College.His many books dive deep into the world of machines and creativity, and include “Thinking Better: the Art of the Shortcut,” and “The Creativity Code.”He sits down for this stimulating conversation with Greg covering generative adversarial networks, Ada Lovelace and machine generated music, crediting the code or the coder, and what the future holds for art & AI.Episode Quotes:Two kinds of algorithm we need at work:You need a sort of two algorithms at work. One is the creator coming up with babbling new ideas. And then the second is like, oh, the judgments. No, that's no good. That doesn't work because of this. And you know in my own research, I often pair up with another mathematician and we play these two roles, the creator and the discriminator.So, I think some of the most interesting algorithms that we're seeing that are beginning to look like they're making something genuinely new are capturing that element that we take advantage of as humans.Machines still need humansMachines might be able to do things at speed or at depth that a human could never achieve. But ultimately, we should credit the creativity with the human that told the machine what to do.The Emotional Resonance to MathematicsAda Lovelace went to see, you know, Charles Babbage making a machine do math, but, no, it wasn't doing math. It was doing arithmetic and that's the kind of bread and butter. But mathematics is something much more creative. And, we use this word creativity as a kind of protective shield about, against why a computer can't do what we're doing, because we're making lots of leaps into the unknown, lots of choices, things we choose proofs, which kind of move us emotionally because they got “Aha” moment in them.Show Links:Resources:The ContinuatorThe Turing TestForget Turing, the Lovelace Test Has a Better Shot at Spotting AIAda LovelaceAlphaGoGPT3 algorithmAnish KapoorLibrary of BabelDeep Dream GeneratorGuest Profile:Faculty Profile at University of OxfordProfessional Profile at the Royal SocietyMarcus du Sautoy WebsiteMarcus du Sautoy on TwitterMarcus du Sautoy on FacebookMarcus du Sautoy on YoutubeMarcus Sautoy on TEDTalkHis Work:The Creativity Code: Art and Innovation in the Age of AIFinding Moonshine BlogThinking Better: The Art of the Shortcut in Math and LifeI is a Strange LoopHow to Count to Infinity (Little Ways to Live a Big Life Book 1)The Great Unknown: Seven Journeys to the Frontiers of ScienceWhat We Cannot Know: From consciousness to the cosmos, the cutting edge of science explainedThe Music of the Primes: Searching to Solve the Greatest Mystery in Mathematics The Number Mysteries: A Mathematical Odyssey through Everyday Life (MacSci)Symmetry: A Mathematical Journey Finding Moonshine: A Mathematician's Journey Through Symmetry

For years we've been hearing that the clean energy transition is going to be expensive. But the recent working paper, Empirically grounded technology forecasts and the energy transition, suggests that the high estimates of the expense to transition to renewable energy have been inflated, and that it may in fact be cheaper to transition to renewables than to stay on fossil fuels, regardless of the costs of the changing climate. Using probabilistic cost forecasting methods, the authors of the paper project that because of the exponentially decreasing cost curve of renewables like wind and solar, fossil fuels will become nearly obsolete in just 25 years.Climate Now spoke with co-author of the paper, Dr. Doyne Farmer, to better understand their model and what that might mean for policy and investments. Dr. Farmer is the Director of the Complexity Economics program at the Institute for New Economic Thinking at the Oxford Martin School, Baillie Gifford Professor in the Mathematical Institute at the University of Oxford and an External Professor at the Santa Fe Institute.

Until very recently, the prevailing wisdom cautioned that transitioning to a clean energy economy would be extremely expensive, and therefore only possible if undertaken slowly. New research upends that thinking—when it comes to going green, the faster we go, the cheaper it will be. University of Oxford professors Eric Beinhocker and Doyne Farmer talk with Nick about a new strategy for clean technology that could transform the climate fight.  Eric Beinhocker is a Professor of Public Policy Practice at the Blavatnik School of Government and the Executive Director of the Institute for New Economic Thinking at the University of Oxford's Martin School. He is also a Supernumerary Fellow in Economics at Oriel College, and External Professor at the Santa Fe Institute.  Twitter: @EricBeinhocker Doyne Farmer is Director of the Complexity Economics program at the Institute for New Economic Thinking. He is Baillie Gifford Professor in the Mathematical Institute at the University of Oxford and an External Professor at the Santa Fe Institute.  Website: http://www.doynefarmer.com/ Going big and fast on renewables could save trillions in energy costs: https://www.washingtonpost.com/business/energy/going-big-and-fast-on-renewables-would-save-trillions-in-energy-costs/ A new strategy for climate: make the clean stuff cheap - https://democracyjournal.org/arguments/a-new-strategy-for-climate-make-the-clean-stuff-cheap/  Website: http://pitchforkeconomics.com/ Twitter: @PitchforkEcon Instagram: @pitchforkeconomics Nick's twitter: @NickHanauer

Students and their families face a consequential choice in whether to pursue a degree, and in what area. For those considering mathematics programs, the choice may be particularly fraught: A gulf separates the exploratory and experimental mathematics done by professionals from the computational training of most secondary schools, and this can obscure the meanings of program options. Meanwhile, cultural anxieties and stereotypes can dissuade students who would flourish in mathematical careers. This despite mathematical professionals being among the most satisfied and well-compensated in their careers. In Why Study Mathematics? (2020), Vicky Neale provides a compact guide to this juncture, which i expect students and their families and teachers will find hugely valuable. As part of the London Publishing Partnership's "Why Study" series, her book in Part I explores in detail the substance and varieties of math degrees, how students can shape them to their needs and interests, and what those who complete them go on to do after. For Part II, Neale gives the reader a deeper view into a selection of subfields and the work their practitioners do, including the technologically vital study of data compression and the (for now) more humanistic study of abstract networks known as Ramsey theory. Dr. Neale has exceptional experience and skill as a mentor that comes through as she addresses questions that, in my experience, often aren't: Are mathematics degrees mostly for mathematically adept students? Once in a program, whom should i get to know? Where are all the job postings for "mathematician"? It was a treat to hear her expound further on the book, and i would suggest that anyone at the beginning of their professional life, with interest, aptitude, or just curiosity about mathematics, seek out this resource (or recommend it to their mentors and guidance offices!) as they weigh their options. Suggested companion works: Maths Careers (UK) Numberphile YouTube channel Plus magazine Chalkdust magazine Vicky Neale is the Whitehead Lecturer at the Mathematical Institute, University of Oxford, and a Supernumerary Fellow at Balliol College. She teaches pure mathematics to undergraduates, and combines this with work on public engagement with mathematics: she gives public lectures, leads workshops with school students, and has appeared on numerous BBC radio and television programmes. One of her current interests is in using knitting and crochet to explore mathematical ideas. She is the author of Closing the Gap: The Quest to Understand Prime Numbers (Oxford University Press, 2017)—listen to her interview with Jim Stein about that book here. Cory Brunson is an Assistant Professor at the Laboratory for Systems Medicine at the University of Florida. His research focuses on geometric and topological approaches to the analysis of medical and healthcare data. Learn more about your ad choices. Visit megaphone.fm/adchoices Support our show by becoming a premium member! https://newbooksnetwork.supportingcast.fm/new-books-network

