Daniel K.听Schwartz
- Glenn L. Murphy Professor of Engineering
- Interim Director, Environmental Engineering
- CHEMICAL AND BIOLOGICAL ENGINEERING
Office: JSCBB D124
Mailbox: 596 UCB
Education
PhD in Physics, Harvard University (1991)
专 summa cum laude in Chemistry and Physics, Harvard University (1984)
Selected Honors and Awards
- Dean鈥檚 Performance Award for Outstanding Research (2016)
- Dean鈥檚 Award for Outstanding Research (2014)
- Fellow of the American Chemical Society (2014)
- Fellow of the American Physical Society (2011)
- Graduate Teaching Award (student-awarded), 欧美口爆视频-Boulder ChBE Dept. (2011, 鈥15, 鈥17, 鈥19)
- Faculty Research Award, 欧美口爆视频-Boulder College of Engineering (2010)
- Boulder Faculty Assembly Award for Excellence in Research (2008)
- 欧美口爆视频-LEAD Alliance Faculty Appreciation Award (2006)
- Camille Dreyfus Teacher-Scholar Award (1999)
- NSF/CAREER Award (1998)
- Mortarboard Honor Society Salute for Excellence in Teaching (1997, 1998, 1999)
- Camille & Henry Dreyfus Foundation New Faculty Award (1994)
Selected Publications
- Haichao Wu, Benjamin Greydanus, and Daniel K. Schwartz, 鈥淢echanisms of Transport Enhancement for Self-Propelled Nanoswimmers in a Porous Matrix鈥, Proceedings of the National Academy of Sciences, 118, e2101801118 (2021); doi:10.1073/pnas.2101807118
- Andres F. Chaparro Sosa, Riley M. Bednar, Ryan A. Mehl, Daniel K. Schwartz, and Joel L. Kaar, 鈥淔aster Surface Ligation Reactions Improve Immobilized Enzyme Structure and Activity鈥, J. Am. Chem. Soc., 143, 7154-7163 (2021); doi:10.1021/jacs.1c02375
- Connor J. Thompson, Vinh H. Vu, Deborah E. Leckband, and Daniel K. Schwartz, 鈥淐adherin Cis- and Trans-Interactions are Mutually Cooperative鈥, Proceedings of the National Academy of Sciences, 118, e2019845118 听(2021): doi:10.1073/pnas.2019845118.
- Haichao Wu and Daniel K. Schwartz, 鈥淣anoparticle Tracking to Probe Transport in Porous Media鈥 , Accounts of Chemical Research, 53, 2130-2139 (2020); doi:10.1021/acs.accounts.0c00408
- Andres F. Chaparro Sosa, Kenneth J. Black, Daniel F. Kienle, Joel L. Kaar, and Daniel K. Schwartz, 鈥淓ngineering the Composition of Heterogeneous Lipid Bilayers to Stabilize Tethered Enzymes鈥, Advanced Materials Interfaces, 7, 2000533 (2020); doi:10.1002/admi.202000533
- Dapeng Wang and Daniel K. Schwartz, 鈥淣on-Brownian Interfacial Diffusion: Flying, Hopping, and Crawling鈥, J. Phys Chem C, 124, 19880-19891 (2020); doi:10.1021/acs.jpcc.0c05834
- James S. Weltz, Daniel F. Kienle, Daniel K. Schwartz, and Joel L. Kaar, 鈥淩educed Enzyme Dynamics upon Multipoint Covalent Immobilization Leads to Stability-Activity Tradeoff鈥, J .Am. Chem. Soc.142, 3463-3471 (2020); doi:10.1021/jacs.9b11707
- Benjamin Greydanus, Daniel K. Schwartz, and J. Will Medlin, 鈥淐ontrolling Catalyst Phase Selectivity in Complex Mixtures with Amphiphilic Janus Particles, ACS Applied Matls & Interfaces12, 2338-2345(2020); doi:10.1021/acsami.9b16957
- Dapeng Wang, Lijun Liu, Haichao Wu, Jizhong Chen, and Daniel K. Schwartz, 鈥淒iffusive Escape of a Nanoparticle from a Porous Cavity鈥, Phys Rev Lett 123, 118002 (2019); doi:10.1103/PhysRevLett.123.118002
- Jeremiah C. Traeger, Zachary Lamberty, and Daniel K. Schwartz, 鈥淚nfluence of Oligonucleotide Grafting Density on Surface-Mediated DNA Transport and Hybridization鈥, ACS Nano, 13, 7850-7859 (2019). doi:10.1021/acsnano.9b02157
- Dapeng Wang, Haichao Wu, Daniel K. Schwartz, 鈥淭hree-Dimensional Tracking of Interfacial Hopping Diffusion鈥; doi:10.1103/PhysRevLett.119.268001, Physical Review Letters, 119, 268001 (2017),
- James S. Weltz, Daniel K. Schwartz, and Joel L. Kaar , 鈥淪urface-Mediated Protein Unfolding as a Search Process for Denaturing Sites鈥, ACS Nano; 10, 730-738 (2016); doi:10.1021/acsnano.5b05787
