Publications

Spoerke, Erik D.; Bachand, George B.; Sasaki, Darryl Y.; Stevens, Mark J.; Bollinger, Jonathan B.; Jones, Brad H.; Wheeler, Jill S.; Vervacke, Jeffrey V.; Martinez, Alina M.; mcgrath, dominic m.

Abstract not provided.

Macromolecules

Jones, Brad H.; Wheeler, David R.; Black, Hayden T.; Stavig, Mark E.; Sawyer, P.S.; Giron, Nicholas H.; Celina, Mathias C.; Lambert, Timothy N.; Alam, Todd M.

Physical stress relaxation in rubbery, thermoset polymers is limited by cross-links, which impede segmental motion and restrict relaxation to network defects, such as chain ends. In parallel, the cure shrinkage associated with thermoset polymerizations leads to the development of internal residual stress that cannot be effectively relaxed. Recent strategies have reduced or eliminated such cure stress in thermoset polymers largely by exploiting chemical relaxation processes, wherein temporary cross-links or otherwise transient bonds are incorporated into the polymer network. Here, we explore an alternative approach, wherein physical relaxation is enhanced by the incorporation of organometallic sandwich moieties into the backbone of the polymer network. A standard epoxy resin is cured with a diamine derivative of ferrocene and compared to conventional diamine curing agents. The ferrocene-based thermoset is clearly distinguished from the conventional materials by reduced cure stress with increasing cure temperature as well as unique stress relaxation behavior above its glass transition in the fully cured state. The relaxation experiments exhibit features characteristic of a physical relaxation process. Furthermore, the cure stress is observed to vanish precipitously upon deliberate introduction of network defects through an increasing imbalance of epoxy and amine functional groups. We postulate that these beneficial properties arise from fluxional motion of the cyclopentadienyl ligands on the polymer backbone.

Spoerke, Erik D.; Jones, Brad H.; Martinez, Alina M.; Small, Leo J.; Wheeler, David R.; Wheeler, Jill S.; Bachand, George B.

Abstract not provided.

Jones, Brad H.; Wheeler, David R.; Black, Hayden B.; Stavig, Mark E.; Sawyer, P.S.; Giron, Nicholas H.; Celina, Mathias C.; Lambert, Timothy N.; Alam, Todd M.

Abstract not provided.

Alam, Todd M.; Jones, Brad H.; Black, Hayden B.

Abstract not provided.

Alam, Todd M.; Jones, Brad H.; Black, Hayden B.

Abstract not provided.

Alam, Todd M.; Jones, Brad H.; Black, Hayden B.; Sorte, Eric G.

Abstract not provided.

Journal of the American Ceramic Society

Ihlefeld, Jon I.; Jones, Brad H.; Wheeler, David R.; Rodriguez, Mark A.; McDaniel, Anthony H.; Gurniak, Emily G.

Preparation of sodium zirconium silicate phosphate (NaSICon), Na_1+xZr₂Si_xP_3–xO₁₂ (0.25 ≤ x ≤ 1.0), thin films has been investigated via a chemical solution approach on platinized silicon substrates. Increasing the silicon content resulted in a reduction in the crystallite size and a reduction in the measured ionic conductivity. Processing temperature was also found to affect microstructure and ionic conductivity with higher processing temperatures resulting in larger crystallite sizes and higher ionic conductivities. The highest room temperature sodium ion conductivity was measured for an x = 0.25 composition at 2.3 × 10^–5 S/cm. In conclusion, the decreasing ionic conductivity trends with increasing silicon content and decreasing processing temperature are consistent with grain boundary and defect scattering of conducting ions.

Jones, Brad H.; Rohr, Garth R.; Kaczmarowski, Amy K.

Abstract not provided.

Spoerke, Erik D.; Jones, Brad H.; Wheeler, Jill S.; Martinez, Alina M.; Ting, Christina T.; Stevens, Mark J.; Bachand, George B.

Abstract not provided.

Spoerke, Erik D.; Jones, Brad H.; Martinez, Alina M.; Wheeler, Jill S.; Wheeler, David R.; Ting, Christina T.; Stevens, Mark J.; Bachand, George B.

Abstract not provided.

Greene, Adrienne C.; Jones, Brad H.; Bachand, George B.; Wheeler, David R.; Spoerke, Erik D.

Abstract not provided.

Proceedings of SPIE - The International Society for Optical Engineering

Jones, Brad H.; Rohr, Garth R.; Kaczmarowski, Amy K.