Students and their families face a consequential choice in whether to pursue a degree, and in what area. For those considering mathematics programs, the choice may be particularly fraught: A gulf separates the exploratory and experimental mathematics done by professionals from the computational training of most secondary schools, and this can obscure the meanings of program options. Meanwhile, cultural anxieties and stereotypes can dissuade students who would flourish in mathematical careers. This despite mathematical professionals being among the most satisfied and well-compensated in their careers. In Why Study Mathematics? (2020), Vicky Neale provides a compact guide to this juncture, which i expect students and their families and teachers will find hugely valuable. As part of the London Publishing Partnership's "Why Study" series, her book in Part I explores in detail the substance and varieties of math degrees, how students can shape them to their needs and interests, and what those who complete them go on to do after. For Part II, Neale gives the reader a deeper view into a selection of subfields and the work their practitioners do, including the technologically vital study of data compression and the (for now) more humanistic study of abstract networks known as Ramsey theory. Dr. Neale has exceptional experience and skill as a mentor that comes through as she addresses questions that, in my experience, often aren't: Are mathematics degrees mostly for mathematically adept students? Once in a program, whom should i get to know? Where are all the job postings for "mathematician"? It was a treat to hear her expound further on the book, and i would suggest that anyone at the beginning of their professional life, with interest, aptitude, or just curiosity about mathematics, seek out this resource (or recommend it to their mentors and guidance offices!) as they weigh their options. Suggested companion works: Maths Careers (UK) Numberphile YouTube channel Plus magazine Chalkdust magazine Vicky Neale is the Whitehead Lecturer at the Mathematical Institute, University of Oxford, and a Supernumerary Fellow at Balliol College. She teaches pure mathematics to undergraduates, and combines this with work on public engagement with mathematics: she gives public lectures, leads workshops with school students, and has appeared on numerous BBC radio and television programmes. One of her current interests is in using knitting and crochet to explore mathematical ideas. She is the author of Closing the Gap: The Quest to Understand Prime Numbers (Oxford University Press, 2017)—listen to her interview with Jim Stein about that book here. Cory Brunson is an Assistant Professor at the Laboratory for Systems Medicine at the University of Florida. His research focuses on geometric and topological approaches to the analysis of medical and healthcare data. Learn more about your ad choices. Visit megaphone.fm/adchoices Support our show by becoming a premium member! https://newbooksnetwork.supportingcast.fm/science-technology-and-society

Students and their families face a consequential choice in whether to pursue a degree, and in what area. For those considering mathematics programs, the choice may be particularly fraught: A gulf separates the exploratory and experimental mathematics done by professionals from the computational training of most secondary schools, and this can obscure the meanings of program options. Meanwhile, cultural anxieties and stereotypes can dissuade students who would flourish in mathematical careers. This despite mathematical professionals being among the most satisfied and well-compensated in their careers. In Why Study Mathematics? (2020), Vicky Neale provides a compact guide to this juncture, which i expect students and their families and teachers will find hugely valuable. As part of the London Publishing Partnership's "Why Study" series, her book in Part I explores in detail the substance and varieties of math degrees, how students can shape them to their needs and interests, and what those who complete them go on to do after. For Part II, Neale gives the reader a deeper view into a selection of subfields and the work their practitioners do, including the technologically vital study of data compression and the (for now) more humanistic study of abstract networks known as Ramsey theory. Dr. Neale has exceptional experience and skill as a mentor that comes through as she addresses questions that, in my experience, often aren't: Are mathematics degrees mostly for mathematically adept students? Once in a program, whom should i get to know? Where are all the job postings for "mathematician"? It was a treat to hear her expound further on the book, and i would suggest that anyone at the beginning of their professional life, with interest, aptitude, or just curiosity about mathematics, seek out this resource (or recommend it to their mentors and guidance offices!) as they weigh their options. Suggested companion works: Maths Careers (UK) Numberphile YouTube channel Plus magazine Chalkdust magazine Vicky Neale is the Whitehead Lecturer at the Mathematical Institute, University of Oxford, and a Supernumerary Fellow at Balliol College. She teaches pure mathematics to undergraduates, and combines this with work on public engagement with mathematics: she gives public lectures, leads workshops with school students, and has appeared on numerous BBC radio and television programmes. One of her current interests is in using knitting and crochet to explore mathematical ideas. She is the author of Closing the Gap: The Quest to Understand Prime Numbers (Oxford University Press, 2017)—listen to her interview with Jim Stein about that book here. Cory Brunson is an Assistant Professor at the Laboratory for Systems Medicine at the University of Florida. His research focuses on geometric and topological approaches to the analysis of medical and healthcare data. Learn more about your ad choices. Visit megaphone.fm/adchoices Support our show by becoming a premium member! https://newbooksnetwork.supportingcast.fm/education

Students and their families face a consequential choice in whether to pursue a degree, and in what area. For those considering mathematics programs, the choice may be particularly fraught: A gulf separates the exploratory and experimental mathematics done by professionals from the computational training of most secondary schools, and this can obscure the meanings of program options. Meanwhile, cultural anxieties and stereotypes can dissuade students who would flourish in mathematical careers. This despite mathematical professionals being among the most satisfied and well-compensated in their careers. In Why Study Mathematics? (2020), Vicky Neale provides a compact guide to this juncture, which i expect students and their families and teachers will find hugely valuable. As part of the London Publishing Partnership's "Why Study" series, her book in Part I explores in detail the substance and varieties of math degrees, how students can shape them to their needs and interests, and what those who complete them go on to do after. For Part II, Neale gives the reader a deeper view into a selection of subfields and the work their practitioners do, including the technologically vital study of data compression and the (for now) more humanistic study of abstract networks known as Ramsey theory. Dr. Neale has exceptional experience and skill as a mentor that comes through as she addresses questions that, in my experience, often aren't: Are mathematics degrees mostly for mathematically adept students? Once in a program, whom should i get to know? Where are all the job postings for "mathematician"? It was a treat to hear her expound further on the book, and i would suggest that anyone at the beginning of their professional life, with interest, aptitude, or just curiosity about mathematics, seek out this resource (or recommend it to their mentors and guidance offices!) as they weigh their options. Suggested companion works: Maths Careers (UK) Numberphile YouTube channel Plus magazine Chalkdust magazine Vicky Neale is the Whitehead Lecturer at the Mathematical Institute, University of Oxford, and a Supernumerary Fellow at Balliol College. She teaches pure mathematics to undergraduates, and combines this with work on public engagement with mathematics: she gives public lectures, leads workshops with school students, and has appeared on numerous BBC radio and television programmes. One of her current interests is in using knitting and crochet to explore mathematical ideas. She is the author of Closing the Gap: The Quest to Understand Prime Numbers (Oxford University Press, 2017)—listen to her interview with Jim Stein about that book here. Cory Brunson is an Assistant Professor at the Laboratory for Systems Medicine at the University of Florida. His research focuses on geometric and topological approaches to the analysis of medical and healthcare data. Learn more about your ad choices. Visit megaphone.fm/adchoices Support our show by becoming a premium member! https://newbooksnetwork.supportingcast.fm/science

