Lithium nickel oxide (LiNiO2) has emerged as a potential new material to power next-generation, longer-lasting lithium-ion batteries. Commercialization of the material, however, has stalled because it degrades after repeated charging.
University of Texas at Dallas researchers have discovered why LiNiO2 batteries break down, and they are testing a solution that could remove a key barrier to widespread use of the material. They published their findings in the journal Advanced Energy Materials.
The team plans first to manufacture LiNiO2 batteries in the lab and ultimately to work with an industry partner to commercialize the technology.
A new understanding of our relationship with our ‘friendly’ gut microbes shows they actually have a dark side and help cause ageing. Here’s how to fight back.
AI, Deep Dive, spacetime inertia, unified energy framework, gravity, dark matter, dark energy, black holes, emergent gravity, energy inertia, mass-energy interactions, missing mass problem, cosmic expansion, event horizon mechanics, Einstein’s General Relativity, spacetime curvature, galactic rotation curves, quantum field theory, spacetime as energy, energy resistance, inertial effects, graviton alternative, energy density distribution, inverse-square law, gravitational lensing, galactic halos, high-energy cosmic regions, X-ray emissions, electromagnetic fields, cosmological constant, accelerating universe, large-scale inertia, spacetime resistance, event horizon physics, singularity alternatives, James Webb Space Telescope, early galaxy formation, modified gravity, inertia-driven cosmic expansion, energy saturation point, observational cosmology, new physics, alternative gravity models, astrophysical testing, theoretical physics, unification of forces, experimental validation, fundamental physics revolution, black hole structure, cosmic energy fields, energy gradient effects, resistance in spacetime, extreme energy zones, black hole event horizons, quantum gravity, astrophysical predictions, future space observations, high-energy astrophysics, cosmic structure formation, inertia-based galaxy evolution, spacetime fluid dynamics, reinterpreting physics, mass-energy equivalence.
Description: In this deep dive into the nature of gravity, dark matter, and dark energy, we explore a groundbreaking hypothesis that could revolutionize our understanding of the universe. What if gravity is not a fundamental force but an emergent property of spacetime inertia? This novel framework, proposed by Dave Champagne, reinterprets the role of energy and inertia within the fabric of the cosmos, suggesting that mass-energy interactions alone can account for gravitational effects—eliminating the need for exotic matter or hypothetical dark energy forces.
We begin by examining the historical context of gravity, from Newton’s classical mechanics to Einstein’s General Relativity. While these theories describe gravitational effects with incredible accuracy, they still leave major mysteries unsolved, such as the unexplained motions of galaxies and the accelerating expansion of the universe. Traditionally, these anomalies have been attributed to dark matter and dark energy—hypothetical substances that have yet to be directly observed. But what if there’s another explanation?
Quantum computing is an alternative computing paradigm that exploits the principles of quantum mechanics to enable intrinsic and massive parallelism in computation. This potential quantum advantage could have significant implications for the design of future computational intelligence systems, where the increasing availability of data will necessitate ever-increasing computational power. However, in the current NISQ (Noisy Intermediate-Scale Quantum) era, quantum computers face limitations in qubit quality, coherence, and gate fidelity. Computational intelligence can play a crucial role in optimizing and mitigating these limitations by enhancing error correction, guiding quantum circuit design, and developing hybrid classical-quantum algorithms that maximize the performance of NISQ devices. This webinar aims to explore the intersection of quantum computing and computational intelligence, focusing on efficient strategies for using NISQ-era devices in the design of quantum-based computational intelligence systems.
Speaker Biography: Prof. Giovanni Acampora is a Professor of Artificial Intelligence and Quantum Computing at the Department of Physics “Ettore Pancini,” University of Naples Federico II, Italy. He earned his M.Sc. (cum laude) and Ph.D. in Computer Science from the University of Salerno. His research focuses on computational intelligence and quantum computing. He is Chair of the IEEE-SA 1855 Working Group, Founder and Editor-in-Chief of Quantum Machine Intelligence. Acampora has received multiple awards, including the IEEE-SA Emerging Technology Award, IBM Quantum Experience Award and Fujitsu Quantum Challenge Award for his contributions to computational intelligence and quantum AI.
