Close Menu
    Trending
    • Yankees’ Brian Cashman gives worrisome Aaron Judge injury update
    • Why B2B Customer Experience Needs a New Playbook
    • Special relativity can warp chemical bonds – now we’ve seen it happen
    • When will Andy Burnham become Prime Minister?
    • Market Talk – July 9, 2026
    • Inside The Drunken Night That Sparked Row Among Spice Girls
    • US Senate candidate’s implosion forces Democratic reckoning
    • Is Syria stable enough to engage with the world? | Syria’s War News
    Benjamin Franklin Institute
    Thursday, July 9
    • Home
    • Politics
    • Business
    • Science
    • Technology
    • Arts & Entertainment
    • International
    Benjamin Franklin Institute
    Home»Science»One scientist’s 10-year quest to calculate the strength of gravity
    Science

    One scientist’s 10-year quest to calculate the strength of gravity

    Team_Benjamin Franklin InstituteBy Team_Benjamin Franklin InstituteApril 25, 2026No Comments6 Mins Read
    Share Facebook Twitter Pinterest Copy Link LinkedIn Tumblr Email VKontakte Telegram
    Share
    Facebook Twitter Pinterest Email Copy Link


    April 24, 2026

    4 min read

    Add Us On GoogleAdd SciAm

    One scientist’s 10-year quest to calculate the strength of gravity

    Earth’s gravitational force, g, has been known for centuries. But the exact value of G, the universal gravitational constant, is elusive

    By Emma Gometz edited by Clara Moskowitz

    Two men wearing goggles leaning over a table looking at a torsion balance machine

    NIST scientists Stephan Schlamminger (left) and Vincent Lee examine the torsion balance they used to measure the gravitational constant, big G, a decade-long undertaking.

    After 10 years of painstaking measurements, physicist Stephan Schlamminger stood in a hotel water park, waiting for a career-defining moment. His new measurement of the gravitational constant, or G, one of the most fundamental values in physics, was going to be revealed to his peers that afternoon. Hours before his talk, he took refuge amid the chlorine.

    “I was so stressed out,” he says. “I almost wanted to cancel it.”

    Just as Earth’s gravity pulls baseballs to the ground after they are thrown, all masses exert a gravitational force on other masses. But measuring the constant that determines the strength of that force is tricky, even for experienced scientists. On April 16 Schlamminger published a new measurement of G, adding another data point in the quest to determine its exact value.


    On supporting science journalism

    If you’re enjoying this article, consider supporting our award-winning journalism by subscribing. By purchasing a subscription you are helping to ensure the future of impactful stories about the discoveries and ideas shaping our world today.


    According to Isaac Newton’s law of universal gravitation, the gravitational force between two objects is the gravitational constant, G, multiplied by the product of the two masses divided by the square of the distance between them. In an equation, that looks like F = G(m1m2)/ r2.

    The force of Earth’s gravitational pull, which can be found using this equation, is known as “little g.” Scientists have measured this constant to a high degree of precision with little disagreement: g = 9.80665 meters per second squared, or 9.80665 m/s2 at Earth’s surface. But “big G” is different. It’s the gravitational constant that is the same for all objects, no matter how massive. Previous measurements of G look like a scatter plot when they’re put together on a chart—the value still has a pretty large degree of uncertainty, Schlamminger says. That’s because it’s a very weak force, and isolating it is very difficult, even for our most cutting-edge instruments.

    “G is kind of special,” Schlamminger says. “It’s like the lady clad in red velvet, it’s always wrapped in scandal.”

    Schlamminger’s team repeated methods from a 2014 study from the International Bureau of Weights and Measurements (BIPM) and hoped for the same result. The measuring tool the researchers used in the new study is called a torsion balance, which is a modern update on a centuries-old method pioneered in the so-called Cavendish experiment. That experiment was originally designed to determine the density of the Earth. In it, a thin wooden beam with two lead balls on its ends was suspended from a wire at its center and then a structure that had heavier lead balls and was otherwise identical was stacked on top of the first beam. The result looked something like a weathervane. Instead of wind pushing the lead balls around, however, their mutual gravitational attraction caused them to twist toward one another. When they twisted, the angle of the beam balancing the small weights could be used to calculate the value of G.