Students and their families face a consequential choice in whether to pursue a degree, and in what area. For those considering mathematics programs, the choice may be particularly fraught: A gulf separates the exploratory and experimental mathematics done by professionals from the computational training of most secondary schools, and this can obscure the meanings of program options. Meanwhile, cultural anxieties and stereotypes can dissuade students who would flourish in mathematical careers. This despite mathematical professionals being among the most satisfied and well-compensated in their careers. In Why Study Mathematics? (2020), Vicky Neale provides a compact guide to this juncture, which i expect students and their families and teachers will find hugely valuable. As part of the London Publishing Partnership's "Why Study" series, her book in Part I explores in detail the substance and varieties of math degrees, how students can shape them to their needs and interests, and what those who complete them go on to do after. For Part II, Neale gives the reader a deeper view into a selection of subfields and the work their practitioners do, including the technologically vital study of data compression and the (for now) more humanistic study of abstract networks known as Ramsey theory. Dr. Neale has exceptional experience and skill as a mentor that comes through as she addresses questions that, in my experience, often aren't: Are mathematics degrees mostly for mathematically adept students? Once in a program, whom should i get to know? Where are all the job postings for "mathematician"? It was a treat to hear her expound further on the book, and i would suggest that anyone at the beginning of their professional life, with interest, aptitude, or just curiosity about mathematics, seek out this resource (or recommend it to their mentors and guidance offices!) as they weigh their options. Suggested companion works: Maths Careers (UK) Numberphile YouTube channel Plus magazine Chalkdust magazine Vicky Neale is the Whitehead Lecturer at the Mathematical Institute, University of Oxford, and a Supernumerary Fellow at Balliol College. She teaches pure mathematics to undergraduates, and combines this with work on public engagement with mathematics: she gives public lectures, leads workshops with school students, and has appeared on numerous BBC radio and television programmes. One of her current interests is in using knitting and crochet to explore mathematical ideas. She is the author of Closing the Gap: The Quest to Understand Prime Numbers (Oxford University Press, 2017)—listen to her interview with Jim Stein about that book here. Cory Brunson is an Assistant Professor at the Laboratory for Systems Medicine at the University of Florida. His research focuses on geometric and topological approaches to the analysis of medical and healthcare data. Learn more about your ad choices. Visit megaphone.fm/adchoices Support our show by becoming a premium member! https://newbooksnetwork.supportingcast.fm/mathematics

In the last twenty years, cosmology has unexpectedly emerged as one of the most exciting and dynamic fields of modern science. From astoundingly precise measurements of the cosmic microwave background to the ongoing mysteries of dark energy and dark matter, modern cosmology is unquestionably in the midst of its Golden Age. And yet, one of the most eminent mathematical physicists of our age, Roger Penrose is convinced that there is one fundamental problem that is consistently being overlooked: why did our universe begin in such a particular state of extremely low entropy? His Conformal Cyclic Cosmology (CCC) is an attempt to directly address that question. The Cyclic Universe is based on an extensive conversation between Howard Burton and Roger Penrose, co-recipient of the 2020 Nobel Prize in Physics and Emeritus Rouse Ball Professor of Mathematics at the Mathematical Institute at the University of Oxford, and explores his motivation to come up with this theory in the first place and provides detailed insights into his groundbreaking research and Conformal Cyclic Cosmology. Howard Burton is the founder of the Ideas Roadshow, Ideas on Film and host of the Ideas Roadshow Podcast. He can be reached at howard@ideasroadshow.com. Learn more about your ad choices. Visit megaphone.fm/adchoices

In the last twenty years, cosmology has unexpectedly emerged as one of the most exciting and dynamic fields of modern science. From astoundingly precise measurements of the cosmic microwave background to the ongoing mysteries of dark energy and dark matter, modern cosmology is unquestionably in the midst of its Golden Age. And yet, one of the most eminent mathematical physicists of our age, Roger Penrose is convinced that there is one fundamental problem that is consistently being overlooked: why did our universe begin in such a particular state of extremely low entropy? His Conformal Cyclic Cosmology (CCC) is an attempt to directly address that question. The Cyclic Universe is based on an extensive conversation between Howard Burton and Roger Penrose, co-recipient of the 2020 Nobel Prize in Physics and Emeritus Rouse Ball Professor of Mathematics at the Mathematical Institute at the University of Oxford, and explores his motivation to come up with this theory in the first place and provides detailed insights into his groundbreaking research and Conformal Cyclic Cosmology. Howard Burton is the founder of the Ideas Roadshow, Ideas on Film and host of the Ideas Roadshow Podcast. He can be reached at howard@ideasroadshow.com. Learn more about your ad choices. Visit megaphone.fm/adchoices

In the last twenty years, cosmology has unexpectedly emerged as one of the most exciting and dynamic fields of modern science. From astoundingly precise measurements of the cosmic microwave background to the ongoing mysteries of dark energy and dark matter, modern cosmology is unquestionably in the midst of its Golden Age. And yet, one of the most eminent mathematical physicists of our age, Roger Penrose is convinced that there is one fundamental problem that is consistently being overlooked: why did our universe begin in such a particular state of extremely low entropy? His Conformal Cyclic Cosmology (CCC) is an attempt to directly address that question. The Cyclic Universe is based on an extensive conversation between Howard Burton and Roger Penrose, co-recipient of the 2020 Nobel Prize in Physics and Emeritus Rouse Ball Professor of Mathematics at the Mathematical Institute at the University of Oxford, and explores his motivation to come up with this theory in the first place and provides detailed insights into his groundbreaking research and Conformal Cyclic Cosmology. Howard Burton is the founder of the Ideas Roadshow, Ideas on Film and host of the Ideas Roadshow Podcast. He can be reached at howard@ideasroadshow.com. Learn more about your ad choices. Visit megaphone.fm/adchoices

In the last twenty years, cosmology has unexpectedly emerged as one of the most exciting and dynamic fields of modern science. From astoundingly precise measurements of the cosmic microwave background to the ongoing mysteries of dark energy and dark matter, modern cosmology is unquestionably in the midst of its Golden Age. And yet, one of the most eminent mathematical physicists of our age, Roger Penrose is convinced that there is one fundamental problem that is consistently being overlooked: why did our universe begin in such a particular state of extremely low entropy? His Conformal Cyclic Cosmology (CCC) is an attempt to directly address that question. The Cyclic Universe is based on an extensive conversation between Howard Burton and Roger Penrose, co-recipient of the 2020 Nobel Prize in Physics and Emeritus Rouse Ball Professor of Mathematics at the Mathematical Institute at the University of Oxford, and explores his motivation to come up with this theory in the first place and provides detailed insights into his groundbreaking research and Conformal Cyclic Cosmology. Howard Burton is the founder of the Ideas Roadshow, Ideas on Film and host of the Ideas Roadshow Podcast. He can be reached at howard@ideasroadshow.com. Learn more about your ad choices. Visit megaphone.fm/adchoices Support our show by becoming a premium member! https://newbooksnetwork.supportingcast.fm/science