- Michael J. Skaug, Liang Wang, Yifu Ding, and Daniel K. Schwartz, 鈥淗indered Nanoparticle Diffusion and Void Accessibility in a Three-Dimensional Porous Medium鈥 , ACS Nano, 9, 2148-2156 (2015); doi:10.1021/acsnano.5b00019
- Carolyn A. Schoenbaum, Daniel K. Schwartz, and J. Will Medlin, 鈥淐ontrolling the Surface Environment of Heterogeneous Catalysts Using Self-Assembled Monolayers鈥, Accounts of Chemical Research, 47, 1438-1445 (2014); doi:10.1021/ar500029y
- Michael J. Skaug, Joshua Mabry, Daniel K. Schwartz, 鈥淚ntermittent Molecular Hopping at the Solid-Liquid Interface鈥, Physical Review Letters, 110, 256101 (2013)
- Stephen T. Marshall, Marykate O鈥橞rien, Brittany Oetter, April Corpu, Ryan M. Richards, Daniel K. Schwartz, J. William Medlin, 鈥淐ontrolled Selectivity for Palladium Catalysts using Self-assembled Monolayers鈥, Nature Materials, 9, 853-858 (2010)
Research Interests
Colloids and Interfaces, Transport in porous/nonporous materials, Single-molecule microscopy, Separations, Biomolecules at interfaces, Surface modification by self-assembly, Heterogeneous Catalysis/Biocatalysis, Biomaterials.
Molecular Transport at Interfaces
The dynamic behavior of molecules and nanoparticles at interfaces leads to complex phenomena, where heterogeneity may arise from spatial variation of the interface itself, from molecular structures, or through inhomogeneous dynamic behavior. To obtain relevant information about these complex dynamics, we have developed highly multiplexed single-molecule/single-particle tracking methods that acquire large numbers of trajectories permitting rigorous analysis using statistical modeling and machine learning. A specific discovery that was enabled by these methods involves the ubiquitous intermittent motion (i.e. 鈥渉opping diffusion鈥) of molecules at interfaces, which was explicitly confirmed using 3D double-helix point spread function imaging. Ongoing research studies the impacts of interfacial dynamics on various technological applications, membrane biophysics, and separations processes.
Transport in Porous and Complex Materials
Work in our lab has explored the motion of Brownian, pressure-driven, and self-propelled molecules, polymers, and nanoparticles within highly interconnected porous environments (both static and dynamic), leading to insights linking microscopic pore-scale mechanisms to macroscopic transport. Ongoing research includes fundamental studies of mass transport in complex interface-rich environments and within nominally non-porous materials, as well as more applied studies of phenomena in porous filtration and separations media that are relevant to energy and pharmaceutical technologies.
Biomolecules at Interfaces
Biomacromolecules, like proteins and DNA, interact in complex ways at interfaces and within interface-rich materials. We are studying the structural changes that occur when proteins and oligonucleotides adsorb or are immobilized at solid surfaces and at the air/water interface using single-molecule tracking fluorescence microscopy and other tools. We are particularly interested in understanding how surface-mediated structural changes (e.g. protein unfolding and refolding) influence applications including biosensing, biocatalysis, biomaterials, pharmaceuticals, and vaccines.
Catalyst Surface Modification using Self-assembled Monolayers
Self-assembled monolayers (SAMs) represent a versatile coating technology with applications in biocompatibility, nanotechnology, biosensors, corrosion resistance, and molecular electronics. We study the growth and structure of SAMs, ultra-thin molecular films adsorbed from solution on solid surfaces, and we are particularly interested in the use of SAMs to modify heterogeneous catalysts, to control activity and selectivity in thermal, biphasic, and electrochemical reactions.
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