William O. Baker Award for Initiatives in Research

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The William O. Baker Award for Initiatives in Research, previously the NAS Award for Initiatives in Research, is awarded annually by the National Academy of Sciences "to recognize innovative young scientists and to encourage research likely to lead toward new capabilities for human benefit. The award is to be given to a citizen of the United States, preferably no older than 35 years of age. The field of presentation rotates among the physical sciences, engineering, and mathematics." [1]

The award was established in 1981 in honor of William O. Baker by AT&T Bell Laboratories and is supported by Lucent Technologies.

Recipients[edit]

Source: National Academy for Sciences

For his development and mechanistic elucidation of remarkable iron catalysts for carbon-hydrogen bond functionalization.

For innovative research on advanced materials for next-generation implanted medical devices.

For revolutionary advances in multidimensional spectroscopies, which are enabling discoveries in biological, medical, and condensed matter chemical systems.

For development of fast algorithms in mathematical physics, operator compression, and linear algebra, using deep, innovative ideas based on randomization and harmonic analysis.

For seminal advances in carbon nanoelectronics, utilizing and synthesizing concepts from chemistry, physics, and engineering.

For innovative algorithms using wavelets and sampling techniques and their impact on data analysis and sparse approximation.

For innovative research on the theory and applications of photonic crystal devices.

For his fundamental studies of electron correlations in mesoscopic structures.

  • Ronald Fedkiw (2005, computational science/applied mathematics )

For his many innovations in the modeling and numerical simulation of flows and his pioneering contributions to physically based computer graphics.

  • Yoel Fink (2004, condensed matter/materials science)

For his pioneering contributions and ingenuity in the creative design and development of photonic materials and devices.

For the elegant use of randomness to design improved algorithms for classically studied problems such as network flow, graph coloring, finding minimum trees, and finding minimum cuts.

For her experimental realization and characterization of a new quantum system, the vapor-phase degenerate Fermi gas.

For his development of deep and innovative algorithms to solve fundamental problems in network, information extraction, and discrete optimization.

For his insightful use of isotope geochemistry to address the origin of Earth's atmosphere, the infall of cosmic dust, and the uplift rates of mountains.

For her pioneering studies, which have enabled the determination of complex RNA structures, especially those of ribozymes, through X-ray crystallography.

For his contribution to our understanding of the importance of knowledge, learning, and persuasion to political decision-making by voters, legislators, and jurors.

For his seminal contributions to the theory of the vortex-glass phase, the superconductor-insulator transition, and the quantum properties of mesoscopic wires and n-leg Hubbard ladders.

For his innovative development and utilization of instrumentation to attack fundamental issues in physics and astronomy, including the discovery of baryonic dark matter in the galactic halo.

For his fundamental contributions to the understanding of motion perception through the creative integration of single-unit electrophysiology in monkeys, human psychophysics, and computational modeling.

For her pioneering genetic and molecular approaches that have altered our understanding of how photomorphogenesis in plants is controlled by photoreceptor signal transduction pathways.

For his implementation of a near-field scanning optical microscope, which extends the resolution of optical microscopy far beyond the diffraction limit to dimensions as small as one-fortieth of an optical wave length.

For her innovative experimental and theoretical research of polymer and colloidal systems leading to discoveries of new microscopic phenomena.

For his refinement of mathematical techniques in low Reynolds number hydrodynamics, and for his development of novel computer strategies for solving complex chemical engineering problems.

For his distinguished research in number theory, particularly his work on elliptic curves over the rational numbers and his remarkable constructions of dense sphere packings in Euclidean space.

For his contributions to femtosecond quantum electronics and applications of subpicosecond lasers to studies of electronic materials and biological tissues.

For his contributions to femtosecond quantum electronics and applications of subpicosecond lasers to study ultrafast processed in molecular systems and semiconductor heterostructures.

For his outstanding achievements in the engineering of software ranging from operating systems to the computer-aided design of VLSI circuits.

For his outstanding theoretical studies of the structure and properties of amorphous and semicrystalline polymers.

For providing molecular genetic proof of the Young-Helmholtz trichromatic theory of color vision and for defining the changes in DNA in colorblindness.

For his contributions to the understanding of imperfectly ordered systems including hexactics, liquid crystals, glasses, and icosahedral order in liquids.

For his pioneering research, demonstrating the role of epiphytic bacteria in ice nucleation and resultant frost damage to plants, the feasibility of biological as well as chemical control of frost injury, and the genetic control of ice nucleation in bacteria.

For his leadership in the subtle design of the most efficient algorithms known for many fundamental problems related to graphs and other combinatorial structures.

For his development of a comprehensive theory of visual imagery and its representation in the human memory system.

For his development and application of innovative field techniques for studying active faults to identify and date paleoearthquakes, thereby providing quantitative assessment of earthquake hazards.

For his outstanding theoretical and experimental contributions to polymer science, particularly in the application of light scattering measurements to the understanding of polymer chain dynamics.

References[edit]

  1. ^ "William O. Baker Award for Initiatives in Research". National Academy for Sciences. Retrieved 15 August 2015. 

External links[edit]