Tag Archives: Ligo

TACNY Junior Cafe Scientifique: “Exploring The Most Extreme Corners Of The Universe”

Posted on February 9, 2019 1:24 pm - - Leave a Comment

Saturday – February 16, 2019, 9:30-11:00am

Milton J Rubenstein Museum of Science & Technology – Syracuse, NY

Please RSVP to jrcafe@tacny.org

Speaker: Stefan W. Ballmer, PhD, Associate Professor of Physics, Syracuse University

Talk Overview: Come along on a journey to explore the most extreme corners of the universe. We will encounter places where every-day geometry stops working and the time stands still. We will witness black holes and neutron stars on collision courses, smashing into each other at half the speed of light, producing some of the biggest known explosions in the universe. And I will take you behind the curtains of a brand-new, one-of-a-kind astronomical observatory: The Advanced Laser Gravitational-Wave Interferometer, a machine capable of measuring the vibrations in the fabric of space and time. 

BiographyStefan Ballmer, associate professor of physics at Syracuse University, is an authority on gravitational-wave detector technology. He has logged thousands of hours at the LIGO Hanford Observatory in Richland, Washington putting together the Advanced LIGO interferometer. He was a member of Advanced LIGO’s design team and is now designing the next generation of gravitational-wave detectors. Rounding out his contributions to LIGO’s Nobel Prize-winning work have been an NSF CAREER Award at Syracuse, Visiting Associate Professor positions at the University of Tokyo, a Robert A. Millikan Fellowship at Caltech; and a postdoctoral fellowship from the Japan Society for the Promotion of Science, underwriting research at the National Astronomical Observatory of Japan. Ballmer earned a Ph.D. from MIT in the group Rai Weiss and a Master’s degree from ETH Zurich in Switzerland. In his spare time, he is also a pilot and flight instructor in the local Syracuse Flying Club, exploring the 3rd dimension here on earth.

TACNY Junior Cafe Scientifique

TACNY Junior Cafe Scientifique, a program for middle-school students founded in 2005, features discussions about topics in the fields of science, technology, engineering and mathematics in an informal atmosphere and seeks to encourage students to consider careers in these areas. Students must be accompanied by an adult and can explore the MOST at no cost after the event.

Technology Alliance of Central New York

Founded in 1903 as the Technology Club of Syracuse, the nonprofit Technology Alliance of Central New York’s mission is to facilitate community awareness, appreciation, and education of technology; and to collaborate with like-minded organizations across Central New York.

For more information about TACNY, visit www.tacny.org.


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NASA Space Place – Gravitational Wave Astronomy Will Be The Next Great Scientific Frontier

Posted on March 22, 2016 8:59 am - - Leave a Comment

Poster’s Note: One of the many under-appreciated aspects of NASA is the extent to which it publishes quality science content for children and Ph.D.’s alike. NASA Space Place has been providing general audience articles for quite some time that are freely available for download and republishing. Your tax dollars help promote science! The following article was provided for reprinting in March, 2016.

By Dr. Ethan Siegel

2013february2_spaceplaceImagine a world very different from our own: permanently shrouded in clouds, where the sky was never seen. Never had anyone see the Sun, the Moon, the stars or planets, until one night, a single bright object shone through. Imagine that you saw not only a bright point of light against a dark backdrop of sky, but that you could see a banded structure, a ringed system around it and perhaps even a bright satellite: a moon. That’s the magnitude of what LIGO (the Laser Interferometer Gravitational-wave Observatory) saw, when it directly detected gravitational waves for the first time.

An unavoidable prediction of Einstein’s General Relativity, gravitational waves emerge whenever a mass gets accelerated. For most systems — like Earth orbiting the Sun — the waves are so weak that it would take many times the age of the Universe to notice. But when very massive objects orbit at very short distances, the orbits decay noticeably and rapidly, producing potentially observable gravitational waves. Systems such as the binary pulsar PSR B1913+16 [the subtlety here is that binary pulsars may contain a single neutron star, so it’s best to be specific], where two neutron stars orbit one another at very short distances, had previously shown this phenomenon of orbital decay, but gravitational waves had never been directly detected until now.

When a gravitational wave passes through an objects, it simultaneously stretches and compresses space along mutually perpendicular directions: first horizontally, then vertically, in an oscillating fashion. The LIGO detectors work by splitting a laser beam into perpendicular “arms,” letting the beams reflect back and forth in each arm hundreds of times (for an effective path lengths of hundreds of km), and then recombining them at a photodetector. The interference pattern seen there will shift, predictably, if gravitational waves pass through and change the effective path lengths of the arms. Over a span of 20 milliseconds on September 14, 2015, both LIGO detectors (in Louisiana and Washington) saw identical stretching-and-compressing patterns. From that tiny amount of data, scientists were able to conclude that two black holes, of 36 and 29 solar masses apiece, merged together, emitting 5% of their total mass into gravitational wave energy, via Einstein’s E = mc2.

During that event, more energy was emitted in gravitational waves than by all the stars in the observable Universe combined. The entire Earth was compressed by less than the width of a proton during this event, yet thanks to LIGO’s incredible precision, we were able to detect it. At least a handful of these events are expected every year. In the future, different observatories, such as NANOGrav (which uses radiotelescopes to the delay caused by gravitational waves on pulsar radiation) and the space mission LISA will detect gravitational waves from supermassive black holes and many other sources. We’ve just seen our first event using a new type of astronomy, and can now test black holes and gravity like never before.

This article was provided by the Jet Propulsion Laboratory, California Institute of Technology, under a contract with the National Aeronautics and Space Administration.

2016_02_gravitationalwaves.en

Caption: Observation of Gravitational Waves from a Binary Black Hole Merger B. P. Abbott et al., (LIGO Scientific Collaboration and Virgo Collaboration), Physical Review Letters 116, 061102 (2016). This figure shows the data (top panels) at the Washington and Louisiana LIGO stations, the predicted signal from Einstein’s theory (middle panels), and the inferred signals (bottom panels). The signals matched perfectly in both detectors. Click for a larger view.

About NASA Space Place

With articles, activities, crafts, games, and lesson plans, NASA Space Place encourages everyone to get excited about science and technology. Visit spaceplace.nasa.gov (facebook|twitter) to explore space and Earth science!

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