0:00 Largest superstructure in the universe — Quipu. 0:45 Laniakea discovery of 2014 1:25 Shapley concentration. 2:35 Cosmological issues: Hubble Tension and S8 tension. 3:45 New study mapping galaxies and the discovery. 5:15 Additional findings and implications. 6:25 What is this though? 7:20 Confirming predictions and how this was found. 8:40 What’s next?
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🚀 Scientists have confirmed a super-Earth in the habitable zone! HD 20,794D, located just 20 light-years away, could have liquid water, making it a prime candidate for life. But its elliptical orbit raises big questions—could life survive its extreme temperature swings? 🌍 With future telescopes set to analyze its atmosphere, we may be on the verge of a historic discovery. Watch now to explore what makes HD 20,794D so special! Subscribe for more space discoveries! 🌌✨
Paper link: https://www.aanda.org/articles/aa/ful… 00:00 Introduction 00:41 Discovery and Confirmation Process 02:13 Characteristics of HD 20,794D 04:43 Implications for Habitability and Future Research 08:38 Outro 09:07 Enjoy MUSIC TITLE : Starlight Harmonies MUSIC LINK : https://pixabay.com/music/pulses-star… Visit our website for up-to-the-minute updates: www.nasaspacenews.com Follow us Facebook: / nasaspacenews Twitter: / spacenewsnasa Join this channel to get access to these perks: / @nasaspacenewsagency #NSN #NASA #Astronomy#HD20794D #Exoplanet #SuperEarth #NASA #SpaceExploration #AlienLife #HabitableZone #EarthLikePlanet #Astronomy #Astrobiology #LifeOnOtherPlanets #ExoplanetDiscovery #SpaceNews #AstronomyLovers #Telescope #PlanetHunting #NewEarth #DeepSpace #JWST #HabitableExoplanets #ScienceNews #FutureOfSpace #NASAUpdates #ExtremePlanets #SpaceFacts #AstronomyCommunity #SpaceTech #SolarSystem #GalaxiesBeyond #AlienWorld.
Chapters: 00:00 Introduction. 00:41 Discovery and Confirmation Process. 02:13 Characteristics of HD 20,794D. 04:43 Implications for Habitability and Future Research. 08:38 Outro. 09:07 Enjoy.
Quantum physics, space documentary, and the fabric of reality—these are not just abstract ideas but the keys to unlocking the mysteries of existence. What is reality? Is it an illusion, a simulation, or something far beyond our comprehension? In this mind-expanding documentary, we explore the very fabric of the universe, from the bizarre behavior of quantum mechanics to the cosmic forces shaping space and time.
The universe is a grand puzzle, and science has only begun to unravel its secrets. Quantum physics reveals a world where particles exist in multiple states at once, where time behaves unpredictably, and where observation itself shapes reality. But how does this strange quantum realm connect to the vast expanse of space? Is the fabric of reality woven with unseen forces that govern everything, from black holes to the flow of time itself?
This space documentary takes you on a journey through the cutting-edge theories that challenge our understanding of the cosmos. Could our universe be a hologram? Is time an illusion? Do parallel realities exist beyond our perception? With stunning visuals, expert insights, and mind-bending concepts, we push the boundaries of what we know about existence.
🔔 Subscribe for more deep-space documentaries and quantum mysteries!
Euclid, a space telescope on a mission to uncover the secrets of dark matter and dark energy, has already made a stunning discovery: a perfectly formed Einstein ring hidden in a well-known galaxy.
This rare phenomenon, predicted by Einstein’s theory of relativity, reveals the power of gravitational lensing, allowing scientists to glimpse far-off galaxies otherwise invisible. The find is a testament to Euclid’s groundbreaking capabilities, suggesting a future filled with even more cosmic surprises.
