Researchers are tackling the computational burden of simulating left ventricular (LV) mechanics, a crucial aspect of understanding cardiac function and planning interventions. Siyu Mu, Wei Xuan Chan, and Choon Hwai Yap, all from the Department of Bioengineering at Imperial College London, alongside et al., have developed CardioGraphFENet, a novel graph-based surrogate model that rapidly estimates full-cycle LV myocardial biomechanics. This work represents a significant advance because existing graph surrogates lack full-cycle prediction, and physics-informed methods often fail with complex heart shapes. By integrating a global-local graph encoder, a temporal encoder, and a cycle-consistent bidirectional formulation, CardioGraphFENet achieves high fidelity to traditional finite-element analysis while requiring substantially less computational power and supervisory data. Conventional finite-element analysis, while valuable for understanding cardiac function and planning clinical interventions, is computationally demanding and limits patient-specific modelling. Current graph-based surrogates lack full-cycle prediction capabilities, and physics-informed neural networks often struggle with the complexities of cardiac geometries. This new framework addresses these limitations by integrating a global-local graph encoder, a gated recurrent unit-based temporal encoder, and a cycle-consistent bidirectional formulation. The research team’s approach leverages a large dataset of finite-element analysis simulations to train the model, enabling high-fidelity predictions that align with traditional FEA ground truths. CGFENet captures mesh features using weak-form-inspired global coupling and models cycle-coherent dynamics conditioned on the target volume-time signal. Crucially, the cycle-consistency strategy significantly reduces the need for extensive FEA supervision while maintaining accuracy. This allows for efficient and reliable estimation of myocardial biomechanics across div

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f left ventricular finite element analysis data A 72-qubit superconducting...

Heart Simulations Now Run Rapidly Thanks to New AI-Powered Modelling Technique

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Scientists have investigated shear mode transport coefficients arising from gravitational perturbations around anti-de Sitter black branes, revealing a surprising connection to multiple polylogarithms. Paolo Arnaudo from the University of Southampton, alongside colleagues, detail an analytical study extending previous work to higher orders and dimensions. Their calculations, performed within a five-dimensional black hole background up to order, characterise the mathematical structure of these transport coefficients and provide a more complete understanding of strongly coupled systems like Super Yang-Mills theory. This research significantly advances the field by offering a robust framework for analysing transport phenomena in these complex gravitational settings. Holographic calculation of shear viscosity in strongly coupled gauge theories Scientists have achieved a significant advance in understanding the behaviour of strongly coupled quantum field theories through detailed analysis of gravitational perturbations. This work presents an analytical study of transport coefficients associated with shear forces around black branes in anti-de Sitter space, revealing a mathematical structure fully described by multiple polylogarithms. Researchers focused on computing these transport coefficients for N = 4 super Yang-Mills theory, extending previous results to order q10 in a five-dimensional black hole background. The study not only refines calculations within this established framework but also generalises the procedure to d + 1 dimensions, characterising the mathematical form of the resulting transport coefficient expressions. This breakthrough builds upon the holographic duality, a concept linking gravity and quantum field theory, to probe the non-equilibrium dynamics of strongly interacting systems. By examining gravitational perturbations around black brane backgrounds, the research decodes the dissipative and hydrodynamic responses of the boundary theory. The solutio

lylogarithmic Expansion in Anti-de Sitter Space A 72-qubit superconducting processor...