In the last twenty years, cosmology has unexpectedly emerged as one of the most exciting and dynamic fields of modern science. From astoundingly precise measurements of the cosmic microwave background to the ongoing mysteries of dark energy and dark matter, modern cosmology is unquestionably in the midst of its Golden Age. And yet, one of the most eminent mathematical physicists of our age, Roger Penrose is convinced that there is one fundamental problem that is consistently being overlooked: why did our universe begin in such a particular state of extremely low entropy? His Conformal Cyclic Cosmology (CCC) is an attempt to directly address that question. The Cyclic Universe is based on an extensive conversation between Howard Burton and Roger Penrose, co-recipient of the 2020 Nobel Prize in Physics and Emeritus Rouse Ball Professor of Mathematics at the Mathematical Institute at the University of Oxford, and explores his motivation to come up with this theory in the first place and provides detailed insights into his groundbreaking research and Conformal Cyclic Cosmology. Howard Burton is the founder of the Ideas Roadshow, Ideas on Film and host of the Ideas Roadshow Podcast. He can be reached at howard@ideasroadshow.com. Learn more about your ad choices. Visit megaphone.fm/adchoices Support our show by becoming a premium member! https://newbooksnetwork.supportingcast.fm/new-books-network

In the last twenty years, cosmology has unexpectedly emerged as one of the most exciting and dynamic fields of modern science. From astoundingly precise measurements of the cosmic microwave background to the ongoing mysteries of dark energy and dark matter, modern cosmology is unquestionably in the midst of its Golden Age. And yet, one of the most eminent mathematical physicists of our age, Roger Penrose is convinced that there is one fundamental problem that is consistently being overlooked: why did our universe begin in such a particular state of extremely low entropy? His Conformal Cyclic Cosmology (CCC) is an attempt to directly address that question. The Cyclic Universe is based on an extensive conversation between Howard Burton and Roger Penrose, co-recipient of the 2020 Nobel Prize in Physics and Emeritus Rouse Ball Professor of Mathematics at the Mathematical Institute at the University of Oxford, and explores his motivation to come up with this theory in the first place and provides detailed insights into his groundbreaking research and Conformal Cyclic Cosmology. Howard Burton is the founder of the Ideas Roadshow, Ideas on Film and host of the Ideas Roadshow Podcast. He can be reached at howard@ideasroadshow.com. Learn more about your ad choices. Visit megaphone.fm/adchoices Support our show by becoming a premium member! https://newbooksnetwork.supportingcast.fm/science-technology-and-society

Cryptoreality is based on an in-depth filmed conversation between Howard Burton and Artur Ekert, Professor of Quantum Physics at the Mathematical Institute at the University of Oxford and Director of the Centre for Quantum Technologies and Lee Kong Chian Centennial Professor at the National University of Singapore. Artur Ekert is one of the pioneers of quantum cryptography. This wide-ranging conversation provides detailed insights into his research and covers many fascinating topics such as mathematical and physical intuition, a detailed history of cryptography from antiquity to the present day and how it works in practice, the development of quantum information science, the nature of reality, and more. Howard Burton is the founder of the Ideas Roadshow, Ideas on Film and host of the Ideas Roadshow Podcast. He can be reached at howard@ideasroadshow.com. Learn more about your ad choices. Visit megaphone.fm/adchoices

Cryptoreality is based on an in-depth filmed conversation between Howard Burton and Artur Ekert, Professor of Quantum Physics at the Mathematical Institute at the University of Oxford and Director of the Centre for Quantum Technologies and Lee Kong Chian Centennial Professor at the National University of Singapore. Artur Ekert is one of the pioneers of quantum cryptography. This wide-ranging conversation provides detailed insights into his research and covers many fascinating topics such as mathematical and physical intuition, a detailed history of cryptography from antiquity to the present day and how it works in practice, the development of quantum information science, the nature of reality, and more. Howard Burton is the founder of the Ideas Roadshow, Ideas on Film and host of the Ideas Roadshow Podcast. He can be reached at howard@ideasroadshow.com. Learn more about your ad choices. Visit megaphone.fm/adchoices

Cryptoreality is based on an in-depth filmed conversation between Howard Burton and Artur Ekert, Professor of Quantum Physics at the Mathematical Institute at the University of Oxford and Director of the Centre for Quantum Technologies and Lee Kong Chian Centennial Professor at the National University of Singapore. Artur Ekert is one of the pioneers of quantum cryptography. This wide-ranging conversation provides detailed insights into his research and covers many fascinating topics such as mathematical and physical intuition, a detailed history of cryptography from antiquity to the present day and how it works in practice, the development of quantum information science, the nature of reality, and more. Howard Burton is the founder of the Ideas Roadshow, Ideas on Film and host of the Ideas Roadshow Podcast. He can be reached at howard@ideasroadshow.com. Learn more about your ad choices. Visit megaphone.fm/adchoices Support our show by becoming a premium member! https://newbooksnetwork.supportingcast.fm/new-books-network

Cryptoreality is based on an in-depth filmed conversation between Howard Burton and Artur Ekert, Professor of Quantum Physics at the Mathematical Institute at the University of Oxford and Director of the Centre for Quantum Technologies and Lee Kong Chian Centennial Professor at the National University of Singapore. Artur Ekert is one of the pioneers of quantum cryptography. This wide-ranging conversation provides detailed insights into his research and covers many fascinating topics such as mathematical and physical intuition, a detailed history of cryptography from antiquity to the present day and how it works in practice, the development of quantum information science, the nature of reality, and more. Howard Burton is the founder of the Ideas Roadshow, Ideas on Film and host of the Ideas Roadshow Podcast. He can be reached at howard@ideasroadshow.com. Learn more about your ad choices. Visit megaphone.fm/adchoices Support our show by becoming a premium member! https://newbooksnetwork.supportingcast.fm/mathematics

Cryptoreality is based on an in-depth filmed conversation between Howard Burton and Artur Ekert, Professor of Quantum Physics at the Mathematical Institute at the University of Oxford and Director of the Centre for Quantum Technologies and Lee Kong Chian Centennial Professor at the National University of Singapore. Artur Ekert is one of the pioneers of quantum cryptography. This wide-ranging conversation provides detailed insights into his research and covers many fascinating topics such as mathematical and physical intuition, a detailed history of cryptography from antiquity to the present day and how it works in practice, the development of quantum information science, the nature of reality, and more. Howard Burton is the founder of the Ideas Roadshow, Ideas on Film and host of the Ideas Roadshow Podcast. He can be reached at howard@ideasroadshow.com. Learn more about your ad choices. Visit megaphone.fm/adchoices Support our show by becoming a premium member! https://newbooksnetwork.supportingcast.fm/science-technology-and-society

