A Tabletop Source of Strong Terahertz Radiation

By: Ki-Yong Kim

Sandwiched between the traditional optical and microwave regimes, far infrared or terahertz (THz) frequency (1 THz = 1012 Hz) has recently drawn special attention due to its potential for molecular sensing, biomedical imaging and spectroscopy, security scanners, and plasma diagnostics. These applications provide strong motivation to advance the state of the art in THz source development. In particular, large-scale electron accelerators such as synchrotrons and free electron lasers are currently available to produce THz radiation energy in excess of several microjoule per pulse. However, due to its large cost to build those facilities and thereby limited access, there is a present and growing need to realize such strong THz generation at the tabletop scale. In this effort, we have recently demonstrated a high-energy (>5 microjoule), super-broadband (>75 THz), tabletop THz source via ultrafast photoionization in gases [1].

In this scheme, an ultrafast pulsed laser’s fundamental and second harmonic fields are mixed in a gas of atoms or molecules, causing them to ionize. Microscopically, the laser fields act to suppress the atom’s or molecule’s Coulomb potential barrier, and, via rapid tunneling ionization, bound electrons are freed. The electrons, once liberated, oscillate at the laser frequencies, and also drift away from their parent ions at velocities determined by the laser field amplitudes and the relative phase between the two laser fields. Depending on the relative phase, symmetry can be broken to produce a net directional electron current. As this current occurs on the timescale of photoionization, for sub-picosecond lasers, it can generate electromagnetic radiation at THz frequencies.

This THz generation mechanism turns out to be closely related to the mechanism used to explain high harmonic generation (HHG) in gases, as both processes originate from a common source, that is, a nonlinear electron current. The electrons re-colliding with the parent ions are responsible for HHG, whereas the electrons drifting away from the ions without experiencing re-scattering ions account for THz generation. As demonstrated experimentally [1], the generated THz and third-harmonic are strongly correlated in such a way that changing the relative phase can effectively switch the emission between THz and harmonics. This provides the basis to coherently control electromagnetic radiation in a broad spectral range, from THz to extreme ultraviolet.

Now, the next step is to scale up the laser power to produce even more powerful THz radiation. Using the Maryland’s 30 terawatt (TW) laser, we anticipate producing an unprecedented millijoule level of THz radiation. Such radiation may allow us to observe extreme nonlinear THz phenomena in a university laboratory.


[1]  K. Y. Kim et al., Nature Photon. 2, 605 (2008).

Long-Distance Teleportation Between Atoms

For the first time, scientists have successfully teleported information between two separate atoms in unconnected enclosures a meter apart – a significant milestone in the global quest for practical quantum information processing.

Teleportation may be nature’s most mysterious form of transport: Quantum information, such as the spin of a particle or the polarization of a photon, is transferred from one place to another, but without traveling through any physical medium. It has previously been achieved between photons over very large distances, between photons and ensembles of atoms, and between two nearby atoms through the intermediary action of a third. None of those, however, provides a feasible means of holding and managing quantum information over long distances. 

Read More

UMD Physicists Play Major Roles in Four of AIP's Top Ten Physics Discoveries of 2008

Editors and science writers at the American Institute of Physics and the American Physical Society selected a list of Top Ten Physics Stories in 2008. The selections were released on December 22, 2008 and included four discoveries in which UMD Physicists had major roles (Large Hadron Collider, Quarks , Ultracold Molecules and Cosmic Rays).

To view the full article, visit: http://www.aip.org/pnu/2008/split/879-1.html

Robert Gluckstern: 1924 - 2008

Bob Gluckstern passed away December 17, 2008.

Bob was a brilliant physicist and superb administrator. He received his PhD from MIT in 1948, was a postdoc/assistant professor/associate professor at Yale until 1964, and a Professor at the University of Massachusetts, Amherst, as Chair of the Physics Department for 5 years, and Provost until 1975. He was Chancellor here (the same position is called President now) from 1975 to 1982, when he stepped down to return to full-time teaching and research. He did research in many fields, from early work in coulomb scattering, nucleon scattering, relativistic electrodynamics, to more recent work in accelerator theory and non- linear dynamics. As an aside, he was a long time participant in the Maryland Choir. As another aside, Bob once wrote a paper on how to calculate the uncertainties in the measurement of the curvature (and hence the momentum) of charged tracks in magnetic fields due to multiple scattering and measurement errors. This paper had a huge impact in the field of particle physics.

Bob was an extraordinary physicist who had a pure and deep understanding of the material. In the past few years, true to form, Bob played an important role in the Slawsky clinic. He really enjoyed having contact with the students. Indeed, while Chancellor, he was also a TA in Physics and Math (assisting both Jordan Goodman and Vic Korenman). He was a superb teacher and human being to the end, and he fought a hard fight with cancer. We will miss him, his rich New Yawk accent, his good nature, his perspective, his brilliance, and his friendship.

--Drew Baden, Chair
Obituary in The Washington Post.