Black Hole Maths Unlocks Secrets of How Energy Flows in Exotic Matter

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Scientists are increasingly exploring variational quantum eigensolvers as practical approaches to prepare ground states, but their potential for quantum advantage remains unclear. Baptiste Anselme Martin from Eviden Quantum Lab and Thomas Ayral from CPHT, CNRS, Ecole Polytechnique, IP Paris, alongside et al., demonstrate a novel method utilising differentiable 2D tensor networks to optimise parameterised circuits for the transverse field Ising model. This research is significant because it enables the preparation of highly accurate ground states for systems exceeding one dimension and crucially, mitigates the detrimental barren plateau issue by identifying enhanced gradient zones that maintain performance as system size increases. By evaluating the classical simulation cost at these optimised starting points, the team delineate regimes where quantum hardware may ultimately outperform tensor network simulations. Tensor network pre-optimisation overcomes barren plateaus in variational quantum circuits by improving initial parameterisation Researchers are pioneering a new approach to harness the power of quantum computing by integrating classical tensor network algorithms with parameterized quantum circuits. This work details the use of differentiable two-dimensional tensor networks to optimize circuits designed to prepare the ground state of the transverse field Ising model, achieving high energy accuracy even for complex systems exceeding one-dimensional limitations. The study demonstrates that pre-optimization using tensor networks effectively mitigates the barren plateau issue, a significant obstacle in quantum computation, by unlocking enhanced gradient zones that maintain their size even as system complexity increases. Specifically, the research focuses on optimizing quantum circuits using projected entangled pair states, a type of two-dimensional tensor network, combined with automatic differentiation techniques. This method allows for the efficient preparation 

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Quantum Computers Sidestep Major Flaw, Paving Way for Larger, More Accurate Calculations

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Researchers are actively pursuing higher-order topological superconductivity as a pathway to creating stable and manipulable Majorana networks, circumventing the limitations of vortex-based approaches. Yongting Shi from the Institute of Applied Physics and Computational Mathematics, Qing Wang from the Anhui Provincial Key Laboratory of Low-Energy Quantum Materials and Devices, and Zhen-Guo Fu et al. demonstrate a symmetry-protected realisation of this phenomenon within a MnXPb (X=Se, Te)-Pb heterostructure. Their work reveals that the unique boundary properties of antiferromagnetic topological insulators naturally give rise to Majorana corner modes at the interfaces between superconducting and magnetic regions. Combining first-principles calculations with theoretical modelling, the team show robust corner localisation and, crucially, the potential for purely electrical control over Majorana fusion and braiding in a two-dimensional triangular geometry, establishing MnXPb as a promising platform for future quantum computation. This breakthrough centers on manipulating Majorana zero modes, exotic quasiparticles considered prime candidates for building stable and scalable quantum bits. Unlike existing approaches that often rely on complex structures involving vortices or magnetic fields, this work demonstrates a route to engineer Majorana modes localized at the corners of two-dimensional materials, offering a simpler and more controllable architecture. Researchers propose utilizing heterostructures composed of antiferromagnetic topological insulators, specifically, monolayer MnXPb2 (where X represents selenium or tellurium) combined with lead, to achieve this unique state. The core of this discovery lies in the intrinsic boundary properties of these antiferromagnetic topological insulators. These materials exhibit a dichotomy at their edges, possessing gapless Dirac states protected by time-reversal symmetry on antiferromagnetic boundaries and magnetic gaps on ferromagn

New Material Hosts ‘Majorana’ Particles for Robust Quantum Computing Networks

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Lyft Misses on Profit Outlook, Posts Surprise Operating Loss

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The FBI raid of a Fulton County, Georgia, election center generated controversy because of the presence of Trump national intelligence director Tulsi Gabbard.

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Former Trump campaign lawyer sparked FBI probe of Fulton County ballots: Affidavit

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NOT FOR DISTRIBUTION TO U.S. NEWSWIRE SERVICES OR FOR DISSEMINATION IN THE UNITED STATES OF AMERICA Allied’s base shelf prospectus, and the shelf prospectus supplement for the public offering, will be accessible, within two business days, through SEDAR+ Completes succession plan; Michael Emory to conclude term as Executive Chair Announces Q4 2025 and year-end results […]

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Allied Reports Q4 and Full-Year Results; Announces Leadership Update and Equity Financing