Cryptoreality is based on an in-depth filmed conversation between Howard Burton and Artur Ekert, Professor of Quantum Physics at the Mathematical Institute at the University of Oxford and Director of the Centre for Quantum Technologies and Lee Kong Chian Centennial Professor at the National University of Singapore. Artur Ekert is one of the pioneers of quantum cryptography. This wide-ranging conversation provides detailed insights into his research and covers many fascinating topics such as mathematical and physical intuition, a detailed history of cryptography from antiquity to the present day and how it works in practice, the development of quantum information science, the nature of reality, and more. Howard Burton is the founder of the Ideas Roadshow, Ideas on Film and host of the Ideas Roadshow Podcast. He can be reached at howard@ideasroadshow.com. Learn more about your ad choices. Visit megaphone.fm/adchoices Support our show by becoming a premium member! https://newbooksnetwork.supportingcast.fm/science

Cryptoreality is based on an in-depth filmed conversation between Howard Burton and Artur Ekert, Professor of Quantum Physics at the Mathematical Institute at the University of Oxford and Director of the Centre for Quantum Technologies and Lee Kong Chian Centennial Professor at the National University of Singapore. Artur Ekert is one of the pioneers of quantum cryptography. This wide-ranging conversation provides detailed insights into his research and covers many fascinating topics such as mathematical and physical intuition, a detailed history of cryptography from antiquity to the present day and how it works in practice, the development of quantum information science, the nature of reality, and more. Howard Burton is the founder of the Ideas Roadshow, Ideas on Film and host of the Ideas Roadshow Podcast. He can be reached at howard@ideasroadshow.com. Learn more about your ad choices. Visit megaphone.fm/adchoices Support our show by becoming a premium member! https://newbooksnetwork.supportingcast.fm/communications

Cryptoreality is based on an in-depth filmed conversation between Howard Burton and Artur Ekert, Professor of Quantum Physics at the Mathematical Institute at the University of Oxford and Director of the Centre for Quantum Technologies and Lee Kong Chian Centennial Professor at the National University of Singapore. Artur Ekert is one of the pioneers of quantum cryptography. This wide-ranging conversation provides detailed insights into his research and covers many fascinating topics such as mathematical and physical intuition, a detailed history of cryptography from antiquity to the present day and how it works in practice, the development of quantum information science, the nature of reality, and more. Howard Burton is the founder of the Ideas Roadshow, Ideas on Film and host of the Ideas Roadshow Podcast. He can be reached at howard@ideasroadshow.com. Learn more about your ad choices. Visit megaphone.fm/adchoices Support our show by becoming a premium member! https://newbooksnetwork.supportingcast.fm/national-security

Dr Vicky Neale is the Whitehead Lecturer at the Mathematical Institute and Balliol College at the University of Oxford. She is also a Supernumerary Fellow at Balliol and the author of two great books aimed at general audiences, namely ‘Closing the Gap' and ‘Why Study Mathematics?'. Vicky Neale is a great communicator of Mathematics. She was given an MPLS Teaching Award in 2016 and she also won an award for being the Most Acclaimed Lecturer in MPLS in the student-led Oxford University Student Union Teaching Awards 2015.Follow her on Twitter: @VickyMaths1729 For some clear proofs of a selection of mathematical theorems, check out her YouTube channel: https://www.youtube.com/channel/UCBGhXXBCAzbzQV65JZoGhjw and her blog https://theoremoftheweek.wordpress.com/ Conversation Outline: 00:00 Guest Introduction01:05 Vicky's mathematical background04:13 Motivations for writing a book on reasons to study mathematics07:11 Are good reasons for studying Mathematics timeless? Would this book have more or less the same contents, had it been written many years ago? 10:10 Is the job of pure mathematicians safe from AI developments?12:13 What are the benefits (for the non-mathematician) of knowing about mathematical notions such as integrals, derivatives, matrices and so on? 15:39 Are some people more mathematically talented than others? 18:45 Does the discussion of talent change when we are talking about research-level Mathematics? Douglas Hofstadter's experience.22:45 Aesthetics of Mathematics25:00 Is Number Theory more beautiful than other mathematical subfields? 25:52 A mathematician's view of the metaphysics of numbers27:58 Fermat's Last Theorem, Andrew Wiles and finding meaning in Mathematics29:26 FLT and the Twin Prime Conjecture32:27 Should graduate students tackle famous open problems?33:41 Closing the Gap: significant progress towards solving the Twin Prime Conjecture35:10 Polymath: an example of collaborative Mathematics39:40 Do we have reasons to believe that the Twin Prime Conjecture is actually true?Enjoy!Apple Podcasts:https://podcasts.apple.com/gb/podcast/philosophical-trials/id1513707135Spotify: https://open.spotify.com/show/3Sz88leU8tmeKe3MAZ9i10Google Podcasts:https://podcasts.google.com/?q=philosophical%20trialsInstagram: https://www.instagram.com/tedynenu/

Today's guest is Renaud Lambiotte Renaud is an associate professor at the Mathematical Institute of Oxford University, investigating processes taking place on large networks.In the episode, we talk about his story in science, the joy and value of exploring without a particular purpose, doing a PhD without publishing any papers, … and how reading classical texts by Boltzman and others early on has shaped the work Renaud does even to this day.When we get to the paper, we talk about Renaud's recent work “Variance and covariance of distributions on graphs” (1) with co-authors Karel Devriendt and Samuel Martin-Gutierrez.#Timestamps[0:00:00] Intro to today's episode[0:00:59] Friendly banter, and being in awe of Mark Newman[0:07:00] Renaud's story[0:28:38] The Louvain Algorithm t-shirt[0:34:00] Now to discuss the paper!# CreditsThe podcast has theme music by Waylon Thornton. Songs are "American Heart" and "Seven". Via freemusicarchive.org and licenced under CC BY-NC-SA. The podcast was funded in part by the Villum Foundation. # References(1) https://arxiv.org/abs/2008.09155

Did you know that the winner of the 2019/2020 Fantasy Premier League, beating over 7 million other players, was Dr Joshua Bull - a researcher at Oxford's Mathematical Institute? How did he win? Turns out that 'mathematical thinking' and a strategic approach, combined with "gut instinct and a healthy dose of good luck" might just be the answer! Could you be next year's winner? Join us as Joshua shares his tips!

Dr Fergus Cooper, Research Software Engineer, Oxford RSE Group, gives a talk for the department of Statistics on 5th June 2020. Following on from Graham Lee's talk on automated testing, we will use GitHub actions to automate the testing of a small Python project. We will: recap why this might be a good idea; walk through setting up a workflow on GitHub; test our code against multiple Python versions on multiple operating systems; and integrate other services such as code coverage and automated documentation generation. Dr Fergus Cooper is a member of the Oxford Research Software Engineering group, which he co-founded in 2018 after finishing a DPhil in the Mathematical Institute. His research background is computational biology where he developed agent-based models of the developing tooth placode. He is now a passionate advocate for software best practices in academia, and will talk to anyone about modern C++."

Dr Fergus Cooper, Research Software Engineer, Oxford RSE Group, gives a talk for the department of Statistics on 5th June 2020. Following on from Graham Lee's talk on automated testing, we will use GitHub actions to automate the testing of a small Python project. We will: recap why this might be a good idea; walk through setting up a workflow on GitHub; test our code against multiple Python versions on multiple operating systems; and integrate other services such as code coverage and automated documentation generation. Dr Fergus Cooper is a member of the Oxford Research Software Engineering group, which he co-founded in 2018 after finishing a DPhil in the Mathematical Institute. His research background is computational biology where he developed agent-based models of the developing tooth placode. He is now a passionate advocate for software best practices in academia, and will talk to anyone about modern C++."

