Atomic, Molecular, and Optical Physics

Areas of Research

Atomic and Molecular Physics
Our research addresses several of the most exciting questions in current atomic and molecular sciences, including quantum control of molecular states and processes (Odom, Seideman), tests of astrophysics and fundamental symmetries (Shahriar, Odom), and trapping and cooling of atoms and molecules (Shahriar, Odom).

We control the properties of light and use it to manipulate matter on length scales ranging from individual molecules, through nano- and micro-particles (including cells), up to the macroscopic level. Areas of interest include coherent control of light (Seideman), non-linear optics, excitonics, and plasmonics, (Kumar, Ketterson, Shahriar, Stern), non-classical states of light (Kumar, Stern), and biophotonics (Ketterson, Jacobsen).

Quantum Computing and Cryptography
We address fundamental and applied questions concerning utilization of quantum-mechanical properties of light and matter in the field of information processing. Our research includes investigation of photon entanglement over fiber networks (Kumar), quantum computing in atom traps (Shahriar), and quantum communication theory (Yuen).


Chris Jacobsen   [Jacobsen Research Group]
Professor Jacobsen's research group is developing novel methods, instruments, and analysis approaches for x-ray imaging, and applying them to problems in biology and environmental science. This research makes use of the Advanced Photon Source (APS) at nearby Argonne National Laboratory, where Jacobsen holds a joint appointment. The APS is a leading facility for x-ray research, and provides unique opportunities for Northwestern students to be at the forefront of developing methods for nanoscale imaging of how metals regulate cellular functions, how environmental contaminants can be remediated, and improved batteries and solar cells can be developed.

John Ketterson
For a number of years the Ketterson group has been studying the properties long-lived  excitons at high density in materials like cuprous oxide with special emphasis on macroscopic coherence displayed by exciton polaritons and expected for an excitonic Bose-Einstein condensate. Other interests include i) laser tweezers (with special emphasis on potential biological applications), ii) plasmonic properties of metal films and nanostructures and iii) studies the non linear optical properties of a wide variety of materials including semiconductors and organic chromophors.

Prem Kumar   [Kumar Research Group]
Professor Kumar's research spans the following three inter-related areas within classical and quantum optics: Quantum Fiber Optics-generation and distribution of quantum entanglement over the fiber  channel and quantum cryptography over fiber lines; Optical Communications-novel optical amplifiers and devices for terabit/s communications; Nonlinear and Quantum Optics-applications of novel quantum states of light such as squeezed and twin-beams states in precision measurement and imaging systems.

Brian Odom   [Odom Research Group]
Professor Odom’s group performs experiments with milliKelvin molecular ions held in radio-frequency traps.  Research projects include a search for time-variation of fundamental constants, a search for differences between left- and right-handed molecules induced by the weak nuclear force, and studies of quantum effects in chemical reactions below 1 Kelvin.

Tamar Seideman   [Seideman Research Group]
Professor Seideman’s group performs theoretical research at the broad interface between molecular physics, chemical dynamics and material research. Specific research interests include quantum transport, molecular electronics, current-driven nanochemistry and molecular machines; nanoplasmonics and light manipulation in the nanoscale; coherent control and coherence spectroscopies in isolated molecules and in dissipative media; the interaction of matter with intense laser fields; and mathematical method development.

Selim Shahriar   [Shahriar Research Group]
Professor Shahriar's research activities include the following areas: superluminal gyroscopes for measuring Lense-Thirring rotation as a test of General Relativity, white light cavities for enhancing the sensitivity of gravitational wave detectors, quantum computers using trapped atomic ensembles, ultra-low light level nonlinear optics using nanofibers and atoms for switching and quantum logic, and holographic and polarimetric image processing.

Nathaniel Stern
Professor Stern’s research is focused on the fundamental quantum interactions of photons with atoms, nano-scale structures, and magnetic materials. Specific research interests include: solid-state quantum optics, nanophotonics and cavity quantum electrodynamics, magnetization dynamics in low-dimensional structures, and spintronics.

Horace Yuen   [Yuen Research Group]
Professor Yuen's research interests encompass a broad spectrum of topics in quantum optics, including quantum communication theory, quantum measurement and the foundations of quantum physics, new quantum devices, quantum cryptography, and new computers based on optical technologies.


NSF Integrative Graduate Education and Research Training (IGERT)
This program focuses on science and technology surrounding quantum coherent optical and matter systems and related photonic structures and sources. Objectives include both training and research. The following physics faculty are members of this program: Garg, Ketterson, Kumar, Odom, Shahriar, Seideman, and Yuen.

Biophotonics Lab (Phyx 357)
Students in this laboratory course obtain hands-on experience with optical techniques widely used in medical and biological studies including optical microscopy (conventional, confocal, and total internal reflection), fluorescence spectroscopy, and use of laser tweezers. Special topics have included tumor detection with optical scattering, laser-tissue interaction as applied to photodynamic therapy and laser surgery, and optical fibers in endoscopes.  Prerequisites:  Phyx 135-3 or the equivalent.

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August 26, 2013