A free electron ‘wiggled’ by graphene plasmons emits an X-ray pulse.
Since their discovery in 1895, X-rays have led to significant advances in science, medicine and industry. From probing distant galaxies to screening at airport security and facilitating medical diagnosis, they have allowed us to look beyond the surface and see what lies beneath.
Now, a collaboration between the A*STAR Singapore Institute of Manufacturing Technology (SIMTech) and the Massachusetts Institute of Technology (MIT) in the US has proposed a versatile, directional X-ray source that could fit on a laboratory bench and is based on the intriguing two-dimensional material graphene.
X-rays are high-frequency electromagnetic waves that can be generated using X-ray tube technology or from huge sources like synchrotrons and kilometrelong free electron lasers.
But X-ray tube sources, popularly used in medical diagnostics, emit radiation in all directions, wasting a significant amount of the generated X-rays. They are also not ‘tunable’, meaning that a different X-ray source must be installed in a diagnostic device for each desired wavelength.
Kilometre-long free electron lasers, on the other hand, can produce intense, tunable X-rays by accelerating free electrons to extremely high energies and then causing them to ‘wiggle’ using magnets. But these enormous X-ray sources only exist in a few places in the world and are housed in very large, expensive facilities.
An X-ray source that is both small and powerful has been much sought after for some time.
To this end, the team of SIMTech-MIT researchers employed graphene, a oneatom-thick sheet of carbon atoms, which, among other things, can support plasmons: collections of electronic oscillations that can be used to confine and manipulate light on scales of around ten nanometres.
The team first developed a robust simulation tool that models the exact physics of electrons interacting with a plasmon field sustained on a graphene sheet deposited on a piece of 'dielectric’, or insulating, material. By performing numerical simulations, the team showed that this set-up induces a ‘wiggling’ motion in electrons fired through the graphene plasmons, causing the electrons to produce high-frequency X-ray radiation. The simulations agreed with the analytical theory developed by the team to explain how electrons and plasmons interact to produce X-rays.
One standout characteristic of such a source will be its ‘pointability’, which will increase efficiency and hence reduce costs by ensuring that all the generated radiation goes where it’s intended. This will make the source promising for medical treatments as it could be used to target tumours more precisely and hence minimize damage to surrounding organs and cells.
Perhaps most attractive will be the source’s versatility. The output radiation frequency can be tuned in real time from longer infrared rays to shorter X-rays by modifying various elements of the source, such as the speed of the electrons, the frequency of the graphene plasmons and the conductivity of the graphene.
This flexible, compact source is promising as a cost-effective alternative to the high-intensity beams used for fundamental scientific and biomedical research. “Although there is a long way to go to actual realization, this is a very exciting research direction,” says Liang Jie Wong from SIMTech. “Developing an intense X-ray source that can fit on a table or be held in one’s hand would potentially revolutionize many areas of science and technology.”
The team next plans to experimentally verify their concept with proof-of-principle trials.
Further information
Dr Liang Jie Wong
E-mail: [email protected]
Singapore Institute of Manufacturing Technology
Agency for Science, Technology and Research
Meet the Expert
Dr. Liang Jie Wong is a scientist and principal investigator at the Singapore Insttitute of Manufacturing Technologies (SIMTech). He specializes in the study of X-ray photonics and laser-electron interactions.
Dr. Ido Kaminer is a postdoctoral researcher in MIT's physics department, and specializes in the quantum engineering of electron wavefunctions and electromagnetic waves.
Dr. Ognjen Ilic is a postdoctoral researcher in MIT's physics department, and specializes in nanophotonics, renewable energy and efficient energy conversion.
Professor John Joannopoulos is the Francis Wright Davis Professor of Physics at MIT, and Director of the Institute for Soldier Nanotechnologies at MIT. His research interests include photonic crystals and ab-initio simulations of material systems.
Professor Marin Soljačić is a Professor of Physics at MIT and one of the founders of WiTricity Corporation. His research interests include nanophotonics, non-linear optics and wireless power transfer.
Researchers Dr. Liang Jie Wong (left) and Dr. Ido Kaminer (right)
