Assistant Professor of Chemical Engineering
School of Chemical Engineering
Forney Hall of Chemical Engineering
480 Stadium Mall Drive
West Lafayette, IN 47907-2100
POWER Lab Research Group
Twitter PageFunctional homopolymers and block polymers have attracted increasing attention as applications for these materials have begun to emerge in fields ranging from bioengineering to advanced energy systems. In particular, optoelectronically-active polymers have emerged as their own class of materials in recent years due to their promise of offering inexpensive, flexible, and lightweight alternatives to applications previously dominated by inorganic materials. Importantly, semiconducting polymers have optical and electronic properties that may be tuned by using well-designed chemical synthesis to control precisely the chemical constituents, the distribution of functionality along the polymer backbone, the molecular weight, and the molecular weight distributions of the macromolecules.
In the Polymers for Optoelectronic and Widespread Energy Research (POWER) Laboratory, we examine how control of macromolecular design affects the all-important nanoscale structure of these materials. In turn, this provides a handle by which to improve the performance of a variety of thin film, flexible organic electronic devices. Currently, we are examining five specific research thrusts that will utilize the advantages of functional homopolymers and block polymers for the fabrication of next generation organic electronic and advanced separations devices for enhanced energy, water, and homeland security applications.
- The design and utilization of functional radical polymers for transparent, conducting polymer thin films.
- The design of novel polymers, polymer-based nanoparticles, and inorganic nanoparticles for thermoelectric devices and catalytic applications.
- The fabrication of well-ordered, nanostructured organic non-volatile memory elements from nanostructured templates.
- The synthesis and microstructural characterization of functional triblock polymers for enhanced desalination separations.
- The fabrication of microstructured and nanostructured conducting polymers for advanced threat detection and homeland security applications.
- Aditya Baradwaj
- Martha Hay
- Darby Hoss (co-advised with Professor Steve Beaudoin)
- Jennifer Laster (co-advised with Professor Steve Beaudoin)
- Ryan Mulvenna
- Lizbeth Rostro
- Jessica Sargent
- Seung-Hyun Sung
- Edward Tomlinson
- Adam Wingate
- Emily Alcoarace
- Stuart Hillsmier
- Krystopher Jochem
- Alexander Muller
- Yucheng Wang
- Matthew Wilmore
- Si Hui Wong
- Xiaoqin Zhu
Awards and Honors
"Nanoporous Membranes Generated from Block Polymer Precursors, Quo Vadis?," Y. Zhang, J. L. Sargent, B. W. Boudouris, W. A. Phillip, J. App. Poly. Sci., in press (2014)
"Radical-containing Polymer and Their Application to Organic Electronic Devices," E. P. Tomlinson, M. E. Hay, B. W. Boudouris, Macromolecules, 47, 6145-6158 (2014)
"Solid State Electrical Conductivity of Radical Polymers as a Function of Pendant Group Oxidation State," L. Rostro, S. H. Wong, B. W. Boudouris, Macromolecules, 47, 3713-3719 (2014)
"Quantification of Solid-State Charge Mobility in a Model Radical Polymer," A. G. Baradwaj, L. Rostro, M. A. Alam, B. W. Boudouris, Appl. Phys. Lett., 104, 213306 (2014)
"Defect Characterization in Organic Semiconductors: Forward Bias Capacitance Analysis," B. Ray, A. G. Baradwaj, B. W. Boudouris, M. A. Alam, J. Phys. Chem. C, 118, 17461-17466 (2014)
"Tunable Nanoporous Membranes with Chemically-Tailored Pore Walls from Triblock Terpolymer Templates," R. A. Mulvenna, J. L. Weidman, B. Jing, J. A. Pople, Y. Zhu, B. W. Boudouris, W. A. Phillip, J. Membr. Sci., 470, 246-256 (2014)
"Controlled Radical Polymerization and Quantification of Solid State Electrical Conductivities of Macromolecules Bearing Pendant Stable Radical Groups," L. Rostro, A. G. Baradwaj, B. W. Boudouris, ACS Applied Materials and Interfaces, 5, 9896-9901 (2013)
"Engineering Optoelectronically Active Macromolecules for Polymer-based Photovoltaic and Thermoelectric Devices," B. W. Boudouris, Current Opinion in Chemical Engineering, 2, 294-301 (2013)