Publications

Spoerke, Erik D.; Zarick, Holly F.

Abstract not provided.

Carbon

Spoerke, Erik D.; Polsky, Ronen P.; Burckel, David B.; Bunker, B.C.

Abstract not provided.

Spoerke, Erik D.; Brumbach, Michael T.; Meyer, Kelsey M.; Bunker, B.C.

Abstract not provided.

Hsu, Julia W.; Spoerke, Erik D.; Davis, Robert J.

Abstract not provided.

Sasaki, Darryl Y.; Bunker, B.C.; Spoerke, Erik D.; Bachand, George B.

Abstract not provided.

Spoerke, Erik D.; Davis, Robert J.; Voigt, James A.; Hsu, Julia W.

Abstract not provided.

Spoerke, Erik D.

Abstract not provided.

Lee, Yun-Ju L.; Lloyd, Matthew T.; Spoerke, Erik D.; Davis, Robert J.; Voigt, James A.; Hsu, Julia W.

Abstract not provided.

Spoerke, Erik D.

Abstract not provided.

Hsu, Julia W.; Lee, Mark L.; Spoerke, Erik D.; Lee, Yun-Ju L.; Highstrete, Clark H.

Abstract not provided.

Spoerke, Erik D.

Abstract not provided.

Crystal Growth and Design

Lee, Yun J.; Sounart, Thomas L.; Liu, Jun; Spoerke, Erik D.; McKenzie, Bonnie B.; Hsu, Julia W.; Voigt, James A.

We have systematically studied the effect of pH and 1,3-diaminopropane additive concentration on the morphology of ZnO nanorod and nanoneedle arrays grown in aqueous solution using a variety of seed layers. Increase in the growth solution pH from 6.8 to 13.2 resulted in a near doubling of the growth rate in the [0001] direction possibly due to attractive interaction between the zinc species and the growth surface at high pH, leading to nanorod arrays with reduced faceting and higher aspect ratios. Increases in 1,3-diaminopropane concentration initially enhanced and subsequently inhibited growth of tapered ZnO nanoneedles on seed layers consisting of ZnO nanoparticles, oriented ZnO films, or columnar facets of ZnO microrods. The final nanoneedle dimensions, packing density, and alignment were strongly affected by 1,3-diaminopropane concentration and seed layer type, which can be explained in terms of the relative strength of zinc chelation by 1,3-diaminopropane, the areal density of seeds, and other factors. The precise tuning of ZnO crystalline morphology via the control of seeding and growth conditions may be beneficial to many potential applications that require these aligned crystalline nanostructures. © 2008 American Chemical Society.

Garino, Terry J.; Voigt, James A.; Spoerke, Erik D.; Sipola, Diana L.; Lockwood, Steven J.; Yang, Pin Y.; Gibson, Julie T.

Abstract not provided.

Bachand, George B.; Bunker, B.C.; Spoerke, Erik D.

Abstract not provided.

Hsu, Julia W.; Lee, Mark L.; Highstrete, Clark H.; Lee, Yun-Ju L.; Howell, Stephen W.; Spoerke, Erik D.

Abstract not provided.

Bachand, George B.; Orendorff, Christopher O.; McKenzie, Bonnie B.; Bunker, B.C.; Spoerke, Erik D.

Microtubules and motor proteins are protein-based biological agents that work cooperatively to facilitate the organization and transport of nanomaterials within living organisms. This report describes the application of these biological agents as tools in a novel, interdisciplinary scheme for assembling integrated nanostructures. Specifically, selective chemistries were used to direct the favorable adsorption of active motor proteins onto lithographically-defined gold electrodes. Taking advantage of the specific affinity these motor proteins have for microtubules, the motor proteins were used to capture polymerized microtubules out of suspension to form dense patterns of microtubules and microtubule bridges between gold electrodes. These microtubules were then used as biofunctionalized templates to direct the organization of functionalized nanocargo including single-walled carbon nanotubes and gold nanoparticles. This biologically-mediated scheme for nanomaterials assembly has shown excellent promise as a foundation for developing new biohybrid approaches to nanoscale manufacturing.

Proposed for publication in Advanced Materials.

Sounart, Thomas L.; Voigt, James A.; Hsu, Julia W.; Spoerke, Erik D.

