The goal of this highly-interdisciplinary project is the synthesis and characterization of bioinspired hierarchical self-assembling polymer-inorganic nanocomposites. It seeks to answer the following questions:
- What are the general design rules for bioinspired self-assembled polymer nanocomposites? To answer this question, a highly synergistic combination of theory and experiment will be implemented.
- What experimental techniques or approaches can be developed or combined to probe the assembly at multiple length scales?
This work yields a robust and modular method for developing bioinspired hierarchical materials, with control over the formation as well as placement of an inorganic phase in the nanocomposite structure. This, in turn, leads to development of novel hybrid materials, lightweight and energy efficient, with potential for applications in fuel cells, spintronics, quantum computing, or magnetic actuators. This closely knit group, involving biochemists, chemists, materials scientists, engineers, and physicists, provides a unique skill set for this work; the success of their synergy has already been demonstrated by their bioinspired synthesis of magnetic nanoparticles.
Subtasks in this Project are:
- Development of multiscale self-assembling bioinspired hybrid materials using bottom-up approaches. We design hierarchically self-assembling templates (synthetic polymers as well as protein- and peptide-based templates), and use bioinspired methods for room temperature synthesis of several energy-relevant hybrid materials with hierarchical order that are difficult to synthesize otherwise. (S. Mallapragada, M. Nilsen-Hamilton, M. Akinc, T. Prozorov, G. Kraus)
- Development of techniques to probe assembly at multiple length scales and properties of these nanocomposites. We use a combination of solid-state NMR, scattering, and electron microscopy techniques to investigate the nanostructure and composition, and other characterization techniques to investigate the magneto-mechanical properties of these hybrid materials. (K. Schmidt-Rohr, B. Narasimhan, D. Vaknin)
- Development of computational methods for understanding general design rules for self-assembled polymer nanocomposites. We develop and implement molecular simulations, using high performance computational approaches as a powerful tool to understand the underlying principles of self-assembly of complex structures, phase transformation between competing phases, as well as the response of a self assembled system to external stimuli. (A. Travesset-Casas, M. Lamm)
Knorowski C; Burleigh S; Travesset A . 2011. Dynamics and Statics of DNA-Programmable Nanoparticle Self-Assembly and Crystallization. Physical Review Letters. 106:215501.
Wang W J; Park R Y; Travesset A; Vaknin D . 2011. Ion-Specific Induced Charges at Aqueous Soft Interfaces. Physical Review Letters. 106:056102.
Anderson J A; Sknepnek R; Travesset A . 2010. Design of polymer nanocomposites in solution by polymer functionalization. Physical Review E. 82:021803.
Vaknin D; Bu W . 2010. Neutrally Charged Gas/Liquid Interface by a Catanionic Langmuir Monolayer. Journal of Physical Chemistry Letters. 1:1936-1940.
Hu Y Y; Yusufoglu Y; Kanapathipillai M; Yang C Y; Wu Y Q; Thiyagarajan P; Deming T; Akinc M; Schmidt-Rohr K; Mallapragada S . 2009. Self-assembled calcium phosphate nanocomposites using block copolypeptide templates. Soft Matter. 5:4311-4320.
Seok S; Kim T J; Hwang S Y; Kim Y D; Vaknin D; Kim D . 2009. Imaging of Collapsed Fatty Acid Films at Air-Water Interfaces. Langmuir. 25:9262-9269.
Kanapathipillai Mathumai; Mallapragada Surya . 2009. Polymeric Nanomaterials in Biomineralization. International Journal of Nanoscience. 8:473-481.