Daniel Philip Shoemaker

Daniel Philip Shoemaker
Daniel Philip Shoemaker

Daniel Philip Shoemaker

Assistant Professor
Materials Science and Engineering
112 Seitz Materials Research Lab MC 230
104 S. Goodwin
Urbana Illinois 61801
(217) 244-4991

materials chemistry, in situ synthetic reactions, magnetic and electronic properties, nanostructured materials, x-ray and neutron scattering, real-space modeling and crystallography

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Academic and Scientific Experience

Professional Highlights

  • Professor Daniel P. Shoemaker received his BS with Honors in Materials Science and Engineering from the University of Illinois in 2006 and his PhD in Materials from the University of California, Santa Barbara in 2010. His doctoral work focused on using neutron scattering and real-space modeling to understand the structure-property relationships of disordered magnetic and electronic oxides. In 2011 he began a postdoctoral appointment in the Materials Science Division of Argonne National Laboratory where he investigated the synthesis of superconductors and semiconductors with a focus on in situ spectroscopy and x-ray diffraction. Shoemaker joined the Department of Materials Science and Engineering at the University of Illinois at Urbana-Champaign as an Assistant Professor in August 2013.

Courses Taught

  • MSE 403 - Synthesis of Materials
  • MSE 405 - Microstructure Determination
  • MSE 529 - Hard Materials Seminar
  • MSE 595 - Materials Colloquium

Research Statement

Our group focuses on synthesizing new inorganic materials and uncovering routes to engineer their response to electronic, magnetic, and chemical stimuli. Understanding synthesis allows us to use chemistry to tune, alter, or reassemble materials. We grow single crystals, microstructured composites, and nanomaterials, and make heavy use of electronic, magnetic, and optical measurements. Current research topics include:

In situ synthesis: Many arenas of energy conversion, such as light absorbers, batteries, and catalysis, are limited by the library of viable materials. We use special growth cells to observe metastable synthesis reactions as they happen in the solid, liquid, and gas phase. These reactions produce new compounds that are inaccessible from a traditional approach based on equilibrium phase diagrams. X-ray diffraction and optical spectroscopy can reveal how compounds form and identify new materials on the fly. We also develop computational tools to handle the complex data collected during any given experiment.

Micro- and nano-structured magnetism: Performance of magnetic materials is dictated by complex interactions on multiple length scales, from micron-sized domains to the angstrom-level exchange interactions between atoms. We synthesize magnetic materials and develop tools for characterizing and modeling their defects, inclusions, and microstructure. Understanding these relationships allows us to refine our syntheses, improve performance, and uncover new candidate materials.

Structure and dynamics of correlated materials: During our investigations of superconductors, dielectrics, and phase-change materials, intriguing physical phenomena arise when materials deviate from their ideal structure due to formation of defects or disordered domains. We conduct high-energy X-ray and neutron scattering experiments at the Advanced Photon Source at Argonne National Laboratory and the Lujan Neutron Scattering Center at Los Alamos National Laboratory. Scattering and spectroscopy allow us to reconstruct structural snapshots of disordered materials and understand how chemical bonding dictates magnetic and electronic properties.

Research Honors

  • 23rd Louis Rosen Thesis Prize - Los Alamos Neutron Science Center (2011)
  • Materials Research Society Graduate Student Gold Award (2010)