How do you make a star-shaped Cheerio? How do they make the glass on your smartphone screen so flat? And how can you make a vacuum filter that removes the most dust before it blocks? All of these challenges fall under the umbrella of industrial mathematics and they all have a common theme: we know the final properties of the product we want to make and need to come up with a way of manufacturing this. Ian Griffiths demonstrates how we can use mathematics to start with the final desired product and trace the problem ‘back in time' to manufacture products that would otherwise be impossible to produce. Ian Griffiths is a Professor of Industrial Mathematics and a Royal Society University Research Fellow in the Mathematical Institute at the University of Oxford.

How do you make a star-shaped Cheerio? How do they make the glass on your smartphone screen so flat? And how can you make a vacuum filter that removes the most dust before it blocks? All of these challenges fall under the umbrella of industrial mathematics and they all have a common theme: we know the final properties of the product we want to make and need to come up with a way of manufacturing this. Ian Griffiths demonstrates how we can use mathematics to start with the final desired product and trace the problem ‘back in time’ to manufacture products that would otherwise be impossible to produce. Ian Griffiths is a Professor of Industrial Mathematics and a Royal Society University Research Fellow in the Mathematical Institute at the University of Oxford.

Computing In Poland Welcome to the History of Computing Podcast, where we explore the history of information technology. Because understanding the past prepares us to innovate (and sometimes cope with) the future! Today we're going to do something a little different. Based on a recent trip to Katowice and Krakow, and a great visit to the Museum of Computer and Information Technology in Katowice, we're going to look at the history of computing in Poland. Something they are proud of and should be proud of. And I'm going to mispronounce some words. Because they are averse to vowels. But not really, instead because I'm just not too bright. Apologies in advance. First, let's take a stroll through an overly brief history of Poland itself. Atilla the Hun and other conquerors pushed Germanic tribes from Poland in the fourth century which led to a migration of Slavs from the East into the area. After a long period of migration, duke Mieszko established the Piast dynasty in 966, and they created the kingdom of Poland in 1025, which lasted until 1370 when Casimir the Great died without an heir. That was replaced by the Jagiellonian dynasty which expanded until they eventually developed into the Polish-Lithuanian Commonwealth in 1569. Turns out they overextended themselves until the Russians, Prussians, and Austria invaded and finally took control in 1795, partitioning Poland. Just before that, Polish clockmaker Jewna Jakobson built a mechanical computing machine, a hundred years after Pascal, in 1770. And innovations In mechanical computing continued on with Abraham Izrael Stern and his son through the 1800s and Bruno's Intergraph, which could solve complex differential equations. And so the borders changed as Prussia gave way to Germany until World War I when the Second Polish Republic was established. And the Poles got good at cracking codes as they struggled to stay sovereign against Russian attacks. Just as they'd struggled to stay sovereign for well over a century. Then the Germans and Soviets formed a pact in 1939 and took the country again. During the war, Polish scientists not only assisted with work on the Enigma but also with the nuclear program in the US, the Manhattan Project. Stanislaw Ulam was recruited to the project and helped with ENIAC by developing the Monte Carlo method along with Jon Von Neumann. The country remained partitioned until Germany fell in WWII and the Soviets were able to effectively rule the Polish People's Republic until a socal-Democratic movement swept the country in 1989, resulting in the current government and Poland moving from the Eastern Bloc to NATO and eventually the EU around the same time the wall fell in Berlin. Able to put the Cold War behind them, Polish cities are now bustling with technical innovation and is now home some of the best software developers I've ever met. Polish contributions to a more modern computer science began in 1924 when Jan Lukasiewicz developed Polish Notation, a way of writing mathematical expressions such that they are operator-first. during World War II when the Polish Cipher Bureau were the first that broke the Enigma encryption, at different levels from 1932 to 1939. They had been breaking codes since using them to thwart a Russian invasion in the 1920s and had a pretty mature operation at this point. But it was a slow, manUal process, so Marian Rejewski, one of the cryptographers developed a card catalog of permutations and used a mechanical computing device he invented a few years earlier called a cyclometer to decipher the codes. The combination led to the bomba kryptologiczna which was shown to the allies 5 weeks before the war started and in turn led to the Ultra program and eventually Colossus once Alan Turing got a hold of it, conceptually after meeting Rejewski. After the war he became an accountant to avoid being forced into slave cryptographic work by the Russians. In 1948 the Group for Mathematical Apparatus of the Mathematical Institute in Warsaw was formed and the academic field of computer research was formed in Poland. Computing continued in Poland during the Soviet-controlled era. EMAL-1 was started in 1953 but was never finished. The XYZ computer came along in 1958. Jack Karpiński built the first real vacuum tube mainframe in Poland, called the AAH in 1957 to analyze weather patterns and improve forecasts. He then worked with a team to build the AKAT-1 to simulate lots of labor intensive calculations like heat transfer mechanics. Karpinski founded the Laboratory for Artificial Intelligence of the Polish Academy of Sciences. He would win a UNESCO award and receive a 6 month scholarship to study in the US, which the polish government used to spy on American progress in computing. He came home armed with some innovative ideas from the West and by 1964 built what he called the Perceptron, a computer that could be taught to identify shapes and even some objects. Nothing like that had existed in Poland or anywhere else controlled by communist regimes at the time. From 65 to 68 he built the KAR-65, even faster, to study CERN data. By then there was a rising mainframe and minicomputer industry outside of academia in Poland. Production of the Odra mainframe-era computers began in 1959 in Wroclaw, Poland and his work was seen by them and Elwro as a threat do they banned him from publishing for a time. Elwro built a new factory in 1968, copying IBM standardization. In 1970, Karpiński realized he had to play ball with the government and got backing from officials in the government. He would then designed the k-202 minicomputer in 1971. Minicomputers were on the rise globally and he introduced the concept of paging to computer science, key in virtual memory. This time he recruited 113 programmers and hardware engineers and by 73 were using Intel 4004 chips to build faster computers than the DEC PDP-11. But the competitors shut him down. They only sold 30 and by 1978 he retired to Switzerland (that sounds better than fled) - but he returned to Poland following the end of communism in the country and the closing of the Elwro plant in 1989. By then the Personal Computing revolution was upon us. That had begun in Poland with the Meritum, a TRS-80 clone, back in 1983. More copying. But the Elwro 800 Junior shipped in 1986 and by 1990 when the communists split the country could benefit from computers being mass produced and the removal of export restrictions that were stifling innovation and keeping Poles from participating in the exploding economy around computers. Energized, the Poles quickly learned to write code and now graduate over 40,000 people in IT from universities, by some counts making Poland a top 5 tech country. And as an era of developers graduate they are founding museums to honor those who built their industry. It has been my privilege to visit two of them at this point. The description of the one in Krakow reads: The Interactive Games and Computers Museum of the Past Era is a place where adults will return to their childhood and children will be drawn into a lots of fun. We invite you to play on more than 20 computers / consoles / arcade machines and to watch our collection of 200 machines and toys from the '70's-'90's. The second is the Museum of Computer and Information Technology in Katowice, and the most recent that I had the good fortune to visit. Both have systems found at other types of computer history museums such as a Commodore PET but showcasing the locally developed systems and looking at them on a timeline it's quickly apparent that while Poland had begun to fall behind by the 80s, it was more a reflection of why the strikes throughout caused the Eastern Bloc to fall, because Russian influence couldn't. Much as the Polish-Lithuanian Commonwealth couldn't support Polish control of Lithuania in the late 1700s. There were other accomplishments such as The ZAM-2. And the first fully Polish machine, the BINEG. And rough set theory. And ultrasonic mercury memory.

