Publications

[9] L. Yu, R. Han, X. Sang, J. Liu, M. P. Thomas, B. M. Hudak, A. Patel, K. Page, and B. S. Guiton; Shell-Induced Ostwald Ripening: Simultaneous Structure, Composition, and Morphology Transformations During the Creation of Hollow Iron Oxide Nanocapsules. ACS Nano, August 2018. DOI: 10.1021/acsnano.8b02946

Fig for highlight — False-colored, STEM-HAADF image of six subsurface bismuth atoms (circled) in silicon positioned with the electron beam to form a nearly perfect triangular lattice. From “Directed atom-by-atom assembly of dopants in silicon.“

[8] B. H. Hudak, J. Song, H. Sims, M. C. Troparevsky, T. S. Humble, S. T. Pantelides, P. C. Snijders, and A. R. Lupini; Directed atom-by-atom assembly of dopants in silicon. ACS Nano, 12, 5873-5879, (2018). Check out the LiveSlides, where you can hear me describe this work and why it’s important!

This work featured as an ORNL story tip.

[7] S. Jesse*, B. M. Hudak*, E. Zarkadoula, J. Song, A. Maksov, M. Fuentes-Cabrera, P. Ganesh, I. Kravchenko, P. C. Snijders, A. R. Lupini, A. Borisevich, and S. V. Kalinin; Direct atomic fabrication and dopant positioning in Si using electron beams with active real time image-based feedback. Nanotechnology. 29, 255303, (2018). *equal contribution

[6] J. Song, B. M. Hudak, H. Sims, Y. Sharma, T. Z. Ward, S. T. Pantelides, A. R. Lupini, and P. C. Snijders; Homo-endotaxial one-dimensional Si nanostructures. Nanoscale. 10, 260-267, (2017).

[5] B. M. Hudak, S. W. Depner, G. R. Waetzig, A. Talapatra, R. Arroyave, S. Banerjee, and B. S. Guiton; Real-time atomistic observation of structural phase transformations in individual hafnia nanorods. Nature Communications. 8, 15316, (2017).

[4] L. Yu, Y. Zhang, B. M. Hudak, D. K. Wallace, D. Y. Kim, and B. S. Guiton; Simple synthetic route to manganese-containing nanowires with the spinel crystal structure. Journal of Solid State Chemistry. 240, 23-29, (2016).

[3] J. Mackey, F. Dynys, B. M. Hudak, B. S. Guiton, and A. Sehirlioglu; Co_xNi_4-xSb_12-ySn_y Skutterudites: processing and thermoelectric properties.^† Journal of Materials Science. 51, 6117-6132, (2016). ^†STEM data featured on cover.

[2] G. Li, L. Yu, B. M. Hudak, Y.-J. Chang, H. Baek, A. Shundararajan, D. R. Strachan, G.-C. Yi, and B. S. Guiton; Direct observation of Li diffusion in Li-doped ZnO nanowires.^‡ Material Research Express. 3, 054001, (2016). ^‡Focus paper.

[1] B. M. Hudak, Y.-J. Chang, L. Yu, G. Li, D. N. Edwards, and B. S. Guiton; Real-time observation of the solid-liquid-vapor dissolution of individual Tin(IV) Oxide nanowires. ACS Nano. 8, 5441-5448, (2014).

Video from Real-time observation of the solid-liquid-vapor dissolution of individual Tin(IV) Oxide nanowires showing dissolution of tin(IV) oxide into gold nanoparticle in a process dubbed solid-liquid-vapor (SLV) dissolution.

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