⏰ Registration for the Entropy 2026 Conference in Barcelona closes in two days! 📅 June 15th is your last day to get registered for the in-person conference. 🚨 Don’t miss the dedicated Quantum Information and Quantum Computing Session on opening day featuring keynotes on entropic quantum gravity, monitored quantum systems on NISQ platforms, the capacity of a single quantum neuron, quantum reservoir computing and expressibility-guided architecture search under noise. 👉 Interdisciplinary program, poster sessions and a banquet in beautiful Barcelona — perfect for networking and cross-pollination with entropy, information theory and statistical physics. ❗Register now 👉 sciforum.net/event/Entropy20… #Entropy2026 #QuantumComputing #Barcelona #QuantumInformation #MDPI @Entropy_MDPI

🧩 What connects barcode scanners, satellite communications, cloud storage, and quantum computers? 👉 Error-correcting codes. The new Handbook of Error-Correcting Codes catalogs the enormous ecosystem of classical and quantum codes and the mathematical structures behind them. 📚 Codes 🔗 Lattices 🎯 Sphere packings ⚛️ Quantum phases of matter 🚀 Fault-tolerant quantum computing A must-read resource for anyone exploring quantum information science. 📖 Read: arxiv.org/abs/2606.11484 #QuantumComputing #CodingTheory #QuantumInformation #FaultTolerance #QubitScript

🦉மனிதர்களை ஒரு இடத்திலிருந்து மற்றொரு இடத்திற்கு நொடிப்பொழுதில் கடத்தும் 'டெலிபோர்ட்டேஷன்' (Human Teleportation) தொழில்நுட்பம் சாத்தியமா என்ற நீண்ட நாள் கேள்விக்கு விடை தேடும் வகையில், குவாண்டம் இயற்பியல் துறையில் விஞ்ஞானிகள் நிகழ்த்தியுள்ள புதிய சாதனை உலகளவில் பெரும் எதிர்பார்ப்பைக் கிளப்பியுள்ளது. தற்போதைய சூழலில் மனிதர்களை நேரடியாக இப்படி அனுப்ப முடியாது என்றாலும், மிகத் துல்லியமான குவாண்டம் தகவல்களை (Quantum information) முன்னெப்போதையும் விட மிக நீண்ட தூரத்திற்கு வெற்றிகரமாகக் கடத்தி ஆராய்ச்சியாளர்கள் அசத்தியுள்ளனர். இந்தத் தொழில்நுட்ப வளர்ச்சியின் பின்னணியில் ஒரு மிகப்பெரிய அறிவியல் புதிர் ஒளிந்திருக்கிறது; அதாவது, எதிர்காலத்தில் ஒரு மனிதனை உருவாக்கும் ஒவ்வொரு அணுவையும், தகவலையும் குவாண்டம் முறையில் மற்றொரு இடத்திற்கு அனுப்பி, அங்கு அவரை மீண்டும் உருவாக்கினாலும், அவ்வாறு உருவாகும் நபர் அதே மனிதராகத்தான் இருப்பாரா அல்லது புதியவரா என்ற தத்துவார்த்தக் கேள்வி எழுந்துள்ளது. இப்போதைக்கு மனிதர்களைக் கடத்துவது என்பது அறிவியல் புனைகதையாக மட்டுமே இருந்தாலும், குவாண்டம் துறையில் அடுத்தடுத்து நிகழும் அதிரடி முன்னேற்றங்கள், நாம் சாத்தியமே இல்லை என்று நினைத்த பல விஷயங்களை எதிர்காலத்தில் நிஜமாக்கிக் காட்டலாம் என்று விஞ்ஞானிகள் நம்புகின்றனர்! #அறிவியல்உலகம் #குவாண்டம்இயற்பியல் #டெலிபோர்ட்டேஷன் #புதியகண்டுபிடிப்பு #எதிர்காலதொழில்நுட்பம் #ஆந்தைரிப்போர்ட்டர் #ScienceBreakthrough #QuantumPhysics #Teleportation #FutureTech #QuantumInformation #ScienceFictionToReality #AanthaiReporter