Highly acclaimed British author Tessa Hadley talks to Harriett Gilbert about her award-winning novel - The Past. Recorded at the FT Weekend Oxford Literary Festival in the elegant surroundings of The Mathematical Institute, part of the university. Tessa skilfully evokes a brewing storm of lust and envy, the indelible connections of memory and affection, the fierce, nostalgic beauty of the natural world, and the shifting currents of history running beneath the surface of these seemingly steady lives. Over three long, hot summer weeks, four siblings and their children assemble at their country house for a family reunion, where simmering tensions and secrets come to a head. First broadcast on the BBC World Service in April 2019.

J. DOYNE FARMER is director of the Complexity Economics Programme at the Institute for New Economic Thinking at the Oxford Martin School, professor in the Mathematical Institute at the University of Oxford, and an external professor at the Santa Fe Institute. He was a co-founder of Prediction Company, a quantitative automated trading firm that was sold to the United Bank of Switzerland in 2006. The Conversation: https://www.edge.org/conversation/jdoynefarmer-don_ross-collective-awareness

Sam Harris speaks with Eric Weinstein and Ben Shapiro about the breakdown of shared values, the problem with identity politics, religion, free will, the primacy of reason, and many other topics. Eric Weinstein is a managing director of Thiel Capital in San Francisco. He is also a research fellow at the Mathematical Institute of Oxford University. Weinstein speaks and publishes on a variety of topics including, gauge theory, immigration, the market for elite labor, management of financial risk and the incentivizing of risk taking in science. And he, along with brother Bret—whom I just did a podcast with in Seattle—has become an unusually powerful advocate for free speech. Ben Shapiro is editor-in-chief of DailyWire.com, and host of “The Ben Shapiro Show,” the top conservative podcast in the nation, and a leading conservative speaker on college campuses, consistently defending free speech and open debate. Ben is the author of seven books, including The New York Times bestseller, Bullies: How the Left’s Culture of Fear and Intimidation Silences America. He has also been a nationally syndicated columnist since age 17. He’s a graduate of UCLA and Harvard Law School. Twitter:@EricRWeinstein@BenShapiro

Prime numbers have intrigued, inspired and infuriated mathematicians for millennia and yet mathematicians' difficulty with answering simple questions about them reveals their depth and subtlety. Join Vicky to learn about recent progress towards proving the famous Twin Primes Conjecture and to hear the very different ways in which these breakthroughs have been made - a solo mathematician working in isolation, a young mathematician displaying creativity at the start of a career, a large collaboration that reveals much about how mathematicians go about their work. Her new book "Closing the Gap: the quest to understand prime numbers" has recently been published by Oxford University Press. Vicky Neale is Whitehead Lecturer at the Mathematical Institute, University of Oxford and Supernumerary Fellow at Balliol College

Alice Schwarze is a physicist with the Mathematical Institute at Oxford University and a member of Pembroke College. Alice is a Clarendon Scholar specialising in systems approaches to biomedical science. She currently works on modelling protein-interaction networks for pharmaceutical applications. Alice got interested in physics as a young teen attending Mensa summer camps. We discuss her career development including what it's like working in a male-dominated field. Alice shares advice for young women thinking of becoming scientists.

Anne McElvoy meets David Rooney curator of the Winton Mathematics gallery at the Science Museum which has been redesigned by Zaha Hadid architects and explores the way maths skills are increasingly needed for jobs. She discusses the changing attitudes to mathematics in history and the present day with Alex Bellos, writer on maths puzzles, maths historian Serafina Cuomo and maths lecturer Vicky Neale. They are joined by astro-physicist Neil de Grasse Tyson who is director of the Hayden Planetarium at the American Museum of Natural History. Alex Bellos is the author of Alex Through The Looking Glass and his latest book called Can You Solve My Problems. Neil de Grasse Tyson is the author of many books including Welcome to the Universe co-written with J Richard Gott and Michael A Strauss. Vicky Neale is Whitehead Lecturer at the Mathematical Institute and Balliol College at Oxford University. Serafina Cuomo is Reader in Roman History at Birkbeck College, University of London. Producer: Harry Parker.

Sir Roger Penrose, Ph.D., OM, FRS is an English mathematical physicist and Emeritus Rouse Ball Professor of Mathematics at the Mathematical Institute, University of Oxford and Emeritus Fellow of Wadham College. He is renowned for his work in mathematical physics, in particular his contributions to general relativity and cosmology. He is also a recreational mathematician and philosopher.

We are getting better at predicting things about our environment - the impact of climate change for example. But what about predicting our collective effect on ourselves? We can predict the small things, but we fail miserably when it comes to many of the big things. The financial crisis cost the world trillions, yet our ability to forecast and mitigate the next economic crisis is very low. Is this inherently impossible? Or perhaps we are just not going about it the right way? The complex systems approach to economics, which brings in insights from the physical and natural sciences, presents an alternative to standard methods. Doyne will explain this new approach and give examples of its successes. He will present a vision of the economics of the future as it confronts the serious problems that our world will face. J. Doyne Farmer is Director of the Complexity Economics program at the Institute for New Economic Thinking at the Oxford Martin School and Professor in the Mathematical Institute at the University of Oxford

Eric R. Weinstein is a managing director of Thiel Capital in San Francisco. He is also a research fellow at the Mathematical Institute of Oxford University. Weinstein speaks and publishes on a variety of topics including, gauge theory, immigration, the market for elite labor, management of financial risk and the incentivizing of risk taking in science. He can be contacted on Twitter: @EricRWeinstein. Articles mentioned in this podcast:A. Koestler. “The Nightmare That Is a Reality” The New York Times Magazine. January 9, 1944. S. Harris. “Islam and the Misuses of Ecstasy” Visual aid:

