Search Results - "Galloway, Johanna M."

Self-assembled MmsF proteinosomes control magnetite nanoparticle formation in vitro by Rawlings, Andrea E., Bramble, Jonathan P., Walker, Robyn, Bain, Jennifer, Galloway, Johanna M., Staniland, Sarah S.

“…Magnetotactic bacteria synthesize highly uniform intracellular magnetite nanoparticles through the action of several key biomineralization proteins. These…”
Get full text

Bioinspired Silicification Reveals Structural Detail in Self-Assembled Peptide Cages by Galloway, Johanna M, Senior, Laura, Fletcher, Jordan M, Beesley, Joseph L, Hodgson, Lorna R, Harniman, Robert L, Mantell, Judith M, Coombs, Jennifer, Rhys, Guto G, Xue, Wei-Feng, Mosayebi, Majid, Linden, Noah, Liverpool, Tanniemola B, Curnow, Paul, Verkade, Paul, Woolfson, Derek N

“…Understanding how molecules in self-assembled soft-matter nanostructures are organized is essential for improving the design of next-generation nanomaterials…”
Get full text

De Novo Designed Peptide and Protein Hairpins Self‐Assemble into Sheets and Nanoparticles by Galloway, Johanna M., Bray, Harriet E. V., Shoemark, Deborah K., Hodgson, Lorna R., Coombs, Jennifer, Mantell, Judith M., Rose, Ruth S., Ross, James F., Morris, Caroline, Harniman, Robert L., Wood, Christopher W., Arthur, Christopher, Verkade, Paul, Woolfson, Derek N.

“…The design and assembly of peptide‐based materials has advanced considerably, leading to a variety of fibrous, sheet, and nanoparticle structures. A remaining…”
Get full text

Electron transparent nanotubes reveal crystallization pathways in confinement by Galloway, Johanna M, Aslam, Zabeada P, Yeandel, Stephen R, Kulak, Alexander, Ilett, Martha A, Kim, Yi-Yeoun, Bejarano-Villafuerte, Angela, Pokroy, Boaz, Drummond-Brydson, Rik M, Freeman, Colin L, Harding, John H, Kapur, Nikil, Meldrum, Fiona C

“…The cylindrical pores of track-etched membranes offer excellent environments for studying the effects of confinement on crystallization as the pore diameter is…”
Get full text

Universality of Hair as a Nucleant: Exploring the Effects of Surface Chemistry and Topography by Dunn, Thomas H, Skaanvik, Sebastian A, McPherson, Ian J, O'Shaughnessy, Cedrick, He, Xuefeng, Kulak, Alexander N, Micklethwaite, Stuart, Matamoros-Veloza, Adriana, Sandei, Ilaria, Hunter, Liam, Turner, Thomas D, Galloway, Johanna M, Rosenthal, Martin, Britton, Andrew J, Walker, Marc, Dong, Mingdong, Unwin, Patrick R, Meldrum, Fiona C

“…The ability to control crystal nucleation through the simple addition of a nucleating agent (nucleant) is desirable for a huge range of applications. However,…”
Get full text

Biomimetic Synthesis of Materials for Technology by Galloway, Johanna M., Bramble, Jonathan P., Staniland, Sarah S.

“…In a world with ever decreasing natural reserves, researchers are striving to find sustainable methods of producing components for technology. Bioinspired,…”
Get full text

Taking a hard line with biotemplating: cobalt-doped magnetite magnetic nanoparticle arrays by Bird, Scott M, Galloway, Johanna M, Rawlings, Andrea E, Bramble, Jonathan P, Staniland, Sarah S

“…Rapid advancements made in technology, and the drive towards miniaturisation, means that we require reliable, sustainable and cost effective methods of…”
Get more information

Biotemplated Magnetic Nanoparticle Arrays by Galloway, Johanna M., Bramble, Jonathan P., Rawlings, Andrea E., Burnell, Gavin, Evans, Stephen D., Staniland, Sarah S.

“…Immobilized biomineralizing protein Mms6 templates the formation of uniform magnetite nanoparticles in situ when selectively patterned onto a surface. Magnetic…”
Get full text

Nanoparticle Arrays: Biotemplated Magnetic Nanoparticle Arrays (Small 2/2012) by Galloway, Johanna M., Bramble, Jonathan P., Rawlings, Andrea E., Burnell, Gavin, Evans, Stephen D., Staniland, Sarah S.

“…A biomineralization protein from magnetotactic bacteria (Mms6) used to control both the formation and location of magnetic nanoparticles in a patterned array…”
Get full text

Developing Biotemplated Data Storage: Room Temperature Biomineralization of L10 CoPt Magnetic Nanoparticles by Galloway, Johanna M., Talbot, Jennifer E., Critchley, Kevin, Miles, Jim J., Bramble, Jonathan P.

“…L10 cobalt platinum can be used to record data at approximately sixfold higher densities than it is possible to on existing hard disks. Currently, fabricating…”
Get full text

Data Storage: Developing Biotemplated Data Storage: Room Temperature Biomineralization of L10 CoPt Magnetic Nanoparticles (Adv. Funct. Mater. 29/2015) by Galloway, Johanna M., Talbot, Jennifer E., Critchley, Kevin, Miles, Jim J., Bramble, Jonathan P.

“…L10 CoPt can be used in data storage, but high temperatures (500 °C) are usually needed to achieve this. On page 4590, J. Galloway and colleagues demonstrate a…”
Get full text

Developing Biotemplated Data Storage: Room Temperature Biomineralization of L1 sub(0) CoPt Magnetic Nanoparticles by Galloway, Johanna M, Talbot, Jennifer E, Critchley, Kevin, Miles, Jim J, Bramble, Jonathan P

“…L1 sub(0) cobalt platinum can be used to record data at approximately sixfold higher densities than it is possible to on existing hard disks. Currently,…”
Get full text

Developing Biotemplated Data Storage: Room Temperature Biomineralization of L1 0 CoPt Magnetic Nanoparticles by Galloway, Johanna M., Talbot, Jennifer E., Critchley, Kevin, Miles, Jim J., Bramble, Jonathan P.

“…L1 0 cobalt platinum can be used to record data at approximately sixfold higher densities than it is possible to on existing hard disks. Currently, fabricating…”
Get full text

Data Storage: Developing Biotemplated Data Storage: Room Temperature Biomineralization of L1 0 CoPt Magnetic Nanoparticles (Adv. Funct. Mater. 29/2015) by Galloway, Johanna M., Talbot, Jennifer E., Critchley, Kevin, Miles, Jim J., Bramble, Jonathan P.

Get full text