RT: The Aharonov-Berry Symposium in Quantum Physics will bring together leading researchers working at the frontiers of quantum foundations, geometric and topological phases, quantum information, photonics, and emerging quantum technologies. Registration is now open. Space is limited, and attendance will be capped, so early registration is strongly encouraged. For details and registration, please visit the symposium website or scan the QR code below. shorturl.at/IK7Qh Chapman University, Orange County, California September 28–30, 2026 #QuantumPhysics #QuantumFoundations #AharonovBerry #QuantumInformation #Photonics #ChapmanUniversity

📋 #Entropy2026 Detailed Program is out! 17 keynote speakers, with oral talks & posters. 📌 Check the schedule and secure your place by 15 June 2026: sciforum.net/event/Entropy20… #ComplexSystems #Physics #InformationTheory #StatisticalPhysics #QuantumInformation

Quantum information science is advancing quickly — but lasting progress still depends on strong theoretical, mathematical, and physical foundations. World Scientific’s Quantum Information & Quantum Science Journal Collection supports researchers working across quantum information, quantum theory, mathematical physics, many-body systems, photonics, and related areas. This collection is especially relevant for researchers who want to go beyond applied “quantum technology” papers and engage with the rigorous frameworks behind emerging advances in the field. 🔬 Research areas covered include: • Quantum information and computation • Quantum algorithms, communication, and error correction • Quantum probability and mathematical foundations • Many-body quantum systems and statistical mechanics • Optical physics, nonlinear optics, and quantum materials • Theoretical and mathematical physics 📚 Included journals: • International Journal of Quantum Information worldscientific.com/worldsci… • Reviews in Mathematical Physics worldscientific.com/worldsci… • Infinite Dimensional Analysis, Quantum Probability and Related Topics worldscientific.com/worldsci… • International Journal of Modern Physics A worldscientific.com/worldsci… • International Journal of Modern Physics B worldscientific.com/worldsci… • Modern Physics Letters A worldscientific.com/worldsci… • Journal of Nonlinear Optical Physics & Materials worldscientific.com/worldsci… If you are a researcher, faculty member, or librarian working in quantum science, I’d be happy to discuss how this collection may support your research group or institution. 📩 Contact me at amirah@wspc.com to discuss access, trial options, or relevant titles for your research area. #QuantumInformation #QuantumScience #QuantumComputing #MathematicalPhysics #ManyBodyPhysics #TheoreticalPhysics #Photonics #ResearchImpact #ScientificPublishing

📍 Entropy 2026 Barcelona July 1-3 🚀 Explore quantum info, complexity & foundations. Keynotes on entropic quantum gravity & NISQ apps. ‼️Register before June 15‼️ 👉 Get it here -> tinyurl.com/3rcp377x #Entropy2026 #QuantumComputing #Barcelona #QuantumInformation @Entropy_MDPI @InformationMDPI @QMdpi

🚨 New paper 📜 arxiv.org/abs/2605.28939. Dynamical Entanglement Phase Transitions in Holographic CFTs Understanding how quantum information reorganizes during non-equilibrium dynamics is one of the central challenges in many-body physics and holography. In this work, we show that mutual information after a local quench in 1 1D holographic CFTs exhibits a rich structure of dynamical phase transitions (DPTs): sharp non-analytic changes in time-dependent observables that occur during unitary evolution, analogous to phase transitions in equilibrium statistical physics. In the large-central-charge limit, mutual information develops sharp cusps and transition points controlled by changes in the dominant conformal block — equivalently, by competing holographic geodesic configurations in AdS. The dynamics organize into six distinct phases of mutual information. This structure goes beyond the standard quasiparticle picture of entanglement spreading and explains non-analytic features that cannot be understood purely from simple light-cone propagation from the quench points. We also identify a dynamical D₄ symmetry acting on the interval endpoints that determines whether mutual information is present or absent. The onset of correlations is associated with a symmetry breaking pattern D₄ → Z₂ × Z₂, suggesting a symmetry-based framework for non-equilibrium entanglement dynamics. One intriguing possibility raised by our results is that these dynamical entanglement transitions may admit an effective Landau-like description, with mutual-information phases characterized by symmetry and order-parameter-like structures, much like equilibrium critical phenomena. Finally, we compare with numerical simulations of critical spin chains and find that finite-c effects smooth many of the sharp large-c transitions, while transitions associated with the appearance or disappearance of mutual information remain strikingly robust. Big thanks to my wonderful collaborators Lukas Ebner, David Horn, Joseph Dominicus Lap, Jakob Minar, Berndt Mueller, Andreas Schäfer, and Clemens Seidl. #QuantumPhysics #TheoreticalPhysics #QuantumInformation #Holography #Entanglement #NonEquilibriumDynamics #CFT #AdSCFT #QuantumDynamics @ERC_Research @LMU_Muenchen @MCQST_cluster @uni_regensburg @DukeU @EPFL @kh_univ @maxplanckpress @MPI_Quantum

