Close Menu
    Facebook X (Twitter) Instagram
    SciTechDaily
    • Biology
    • Chemistry
    • Earth
    • Health
    • Physics
    • Science
    • Space
    • Technology
    Facebook X (Twitter) Pinterest YouTube RSS
    SciTechDaily
    Home»Physics»Physicists Reveal Unified Theory for Fundamental Forces
    Physics

    Physicists Reveal Unified Theory for Fundamental Forces

    By Jim Shelton, Yale UniversityAugust 22, 2017No Comments2 Mins Read
    Facebook Twitter Pinterest Telegram LinkedIn WhatsApp Email Reddit
    Share
    Facebook Twitter LinkedIn Pinterest Telegram Email Reddit

    Yale Researchers Reveal Unified Theory for Fundamental Forces

    New research suggests that the “swimmers” of the natural world — from ships at sea to microorganisms floating through the bloodstream to ubiquitous quantum particles — exert a predictable influence on each other within seemingly chaotic environments.

    Researchers at Yale, Harvard, Oxford, and the Nordic Institute for Theoretical Physics have devised a model for explaining the attraction and repulsion between objects as waves rise and fall around them. The findings, reported on August 15 in the Proceedings of the National Academy of Sciences, suggest a unifying theory for how force is generated in nonequilibrium systems.

    “What we find is that if the spectrum of waves has a particular structure — sharply peaked — then depending on how far apart floating objects are from each other, sometimes they will attract and sometimes they will repel each other,” said senior author John Wettlaufer, the A.M. Bateman Professor of Geophysics, Mathematics, and Physics at Yale.

    “An entire range of things can be explained in this manner, from microscopic to boats. If you give us the spectrum of waves or fluctuations we can tell you what the forces will be between objects,” Wettlaufer said.

    Reference: “Fluctuation spectra and force generation in nonequilibrium systems” by Alpha A. Lee, Dominic Vella and John S. Wettlaufer, 15 August 2017, Proceedings of the National Academy of Sciences.
    DOI: 10.1073/pnas.1701739114

    Abstract: Many biological systems are appropriately viewed as passive inclusions immersed in an active bath: from proteins on active membranes to microscopic swimmers confined by boundaries. The nonequilibrium forces exerted by the active bath on the inclusions or boundaries often regulate function, and such forces may also be exploited in artificial active materials. Nonetheless, the general phenomenology of these active forces remains elusive. We show that the fluctuation spectrum of the active medium, the partitioning of energy as a function of wavenumber, controls the phenomenology of force generation. We find that, for a narrow, unimodal spectrum, the force exerted by a nonequilibrium system on two embedded walls depends on the width and the position of the peak in the fluctuation spectrum, and oscillates between repulsion and attraction as a function of wall separation. We examine two apparently disparate examples: the Maritime Casimir effect and recent simulations of active Brownian particles. A key implication of our work is that important nonequilibrium interactions are encoded within the fluctuation spectrum. In this sense, the noise becomes the signal.

    Never miss a breakthrough: Join the SciTechDaily newsletter.
    Follow us on Google and Google News.

    Harvard University University of Oxford Yale University
    Share. Facebook Twitter Pinterest LinkedIn Email Reddit

    Related Articles

    More Successful Than Ketamine – A Shocking Depression Treatment

    In Einstein’s Footsteps and Beyond: New Insights Into the Foundations of Quantum Mechanics

    Particle Physics Breakthrough: Scientists Report First-of-Its-Kind Neutrino Measurement

    Quantum Computing Breakthrough: Exotic Quantum Particles – Less Magnetic Field Required

    Harvard Scientists Observe Quantum Spin Liquids – A Never-Before-Seen State of Matter

    A Team of Mathematicians and Physicists Discover How Apples Get Their Shapes

    Quantum Melting of Wigner Crystals: Creating a System for Studying Quantum Phase Transitions

    Physicists Develop New Tool for Identifying Phases of Matter

    Electron’s Shape – Rounder than Predicted by Standard Model

    Leave A Reply Cancel Reply

    • Facebook
    • Twitter
    • Pinterest
    • YouTube

    Don't Miss a Discovery

    Subscribe for the Latest in Science & Tech!

    Trending News

    Chimpanzees Keep Throwing Stones at the Same Trees – Scientists Want To Know Why

    Coffee May Protect the Liver in More Ways Than Scientists Realized

    AI Just Uncovered a Hidden Secret Inside Water

    Scientists Catch a “Jumping Gene” Moving Between Species

    This Tiny-Bead Procedure Is Helping Patients Avoid Knee Replacement

    Neanderthals Nearly Vanished 75,000 Years Ago – Then One Group Repopulated Europe

    AI Detects Hidden Warning Signs Before Major Earthquakes

    Scientists Have Found Evidence That Dark Matter May Not Be Playing by the Rules

    Follow SciTechDaily
    • Facebook
    • Twitter
    • YouTube
    • Pinterest
    • Newsletter
    • RSS
    SciTech News
    • Biology News
    • Chemistry News
    • Earth News
    • Health News
    • Physics News
    • Science News
    • Space News
    • Technology News
    Recent Posts
    • 567-Million-Year-Old Fossils Suggest Animals Evolved Earlier Than We Thought
    • Scientists Discover a 5-Million-Year-Old Whale Graveyard Deep Beneath the Indian Ocean
    • Ancient DNA Reveals the Hidden Origins of China’s Mysterious Shimao Civilization
    • Scientists Finally Solve a 50-Year Mystery Hidden in Solid Nitrogen
    • Saturn’s Largest Moon May Hold the Resources for a Space Colony
    Copyright © 1998 - 2026 SciTechDaily. All Rights Reserved.
    • Science News
    • About
    • Contact
    • Editorial Board
    • Privacy Policy
    • Terms of Use

    Type above and press Enter to search. Press Esc to cancel.