Abstract not provided.

Proposed for publication in Nano Letters.

Spoerke, Erik D.; Bachand, George B.; Sasaki, Darryl Y.; Bunker, B.C.

Abstract not provided.

Spoerke, Erik D.; Sounart, Thomas L.; Voigt, James A.; McKenzie, Bonnie B.

Abstract not provided.

Sasaki, Darryl Y.; Koch, Steven J.; Thayer, Gayle E.; Corwin, Alex D.; De Boer, Maarten P.; Bunker, B.C.; Bachand, George B.; Rivera, Susan B.; Gaudioso, Jennifer M.; Trent, Amanda M.; Spoerke, Erik D.

The formation and functions of living materials and organisms are fundamentally different from those of synthetic materials and devices. Synthetic materials tend to have static structures, and are not capable of adapting to the functional needs of changing environments. In contrast, living systems utilize energy to create, heal, reconfigure, and dismantle materials in a dynamic, non-equilibrium fashion. The overall goal of the project was to organize and reconfigure functional assemblies of nanoparticles using strategies that mimic those found in living systems. Active assembly of nanostructures was studied using active biomolecules to drive the organization and assembly of nanocomposite materials. In this system, kinesin motor proteins and microtubules were used to direct the transport and interactions of nanoparticles at synthetic interfaces. In addition, the kinesin/microtubule transport system was used to actively assemble nanocomposite materials capable of storing significant elastic energy. Novel biophysical measurement tools were also developed for measuring the collective force generated by kinesin motor proteins, which will provide insight on the mechanical constraints of active assembly processes. Responsive reconfiguration of nanostructures was studied in terms of using active biomolecules to mediate the optical properties of quantum dot (QD) arrays through modulation of inter-particle spacing and associated energy transfer interaction. Design rules for kinesin-based transport of a wide range of nanoscale cargo (e.g., nanocrystal quantum dots, micron-sized polymer spheres) were developed. Three-dimensional microtubule organizing centers were assembled in which the polar orientation of the microtubules was controlled by a multi-staged assembly process. Overall, a number of enabling technologies were developed over the course of this project, and will drive the exploitation of energy-driven processes to regulate the assembly, disassembly, and dynamic reorganization of nanomaterials.

Voigt, James A.; Hsu, Julia W.; McKenzie, Bonnie B.; Spoerke, Erik D.

Abstract not provided.

Sounart, Thomas L.; McKenzie, Bonnie B.; Spoerke, Erik D.; Voigt, James A.

Abstract not provided.

Spoerke, Erik D.; Voigt, James A.; Hsu, Julia W.

Abstract not provided.

Hsu, Julia W.; Spoerke, Erik D.; Sounart, Thomas L.; Simmons, Neil C.; McKenzie, Bonnie B.; Chang, Nolanne A.; Voigt, James A.

Abstract not provided.

Criscenti, Louise C.; Spoerke, Erik D.; McKenzie, Bonnie B.; Cygan, Randall T.; Voigt, James A.

Solution-based synthesis is a powerful approach for creating nano-structured materials. Although there have been significant recent successes in its application to fabricating nanomaterials, the general principles that control solution synthesis are not well understood. The purpose of this LDRD project was to develop the scientific principles required to design and build unique nanostructures in crystalline oxides and II/VI semiconductors using solution-based molecular self-assembly techniques. The ability to synthesize these materials in a range of different nano-architectures (from controlled morphology nanocrystals to surface templated 3-D structures) has provided the foundation for new opportunities in such areas as interactive interfaces for optics, electronics, and sensors. The homogeneous precipitation of ZnO in aqueous solution was used primarily as the model system for the project. We developed a low temperature, aqueous solution synthesis route for preparation of large arrays of oriented ZnO nanostructures. Through control of heterogeneous nucleation and growth, methods to predicatively alter the ZnO microstructures by tailoring the surface chemistry of the crystals were established. Molecular mechanics simulations, involving single point energy calculations and full geometry optimizations, were developed to assist in selecting appropriate chemical systems and understanding physical adsorption and ultimately growth mechanisms in the design of oxide nanoarrays. The versatility of peptide chemistry in controlling the formation of cadmium sulfide nanoparticles and zinc oxide/cadmium sulfide heterostructures was also demonstrated.