Close Menu
    Facebook X (Twitter) Instagram
    SciTechDaily
    • Biology
    • Chemistry
    • Earth
    • Health
    • Physics
    • Science
    • Space
    • Technology
    Facebook X (Twitter) Pinterest YouTube RSS
    SciTechDaily
    Home»Physics»Electrons Stand Still As Scientists Rewrite Molecular Rules
    Physics

    Electrons Stand Still As Scientists Rewrite Molecular Rules

    By University of CambridgeMay 20, 20241 Comment3 Mins Read
    Facebook Twitter Pinterest Telegram LinkedIn WhatsApp Email Reddit
    Share
    Facebook Twitter LinkedIn Pinterest Telegram Email Reddit
    Molecules Atoms Vibration Motion
    Researchers have developed new guidelines for molecular design that prevent electrons from losing energy through atomic vibrations. These innovations promise to revolutionize the effectiveness of organic molecules used in OLEDs, sensors, and biomedical imaging. Credit: SciTechDaily.com

    New molecular design rules discovered through laser-based spectroscopic techniques enable the uncoupling of electrons from atomic vibrations, leading to significantly improved performance in applications such as OLEDs and biomedical imaging.

    Since the discovery of quantum mechanics more than a hundred years ago, it has been known that electrons in molecules can be coupled to the motion of the atoms that make up the molecules. Often referred to as molecular vibrations, the motion of atoms act like tiny springs, undergoing periodic motion.

    For electrons in these systems, being joined to the hip with these vibrations means they are constantly in motion too, dancing to the tune of the atoms, on timescales of a millionth of a billionth of a second. But all this dancing around leads to a loss of energy and limits the performance of organic molecules in applications like light-emitting diodes (OLEDs), infrared sensors, and fluorescent biomarkers used in the study of cells and for tagging diseases such as cancer cells.

    Breakthrough in Molecular Design

    Now, researchers using laser-based spectroscopic techniques have discovered ‘new molecular design rules’ capable of halting this molecular dance. Their results, reported in Nature, revealed crucial design principles that can stop the coupling of electrons to atomic vibrations, in effect shutting down their hectic dancing and propelling the molecules to achieve unparalleled performance.

    Organic Molecules Light Emission Property Modulated by Quantum Dance
    Artist’s illustration of an organic molecules light emission property modulated by quantum dance of the atoms. Credit: Pratyush Ghosh, Cavendish Laboratory, University of Cambridge, edited

    “All organic molecules, such as those found in living cells or within the screen of your phone consist of carbon atoms connected to each other via a chemical bond,” said Cavendish PhD student Pratyush Ghosh, first author of the study and member of St John’s College.

    “Those chemical bonds are like tiny vibrating springs, which are generally felt by electrons, impairing the performance of molecules and devices. However, we have now found that certain molecules can avoid these detrimental effects when we restrict the geometric and electronic structure of the molecule to some special configurations.”

    To demonstrate these design principles, the scientists designed a series of efficient near-infrared emitting (680-800 nm) molecules. In these molecules, energy losses resulting from vibrations—essentially, electrons dancing to the tune of atoms —were more than 100 times lower than in previous organic molecules.

    This understanding and development of new rules to design light emitting molecules has opened an extremely interesting trajectory for the future, where these fundamental observations can be applied to industries.

    Potential Applications and Future Directions

    “These molecules also have a wide range of applications today. The task now is to translate our discovery to make better technologies, from enhanced displays to improved molecules for bio-medical imaging and disease detection,” concluded Professor Akshay Rao from Cavendish Laboratory, who led this research.

    Reference: “Decoupling excitons from high-frequency vibrations in organic molecules” by Pratyush Ghosh, Antonios M. Alvertis, Rituparno Chowdhury, Petri Murto, Alexander J. Gillett, Shengzhi Dong, Alexander J. Sneyd, Hwan-Hee Cho, Emrys W. Evans, Bartomeu Monserrat, Feng Li, Christoph Schnedermann, Hugo Bronstein, Richard H. Friend and Akshay Rao, 8 May 2024, Nature.
    DOI: 10.1038/s41586-024-07246-x

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

    OLED Optics Quantum Mechanics Quantum Optics University of Cambridge
    Share. Facebook Twitter Pinterest LinkedIn Email Reddit

    Related Articles

    Scientists Create “Optical Tornadoes” That Twist Light Into a Swirling Vortex

    Quantum Squeezing Unlocks Lightning-Fast Gas Sensors

    How Terahertz Pulses Are Unraveling the Mysteries of Superconductors

    Evading Heisenberg’s Uncertainty Principle Isn’t Easy

    World’s Most Efficient Single-Photon Source Created Using Time Multiplexing

    Scientists Generate the Fastest Electric Current Ever Measured Inside a Solid Material

    Researchers Develop A Universal Quantum Gate

    Physicists Test the Response Time of Electrons

    Physicists Measure Photons in an Entangled NOON State

    1 Comment

    1. Jojo on May 21, 2024 1:15 am

      Amazing! Who or whatever defined all the atomic particles, the rules for their interactions, connections, operatiron, etc. sure was smart!~

      Reply
    Leave A Reply Cancel Reply

    • Facebook
    • Twitter
    • Pinterest
    • YouTube

    Don't Miss a Discovery

    Subscribe for the Latest in Science & Tech!

    Trending News

    Textbooks May Need Rewriting After Researchers Debunk a Core Chemistry Concept

    Alzheimer’s May Start With a Surprising Symptom – Not Memory Loss

    The “Hobbits” Mysteriously Disappeared 50,000 Years Ago – Scientists Have Revealed What Happened to Their Home

    One Sugar Tells Your Brain You’re Full. Another Barely Does

    One of Arizona’s Largest Reservoirs Is Less Than 1% Full After Snowpack Collapse

    This 400-Year-Old Shark May Hold the Secret to Preserving Human Vision

    Your Daily Orange Juice Could Have an Unexpected Health Benefit

    Black Hole Shredded a Massive Star in the Most Powerful Stellar Explosion Ever Seen

    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
    • Rare Iridescent Optical Effect Discovered in a Famous Australian Frog
    • Urban Rodents Are Evolving To Survive Common Poisons
    • Scientists Just Challenged a 70-Year-Old Myth About the Human Brain
    • The Strange Force That Could Slow Interstellar Solar Sails
    • Microscope Breakthrough Could Reveal Proteins Once Thought Too Small To See
    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.