497-204: Developing an Antimatter Gravity Interferometer

Meeting Days/Time
Tuesdays/Thursdays from 1:50 to 3:05 pm.
Daniel Kaplan (PHYS) (kaplan@iit.edu) and Derrick Mancini (PHYS) (dmancini@iit.edu)
Appropriate Disciplines
Aerospace Engineering, Applied Mathematics, Biology, Biomedical Engineering, Chemical Engineering, Chemistry, Computer Engineering, Computer Information Systems, Computer Science, Electrical Engineering, Information Technology & Management, Materials Engineering, Mechanical Engineering, Molecular Biochemistry & Biophysics, Physics, Political Science
Technical Innovation

Does antimatter fall up? The science-fictional idea of antigravity is now being taken seriously by a number of researchers around the world. We will develop novel experimental apparatus to measure the gravitational acceleration of antimatter.

Einstein’s General Relativity, the accepted theory of gravity, predicts no difference whatsoever between the gravitational behaviors of matter and antimatter. While well-established experimentally, General Relativity has never been tested with antimatter. If antimatter is found to fall up in the gravitational field of the Earth — or even if it falls down, but at a different rate from matter — it will fundamentally change our view not only of gravity but of the nature and evolution of the Universe.

The measurement will require a source of neutral antimatter atoms and a precision device to measure their motion under gravity. Our approach is to use muonium — a hydrogen-like atom composed of an antimuon bound to an electron. (Although the electron is matter, since the antimuon is 200 times heavier than the electron, muonium should act gravitationally like antimatter.) Muonium sources exist at a number of particle accelerator laboratories around the world. Since muonium decays on average in 2.2 microseconds, the measurement is difficult and requires extreme mechanical precision.

We will continue the development of a precision interferometer employing thin silicon-nitride gratings made at Argonne National Laboratory using nanotechnology fabrication techniques. This IPRO project started in the fall 2014 semester and continued during spring 2016, with significant progress being made. We will build on that progress by (if not already done) building gratings, characterizing their precision (and, if necessary, figuring out how to improve it). We will carry out further design and simulation studies, including finite-element analysis (FEA) of the gratings, the optical bench, and their mechanical systems, in order to understand and optimize the performance of the experiment as a whole. We will also continue experimental studies of our infrared-laser picometer-alignment system.

This project can benefit from collaborating students from many fields of study, e.g., physics, engineering, computer science, and applied math.

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