🚨UNIPHICS🚨: Entanglement isn’t spooky action at a distance — it’s spin waves staying in phase across the energy sea 🧨 Quantum entanglement is often presented as one of the strangest features of reality: two particles can remain perfectly correlated no matter how far apart they are, as if one instantly “knows” what happens to the other. This has led to decades of debate about what it really means. Uniphics shows that entanglement is a natural and expected consequence of spin-wave behavior in the ξM-field. When Gyrotrons (or groups of them) form coherent spin-wave patterns, the waves can remain phase-locked across significant distances. Because these patterns are extended modes in the unbound energy field, a change or measurement affecting one part of the wave immediately correlates with the other parts — not because of faster-than-light signaling, but because they are aspects of the same underlying spin-wave configuration. Negentropy favors these stable, correlated states because they represent lower-energy organized patterns. The same principles that allow long-lived quantum coherence and protect certain spin correlations also produce the correlations we observe as entanglement. There is no need for mysterious non-local influences; the correlations are carried by the spin waves themselves. This turns entanglement from an inexplicable puzzle into a straightforward result of coherent spin-wave dynamics in the ξM-field. How might understanding entanglement as phase-locked spin waves in the energy field change the way we think about quantum information, measurement, or the design of quantum technologies? A Theory of Everything should be able to answer everything. Uniphics Explained Simply PDF: uniphics.com/wp-content/uplo… Chapters 1–10 free: uniphics.com/gallery/ Grokipedia grokipedia.com/page/Uniphics #Uniphics #Entanglement #SpinWaves #QuantumCoherence #QuantumInformation @grok @xAI

Quantum Optics 2026 ✨ La histórica conferencia internacional sobre óptica cuántica vuelve a reunir a la comunidad científica de América Latina y el mundo para debatir los avances más recientes en información cuántica, fotónica, fundamentos de la mecánica cuántica y más. Esta edición se realizará en honor al profesor Juan Pablo Paz, por sus enormes contribuciones a la física cuántica y su compromiso con el desarrollo de la comunidad científica regional. quantumoptics.lat/xi/ #QuantumOptics #QuantumInformation #Physics #UBA

Kuantum bilgisayarlarını inşa etmek için geliştirdiğimiz Kuantum Hata Düzeltme (Quantum Error Correction) protokolleri, aslınds laboratuvardan çok önce kara deliklerin kalbinde yazılmıştı. ​Fizik dünyası, kara deliğe düşen enformasyonun Hawking radyasyonuyla nasıl buharlaşmadığını çözmeye çalışırken sarsıcı bir gerçekle karşılaştı: Evren, bilginin kaybolmasını engellemek için kara delik olay ufuklarını devasa birer kuantum hata düzeltme kodu olarak kullanıyordu ​Eğer uzay-zamanın dokusunda bu doğal, topolojik kodlama mekanizması olmasaydı, evrensel enformasyon saniyeler içinde gürültüye (decoherence) kurban gider ve bildiğimiz makroskobik gerçeklik çökerdi. Kod sadece bilgisayarlarda yazılmıyor; kara delikler, evrenin kendi tutarlılığını korumak için kullandığı en radikal hata düzeltme düğümleridir (nodes). ​#TheoreticalPhysics #BlackHoles #QuantumErrorCorrection #QuantumInformation #Cosmology #TheLogos

