Assistant Professor of Physics
Geballe Laboratory for Advanced Materials
McCullough Bldg, Room 348
(650) 723-7283
Email: manoharan@stanford.edu
Website: http://mota.stanford.edu/

Professional Experience and Honors

• B.S.E. Princeton University (1991).
• M.S. Stanford University (1992).
• M.A. Princeton University (1993).
• Ph.D. Princeton University (1997).
• Research Scientist, IBM Almaden Research Center (1998-2000).
• Assistant Professor of Physics, Stanford University (2001-present).
• Assistant Professor, by Courtesy, of Electrical Engineering, Stanford University (2001-present).
• Assistant Professor, by Courtesy, of Materials Science and Engineering (2001-present).
• Hertz Foundation Fellow (1991-96).
• Porter Ogden Jacobus Fellow (1996-97).
• Wallace Memorial Fellow (1996-97).
• IBM Invention Achievement Award (2000).
• IBM TEAM Patent Award (2000).
• Research Corporation Research Innovation Award (2002).
• Alfred P. Sloan Research Fellow (2002-2003).
• ONR Young Investigator (2002-2004).
• NSF CAREER Award (2002-2006).
• Presidential Early Career Award for Scientists and Engineers (PECASE, 2004).

Research Interests
Nanoscale Science and Technology: Atomic and Molecular Manipulation
Throughout history, humans have sought to expand their mastery of the material world. Our ability to manipulate matter has been continuously refined, extending to constructions of colossal size and extreme complexity. Progress in the diametric direction of diminishing scale has proved increasingly vital to society. Well-known contemporary examples include the microelectronic and biotechnology industries. The efforts within these fields rely predominantly on new tools that extend control, and measurements, to progressively smaller length scales.

Instead of this "top-down" approach, what if we proceed from the bottom and work our way up? For the first time, we are poised to explore critical science starting from the basic building blocks of matter—single atoms. So the question now becomes: rather than work our way down from the macroscopic level, what can we learn if we build up from the atomic realm? The answer, not surprisingly, seems both manifold and deep.

My research program seeks to apply the "bottom-up" approach of atomic and molecular manipulation to a variety of outstanding problems in science and technology. The effort is interdisciplinary in nature, centering on physics and engineering but involving ideas, techniques, and conundrums from other fields such as chemistry, biology, materials science, and information technology. The primary experimental apparatus for these investigations are custom-built low-temperature scanning probe microscopes capable of both studying and controlling matter at atomic length scales.

Research projects, whose motivations are drawn from several research frontiers, include:

• Nanoassembly using Atomic and Molecular Manipulation
• Studies of Isolated and Interacting Magnetic Moments
• Local Probes of Correlated Electrons in Reduced Dimensions
• Local Response of Novel Superconductors
• Exploring New Paradigms in Computation
• Atomic and Molecular Electronics
• Organic Molecules and the Structure of Life

My research group:

• Manoharan Lab — Manipulation Of The Atom

Our research fields:

• Experimental Condensed Matter
• Microscopy and Imaging
• Mesoscopic Physics
• Superconductivity