My guest this episode is my friend, Eric Weinstein (@ericrweinstein), managing director of Thiel Capital, a Ph.D in mathematical physics from Harvard, and a research fellow at the Mathematical Institute of Oxford University. We recorded at my house after Eric emailed me this question: "Wanna try a podcast on… psychedelics, theories of everything, and the need to destroy education in order to save it?" He’s brilliant and hilarious. If you enjoyed my podcasts with Derek Sivers or Sam Harris, you’ll love this one. We cover a lot of ground, including: Living from first principles rather than the “consensus reality" The genius of Kung Fu Panda What it’s like working with Peter Thiel, and how Peter hired him How to innovate when you risk being crucified by close-minded communities (and experts) His favorite books Why one of his favorite documentaries is about pornographers And much more... Also, be sure to check this out. Here is the Johns Hopkins psychedelic research I'm backing. Check out the supporters from tech and business. Show notes and links for this episode can be found at www.fourhourworkweek.com/podcast. This podcast is brought to you by Wealthfront. Wealthfront is a massively disruptive (in a good way) set-it-and-forget-it investing service, led by technologists from places like Apple and world-famous investors. It has exploded in popularity in the last 2 years and now has more than $2.5B under management. In fact, some of my good investor friends in Silicon Valley have millions of their own money in Wealthfront. Why? Because you can get services previously limited to the ultra-wealthy and only pay pennies on the dollar for them, and it’s all through smarter software instead of retail locations and bloated sales teams. Check out wealthfront.com/tim, take their risk assessment quiz, which only takes 2-5 minutes, and they’ll show you—for free–exactly the portfolio they’d put you in. If you want to just take their advice and do it yourself, you can. Or, as I would, you can set it and forget it. Well worth a few minutes: wealthfront.com/tim. This podcast is also brought to you by 99Designs, the worldís largest marketplace of graphic designers. I have used them for years to create some amazing designs. When your business needs a logo, website design, business card, or anything you can imagine, check out 99Designs. I used them to rapid prototype the cover for The 4-Hour Body, and I've also had them help with display advertising and illustrations. If you want a more personalized approach, I recommend their 1-on-1 service, which is non-spec. You get original designs from designers around the world. The best part? You provide your feedback, and then you end up with a product that you're happy with or your money back. Click this link and get a free $99 upgrade. Give it a test run. ***If you enjoy the podcast, would you please consider leaving a short review on Apple Podcasts/iTunes? It takes less than 60 seconds, and it really makes a difference in helping to convince hard-to-get guests. I also love reading the reviews!For show notes and past guests, please visit tim.blog/podcast.Sign up for Tim’s email newsletter (“5-Bullet Friday”) at tim.blog/friday.For transcripts of episodes, go to tim.blog/transcripts.Interested in sponsoring the podcast? Visit tim.blog/sponsor and fill out the form.Discover Tim’s books: tim.blog/books.Follow Tim:Twitter: twitter.com/tferriss Instagram: instagram.com/timferrissFacebook: facebook.com/timferriss YouTube: youtube.com/timferriss

The understanding of the possible geometries in dimension 3 is one of the triumphs of 20th century mathematics. In this talk Martin Bridson explains why such an understanding is impossible in higher dimensions. When one wants to describe the symmetries of any object or system, in mathematics or everyday life, the right language to use is group theory. How might one go about understanding the universe of all groups and what kinds of novel geometry might emerge as we explore this universe? Martin Bridson became Head of the Mathematical Institute on 01 October 2015. To mark the occasion he gave this Inaugural Chairman's Public Lecture.

The understanding of the possible geometries in dimension 3 is one of the triumphs of 20th century mathematics. In this talk Martin Bridson explains why such an understanding is impossible in higher dimensions. When one wants to describe the symmetries of any object or system, in mathematics or everyday life, the right language to use is group theory. How might one go about understanding the universe of all groups and what kinds of novel geometry might emerge as we explore this universe? Martin Bridson became Head of the Mathematical Institute on 01 October 2015. To mark the occasion he gave this Inaugural Chairman's Public Lecture.

World-renowned mathematician Sir Roger Penrose, Oxford University, describes how crystalline symmetries are necessarily 2-fold, 3-fold, 4-fold, or 6-fold.

World-renowned mathematician Sir Roger Penrose, Oxford University, describes how crystalline symmetries are necessarily 2-fold, 3-fold, 4-fold, or 6-fold.

World-renowned mathematician Sir Roger Penrose, Oxford University, describes how crystalline symmetries are necessarily 2-fold, 3-fold, 4-fold, or 6-fold.

World-renowned mathematician Sir Roger Penrose, Oxford University, describes how crystalline symmetries are necessarily 2-fold, 3-fold, 4-fold, or 6-fold.

Melvyn Bragg and his guests discuss Euler's number, also known as e. First discovered in the seventeenth century by the Swiss mathematician Jacob Bernoulli when he was studying compound interest, e is now recognised as one of the most important and interesting numbers in mathematics. Roughly equal to 2.718, e is useful in studying many everyday situations, from personal savings to epidemics. It also features in Euler's Identity, sometimes described as the most beautiful equation ever written. With: Colva Roney-Dougal Reader in Pure Mathematics at the University of St Andrews June Barrow-Green Senior Lecturer in the History of Maths at the Open University Vicky Neale Whitehead Lecturer at the Mathematical Institute and Balliol College at the University of Oxford Producer: Thomas Morris.

Melvyn Bragg and his guests discuss Euler's number, also known as e. First discovered in the seventeenth century by the Swiss mathematician Jacob Bernoulli when he was studying compound interest, e is now recognised as one of the most important and interesting numbers in mathematics. Roughly equal to 2.718, e is useful in studying many everyday situations, from personal savings to epidemics. It also features in Euler's Identity, sometimes described as the most beautiful equation ever written. With: Colva Roney-Dougal Reader in Pure Mathematics at the University of St Andrews June Barrow-Green Senior Lecturer in the History of Maths at the Open University Vicky Neale Whitehead Lecturer at the Mathematical Institute and Balliol College at the University of Oxford Producer: Thomas Morris.

Knowledge Exchange Fellow Oliver Cox (@OliverJWCox) from The Oxford Research Centre in the Humanities (TORCH) asked members of the public, students and academics in Oxford whether humanities subjects are worth investing in. This question will be asked again at the opening event of TORCH's Humanities and the Public Good Series on Monday 27 January at the Mathematical Institute, Radcliffe Observatory Quarter from 5pm. Introduced by the Vice-Chancellor Professor Andrew Hamilton and chaired by the Head of the Humanities Division Professor Shearer West, the event brings together leading scholars in the humanities and sciences, and influential figures beyond academia, to consider the role of the humanities in addressing contemporary challenges. Professor Earl Lewis, President of the Andrew W. Mellon Foundation will give an opening presentation entitled In Everyone's Interests: What it Means to Invest in the Humanities. This will be followed by a roundtable discussion including David Willetts (Universities Minister), Hermione Lee (President of Wolfson College and Biographer), Marcus du Sautoy (Charles Simonyi Professor for the Public Understanding of Science) and Charlotte Higgins (Chief Arts Writer, The Guardian). Visit http://www.torch.ox.ac.uk for more information and find TORCH on Facebook: http://www.facebook.com/TORCHOxford.

Dr Richard Earl of the Mathematical Institute, Oxford presents a talk about prime numbers. What they are and their role in internet security.

Dr Richard Earl of the Mathematical Institute, Oxford presents a talk about prime numbers. What they are and their role in internet security.

This event brings together scientists Patrick Haggard, Professor at the Institute of Cognitive Neuroscience & Department of Psychology, and Marcus du Sautoy, Professor of Mathematics, Royal Society University Research Fellow, Mathematical Institute, Unive