📢 RA 𝐎𝐩𝐩𝐨𝐫𝐭𝐮𝐧𝐢𝐭𝐲 𝐚𝐭 𝐈𝐈𝐓 (𝐈𝐒𝐌) 𝐃𝐡𝐚𝐧𝐛𝐚𝐝 Applications are invited for a Research Associate-I (Postdoctoral) position under an Anusandhan National Research Foundation (ANRF)-ARG sponsored project at the the Department of Physics, IIT (ISM) Dhanbad) 🔬 Project Title: Strong Correlation, Entanglement and Complexity in Topological and Flat Band Systems: A GPU Accelerated Approach The project focuses on cutting-edge problems in: ✔️ Strongly correlated quantum systems ✔️ Topological and flat-band physics ✔️ Quantum information inspired approaches ✔️ GPU-accelerated computational many-body methods ✔️ Entanglement and dynamical mean-field techniques We are looking for motivated researchers with strong background in: • Theoretical/Computational Condensed Matter Physics • Quantum many-body physics • Programming and scientific computing • Strongly correlated or topological systems 💰 Fellowship: ₹58,000/month HRA 📍 Location: Dhanbad, India 📅 Last date to apply: 18 May 2026 Interested candidates should send their CV, research proposal, past research experience, and publication list (single PDF) to: 📧 ra1topology@gmail.com To know more about Prof. Sen's research group visit: sites.google.com/view/sudesh…  #Postdoc #ResearchAssociate #CondensedMatterPhysics #QuantumPhysics #TopologicalPhysics #StronglyCorrelatedSystems #QuantumInformation #GPUComputing #ComputationalPhysics #ANRF #IITISM #PhysicsResearch

📘 𝐍𝐞𝐰 𝐑𝐞𝐥𝐞𝐚𝐬𝐞: 𝘼 𝙍𝙖𝙣𝙙𝙤𝙢 𝙒𝙖𝙡𝙠 𝙏𝙝𝙧𝙤𝙪𝙜𝙝 𝙁𝙞𝙛𝙩𝙮 𝙔𝙚𝙖𝙧𝙨 𝙤𝙛 𝙍𝙮𝙙𝙗𝙚𝙧𝙜 𝙋𝙝𝙮𝙨𝙞𝙘𝙨 F. Barry Dunning (@RiceUniversity) An insightful journey through five decades of Rydberg physics, tracing how a once niche area of atomic physics has evolved into a cornerstone of modern research in quantum science and technology. 🔍 𝐖𝐡𝐲 𝐢𝐬 𝐭𝐡𝐢𝐬 𝐢𝐦𝐩𝐨𝐫𝐭𝐚𝐧𝐭? Rydberg atoms—featuring electrons in highly excited states—exhibit extreme sensitivity and long-range interactions, making them powerful platforms for exploring fundamental processes and enabling breakthroughs in quantum simulation, sensing, and information processing. 📚 𝐖𝐡𝐚𝐭 𝐬𝐞𝐭𝐬 𝐭𝐡𝐢𝐬 𝐛𝐨𝐨𝐤 𝐚𝐩𝐚𝐫𝐭? • Chronicles 50 years of key discoveries and experimental breakthroughs • Explores unique phenomena such as electron–molecule scattering and resonant energy transfer • Highlights the role of Rydberg atoms in quantum electrodynamics and quantum technologies • Connects foundational physics with emerging applications in quantum science 🎯 𝐖𝐡𝐨 𝐬𝐡𝐨𝐮𝐥𝐝 𝐫𝐞𝐚𝐝 𝐭𝐡𝐢𝐬? Advanced undergraduate and graduate students, as well as researchers in atomic physics, quantum optics, and quantum information science. 🔗 𝐄𝐱𝐩𝐥𝐨𝐫𝐞 𝐭𝐡𝐞 𝐛𝐨𝐨𝐤 𝐡𝐞𝐫𝐞: doi.org/10.1142/q0553 #RydbergAtoms #QuantumPhysics #AtomicPhysics #QuantumInformation #QuantumOptics #AMOPhysics

An Editors' Pick via #OPG_JOSA_B: Einstein–Podolsky–Rosen steering based on hexapartite coherent feedback control in four-wave mixing with a spatially structured pump bit.ly/4teXiHq #BeamSplitters #QuantumInformation

📌 #HighlyCitedPaper in Electronics! An Overview of #QuantumCircuit Design Focusing on Compression and Representation 📖 Read the full article here: mdpi.com/2079-9292/14/1/72 #QuantumComputing #ImageProcessing #DataCompression #QuantumInformation