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Google handed over a trove of personal data about a student and journalist to U.S. Immigration and Customs Enforcement in response to a subpoena that had not been approved by a judge, according to a report by The Intercept.&nbsp; The search and advertising tech giant provided ICE with the usernames, physical addresses, and an itemized list of services associated with the Google account of Amandla Thomas-Johnson, a British student and journalist who briefly attended a pro-Palestinian protest in 2024 while attending Cornell University in New York.&nbsp; Google also turned over Thomas-Johnson’s IP addresses, phone numbers, subscriber numbers and identities, and credit card and bank account numbers linked to his account.&nbsp; The subpoena, which reportedly included a gag order, did not include a specific justification for why ICE was requesting Thomas-Johnson’s personal data, but the student previously said that the demand for his data came within two hours of Cornell informing him that the U.S. government had revoked his student visa.&nbsp; This is the latest example of how the U.S. government is using a controversial type of legal request, called an administrative subpoena, to demand that tech companies turn over the private data of individuals who have been critical of the Trump administration. This has included anonymous Instagram accounts that share information about ICE presence and raids, as well as people who criticize or protest Trump and his policies. ICE and Google did not immediately respond to a request for comment.&nbsp;&nbsp; Administrative subpoenas are issued directly by federal agencies without the intervention of a judge. These legal demands cannot compel companies to turn over the contents of a person’s email accounts, online searches, or location data, but can request metadata and other identifiable information, such as email addresses, in an attempt to de-anonymize the owner of a certain online account.&nbsp; Techcrunch event TechCrunch Founder Su

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Google sent personal and financial information of student journalist to ICE

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Commonwealth Bank Profit Tops Estimates on Business Loans

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Bond Dealers Push Up Private Credit Fund Trading Costs Amid Software Slide

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Monday night, xAI co-founder Yuhuai (Tony) Wu announced he was leaving the company. “It’s time for my next chapter,” Wu wrote in a late-night post on X. “It is an era with full possibilities: a small team armed with AIs can move mountains and redefine what’s possible.” On its own, it’s a pretty standard tech departure announcement — but it’s part of a troubling pattern for the lab. Five members of the company’s 12-person founding team have now left the company, with four of the departures coming in just the last year. Infrastructure lead Kyle Kosic left for OpenAI in mid-2024, followed by Google veteran Christian Szegedy in February 2025. This past August, Igor Babushkin left to found a venture firm, and Microsoft alum Greg Yang departed just last month, citing health issues. By all accounts, the splits have all been amicable, and there are lots of reasons why, nearly three years in, some founders might decide to move on. Elon Musk is a notoriously demanding boss, and with the SpaceX’s acquisition of xAI complete and an IPO pending in the coming months, everyone involved has a pretty big windfall coming. It’s a great time to be fundraising for an AI startup, so it’s only natural for high-level researchers to want to strike out on their own. There are also less amicable reasons that might factor in. The company’s flagship product, the Grok chatbot, has struggled with bizarre behavior and apparent internal tampering — the kind of thing that might easily create friction on the technical team. Then there were the recent changes to xAI’s image-generation tools that flooded the platform with deepfake pornography, sparking slow-moving but real legal consequences. Whatever the cause, the cumulative impact is alarming. There is a lot of work left to do at xAI, and an IPO will bring more scrutiny than the lab has ever faced before. With Musk already spinning up plans for orbital data centers, the pressure to make good on those plans will be intense. The pace of model developm

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Heart Simulations Now Run Rapidly Thanks to New AI-Powered Modelling Technique

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Black Hole Maths Unlocks Secrets of How Energy Flows in Exotic Matter

Quantum Computers Sidestep Major Flaw, Paving Way for Larger, More Accurate Calculations

New Material Hosts ‘Majorana’ Particles for Robust Quantum Computing Networks

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Heart Simulations Now Run Rapidly Thanks to New AI-Powered Modelling Technique

Black Hole Maths Unlocks Secrets of How Energy Flows in Exotic Matter

Quantum Computers Sidestep Major Flaw, Paving Way for Larger, More Accurate Calculations

New Material Hosts ‘Majorana’ Particles for Robust Quantum Computing Networks

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