    Schlamminger’s version, which took place at the National Institute of Standards and Technology’s facilities in Gaithersburg, Md., used the exact same instrument and procedure as the 2014 BIPM setup. (BIPM sent it to NIST in 2016.) Researchers placed the masses on flat platelike objects called torsion disks, with the lighter masses on the inside suspended by a thin copper beryllium strip and the heavier masses located on a separate disk on the outside. Then they placed the whole apparatus inside a vacuum chamber. The arrangement was also a replication of the 2014 BIPM methods, but the team made some updates to it. For example, the scientists repeated the experiment with both copper and sapphire masses to eliminate effects from the type of material being used; replaced the apparatus’s torsion disk so the top and bottom were perfectly parallel; and rewrote the software suite for the device to improve instrument control.

    A GIF of a torsion balance moving

    Setup at NIST for measuring the strength of gravity.

    The final number they calculated for G, 6.67387 × 10–11m3kg–1s–2, was lower than both the BIPM measurement and the internationally agreed-upon standard from the Committee on Data of the International Science Council (CODATA), which had been determined from a group of the best measurements taken so far. The result suggests that we still don’t know G as precisely as we’d like. “I think it’s always worth having one more measurement,” says Terry Quinn, former director of the BIPM and first author of the 2014 measurement study. But for most purposes, the CODATA consensus for G “is as good as we need at the moment,” he adds.

    Measuring G is useful because it tests the quality of precision measurement instruments. The minor discrepancies among measurements may even point toward a yet-unknown mystery of physics, Schlamminger says. But the value itself, he admits, doesn’t have much practical use. Trying to determine the exact value of G is exciting for its own sake.

    “I love taking measurements. Measurement science is my passion,” Schlamminger says. “I know it’s difficult to understand for many people, but it is. It can be exciting and very fulfilling.”

    It’s Time to Stand Up for Science

    If you enjoyed this article, I’d like to ask for your support. Scientific American has served as an advocate for science and industry for 180 years, and right now may be the most critical moment in that two-century history.

    I’ve been a Scientific American subscriber since I was 12 years old, and it helped shape the way I look at the world. SciAm always educates and delights me, and inspires a sense of awe for our vast, beautiful universe. I hope it does that for you, too.

    If you subscribe to Scientific American, you help ensure that our coverage is centered on meaningful research and discovery; that we have the resources to report on the decisions that threaten labs across the U.S.; and that we support both budding and working scientists at a time when the value of science itself too often goes unrecognized.

    In return, you get essential news, captivating podcasts, brilliant infographics, can’t-miss newsletters, must-watch videos, challenging games, and the science world’s best writing and reporting. You can even gift someone a subscription.

    There has never been a more important time for us to stand up and show why science matters. I hope you’ll support us in that mission.



    Source link

    Share. Facebook Twitter Pinterest LinkedIn Tumblr Email Telegram Copy Link

    Related Posts

    Science

    Special relativity can warp chemical bonds – now we’ve seen it happen

    July 9, 2026
    Science

    Resuscitated human retinas respond to light 10 hours after death

    July 9, 2026
    Science

    A worm that lived half a billion years ago preferred turning right

    July 9, 2026
    Science

    The 4 best science-fiction shows of 2026 so far

    July 9, 2026
    Science

    A surprisingly detailed look at the physics of a lugworm’s poop

    July 9, 2026
    Science

    The allergy culprit histamine also boosts our memory

    July 9, 2026
    Editors Picks

    Remote-controlled cockroach swarm can now breathe underwater

    June 29, 2026

    Assailant convicted after Barron Trump calls London police to report crime he saw on video

    January 28, 2026

    Iran says ‘non-hostile’ ships can pass safely through Strait of Hormuz | US-Israel war on Iran News

    March 25, 2026

    Melissa Gilbert Defends Timothy Busfield In Interview

    April 2, 2026

    How your health is being commodified by social media

    January 30, 2026
    About Us
    About Us

    Welcome to Benjamin Franklin Institute, your premier destination for insightful, engaging, and diverse Political News and Opinions.

    The Benjamin Franklin Institute supports free speech, the U.S. Constitution and political candidates and organizations that promote and protect both of these important features of the American Experiment.

    We are passionate about delivering high-quality, accurate, and engaging content that resonates with our readers. Sign up for our text alerts and email newsletter to stay informed.

    Latest Posts

    Yankees’ Brian Cashman gives worrisome Aaron Judge injury update

    July 9, 2026

    Why B2B Customer Experience Needs a New Playbook

    July 9, 2026

    Special relativity can warp chemical bonds – now we’ve seen it happen

    July 9, 2026

    Subscribe for Updates

    Stay informed by signing up for our free news alerts.

    Paid for by the Benjamin Franklin Institute. Not authorized by any candidate or candidate’s committee.
    • Privacy Policy
    • About us
    • Contact us

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