Fiber Bragg gratings (FBGs) are well-suited for embedded sensing of interfacial phenomena in materials systems, due to the sensitivity of their spectral response to locally non-uniform strain fields. Over the last 15 years, FBGs have been successfully employed to sense delamination at interfaces, with a clear emphasis on planar events induced by transverse cracks in fiber-reinforced plastic laminates. We have built upon this work by utilizing FBGs to detect circular delamination events at the interface between epoxy films and alumina substrates. Two different delamination processes are examined, based on stress relief induced by indentation of the epoxy film or by cooling to low temperature. We have characterized the spectral response pre-and post-delamination for both simple and chirped FBGs as a function of delamination size. We show that delamination is readily detected by the evolution of a non-uniform strain distribution along the fiber axis that persists after the stressing condition is removed. These residual strain distributions differ substantially between the delamination processes, with indentation and cooling producing predominantly tensile and compressive strain, respectively, that are well-captured by Gaussian profiles. More importantly, we observe a strong correlation between spectrally-derived measurements, such as spectral widths, and delamination size. Our results further highlight the unique capabilities of FBGs as diagnostic tools for sensing delamination in materials systems.

Spoerke, Erik D.; Jones, Brad H.; Wheeler, Jill S.; Martinez, Alina M.; Ting, Christina T.; Stevens, Mark J.

Abstract not provided.

Tetrahedron Letters

Jones, Brad H.; Wheeler, David R.; Wheeler, Jill S.; Miller, Lance L.; Alam, Todd M.; Spoerke, Erik D.

Deboronation is observed during the reductive amination of formylphenylboronic acid (FPBA) to the amine termini and side chains of peptides. This deboronation is sensitive to the isomerism of the boronic acid (BA), with ortho-FPBA yielding complete deboronation in the preparation of an N-terminally-modified dipeptide. The observed behavior is also clearly mediated by the chemical identity of the amine substrate. These results reveal a previously undocumented subtlety of BA functionalization and highlight the importance of thorough spectroscopic characterization in the preparation of peptide and small molecule BAs.

ChemComm

Jones, Brad H.; Martinez, Alina M.; Wheeler, Jill S.; McKenzie, Bonnie B.; Miller, Lance L.; Wheeler, David R.; Spoerke, Erik D.

Modification of the dipeptide of phenylalanine, FF, with a boronic acid (BA) functionality imparts unique aqueous self-assembly behavior that responds to multiple stimuli. Changes in pH and ionic strength are used to trigger hydrogelation via the formation of nanoribbon networks. Thus, we show for the first time that the binding of polyols to the BA functionality can modulate a peptide between its assembled and disassembled states.

Soft Matter

Jones, Brad H.; Martinez, Alina M.; Wheeler, Jill S.; Spoerke, Erik D.

The secondary structure of peptides in the presence of interacting additives is an important topic of study, having implications in the application of peptide science to a broad range of modern technologies. Surfactants constitute a class of biologically relevant compounds that are known to influence both peptide conformation and aggregation or assembly. We have characterized the secondary structure of a linear nonapeptide composed of a hydrophobic alanine/phenylalanine core flanked by hydrophilic acid/amine units. We show that the anionic surfactant sodium dodecyl sulfate (SDS) induces the formation of β-sheets and macroscopic gelation in this otherwise unstructured peptide. Through comparison to related additives, we propose that SDS-induced secondary structure formation is the result of amphiphilicity created by electrostatic binding of SDS to the peptide. In addition, we demonstrate a novel utility of surfactants in manipulating and stabilizing peptide nanostructures. SDS is used to simultaneously induce secondary structure in a peptide and to inhibit the activity of a model enzyme, resulting in a peptide hydrogel that is impervious to enzymatic degradation. These results complement our understanding of the behavior of peptides in the presence of interacting secondary molecules and provide new potential pathways for programmable organization of peptides by the addition of such components.

Jones, Brad H.; Martinez, Alina M.; Wheeler, Jill S.; McKenzie, Bonnie B.; Wheeler, David R.; Spoerke, Erik D.

Abstract not provided.

Jones, Brad H.; Martinez, Alina M.; Wheeler, Jill S.; Wheeler, David R.; Spoerke, Erik D.

Abstract not provided.

Martinez, Alina M.; Jones, Brad H.; Spoerke, Erik D.; Wheeler, Jill S.

Abstract not provided.

Jones, Brad H.; Martinez, Alina M.; Wheeler, Jill S.; McKenzie, Bonnie B.; Wheeler, David R.; Spoerke, Erik D.

Abstract not provided.