Quantum information science is advancing fast—but meaningful progress still depends on strong theoretical and mathematical foundations. This collection is built for researchers who need more than applied “quantum tech” papers. It provides the rigorous frameworks, methods, and cross-disciplinary insights that underpin real advances in quantum information, many-body physics, and modern quantum theory. 🔬 Why this matters for your research: • Strengthen the theoretical grounding behind your quantum algorithms, models, and experiments • Access mathematically rigorous work that supports high-impact publications and long-term research directions • Connect developments across quantum information, statistical mechanics, and mathematical physics • Stay aligned with foundational research that continues to shape next-generation quantum technologies 📚 Key research areas supported: • Quantum information & computation — algorithms, communication, error correction • Quantum probability & mathematical foundations — rigorous structures for quantum theory • Many-body quantum systems — dynamics, statistical mechanics, complex systems • Optical and quantum materials physics — theoretical frameworks for quantum devices 📖 Included journals: • International Journal of Quantum Information: worldscientific.com/worldsci… • Reviews in Mathematical Physics: worldscientific.com/worldsci… • Infinite Dimensional Analysis, Quantum Probability and Related Topics: worldscientific.com/worldsci… • International Journal of Modern Physics A & B: worldscientific.com/worldsci… / worldscientific.com/worldsci… • Modern Physics Letters A: worldscientific.com/worldsci… • Journal of Nonlinear Optical Physics & Materials: worldscientific.com/worldsci… 📩 Interested in access for your institution? Contact amirah@wspc.com #QuantumScience #QuantumInformation #QuantumComputing #MathematicalPhysics #ManyBodyPhysics #TheoreticalPhysics #ResearchImpact

Language models run on floats, continuous geometry, and billions of learned parameters. What if we used exactly 0 of them? Introducing GeoLLM v6.0: A Cubic p-Adic Spectral Language Model built entirely over the ring Z_13η. zenodo.org/records/19759779 #GeoLLM #MachineLearning #AlgebraicGeometry #DeepLearning #PyTorch #AIResearch #DiscreteMathematics #TensorNetworks #QuantumInformation #LLMs #Algebra

🚨 Atom çekirdeğinde bilgi kontrolü artık mümkün. Bilim insanları, atomun çekirdeğindeki spinleri dış dünya ile minimum etkileşimde tutarak kuantum bilgisini çok daha kararlı ve uzun süre saklayabiliyor. Bu yaklaşım, klasik elektron tabanlı sistemlere göre çok daha az bozulma ve hata oranı sunuyor. Bilgi artık elektron devrelerinde değil, atomun kalbindeki spinlerde depolanıyor. Bu keşif, kuantum bilgi işleme ve gelecekteki bilgisayar teknolojileri için önemli bir yol açıyor. Sizce bilgi, fiziksel dünyanın en temel seviyesinde mi saklanmalı? Yorumlarda düşüncelerinizi paylaşın. ⚛️ #NuclearSpin #QuantumInformation #KuantumBilgi #AtomFiziği #YapayZeka

A tiny detector for microwave photons could advance quantum tech. EPFL researchers have built a tiny device that continuously detects notoriously elusive microwave photons with up to 70% efficiency. By using a "double quantum dot," it opens new doors for quantum sensing & computing. actu.epfl.ch/news/a-tiny-det… #QuantumComputing #QuantumTech #Physics #EPFL #ScienceNews #Twitterscience #QuantumOptics #QuantumInformation #Physics #Innovation #QuantumTech #PhysicsNews #QuantumSensing

The recent industry focus on hardware-accelerated recursive quantum circuits such as recent patent applications for evaluating tensor networks on GPUs highlights a fundamental structural limitation of the current quantum computing architecture. When operating within standard continuous Pauli algebras of SU(2) (rank 2), the lack of complete topological closure forces the system into decoherence. To maintain stability, we rely on computationally intensive external algorithms that use brute-force recursion to track and correct errors. However, recursion need not be an algorithmic correction. In discrete integer geometry of rank 3, such as the (my) SL(3, Z) framework defined by the Tribonacci polynomial, recursion is a native physical structure of the space itself. Because the algebra is strictly closed (the determinant is equal to 1), information is preserved geometrically, rather than through active software monitoring. We are currently spending enormous amounts of hardware resources trying to compute the coherence conditions that a discrete rank 3 lattice provides by definition. Fault tolerance is not an algorithm to be accelerated; it is a geometry to be adopted. #QuantumComputing #FaultTolerance #TopologicalOrder #DiscreteGeometry #MathematicalPhysics #QuantumInformation #ErrorCorrection #TensorNetworks #AlgebraicTopology #Physics