NANOFABRICATION RELATED PAPERS
Hong-Kai Dai, Cheng-Bei Xie, Hui-Chao Liang, Lin-Yong Qian, Cai-Qin Han, Chang-Chun Yan, and Yi-Ping Zhao,"Growth and optical properties of Ag-Ti composite nanorods based on oblique angle co-deposition technique," Optics Express 26, 12022 - 12037 (2018).
Hong-Feng Wang, Jun-Xian Shi, Lin-Yong Qian, Chang-Chun Yan, Cai-Qin Han, and Yi-Ping Zhao, "Large-area broadband optical absorber fabricated by shadowing sphere lithography," Optics Express 26, 7507 - 7515 (2018).
Steven R Larson and Yiping Zhao, "The localized surface plasmonic resonance and sensing properties of Ag-MgF2 composite nanotriangles," J. Phys. Chem. C 122, 7374 - 7381 (2018).
Connor Skehan, Bin Ai, Steven R Larson, Keenan M Stone, William M Dennis, and Yiping Zhao, "Optimized fan-shaped chiral metamaterial as an ultrathin narrow-band circular polarizer at visible frequencies," Nanotechnology 29, 165301 (2018).
Bin Ai, Pradip Basnet, Steven Larson, Whitney Ingram, and Yiping Zhao, "Plasmonic Sensor with High Figure of Merit Based on Differential Polarization Spectra of Elliptical Nanohole Array," Nanoscale 9, 14710-14721 (2017).
Whitney Ingram, Steven Larson, Daniel Carlson, and Yiping Zhao, "Ag-Cu mixed phase plasmonic nanostructures fabricated by shadow nanosphere llithography and glancing angle co-deposition," Nanotechnology 28, 015301 (2017).
Whitney Ingram, Yizhuo He, Dexian Ye, Keenan Stone, William Dennis, and Yiping Zhao, "Tuning the plasmonic properties of Silver nanopatterns fabricated by shadow nanosphere lithography," Nanotechnology 27, 385301 (2016).
Steven Larson, Weijie Huang, and Yiping Zhao, "Combinatorial fabrication of composite nanorods using oblique angle co-deposition," Nanotechnology 27, 365304 (2016).
Layne Bradley, George Larsen, and Yiping Zhao, "Designed to fail – flexible, anisotropic Silver nanorod sheets for low-cost wireless activity monitoring," Journal of Physical Chemistry C 120, 14969 - 14976 (2016).
Layne Bradley and Yiping Zhao, "Uniform plasmonic response of colloidal Ag patchy particles prepared by swinging oblique angle deposition," Langmuir 32, 4969 - 4974 (2016).
Yizhuo He, George Larsen, Xibo Li, Whitney Ingram, Funing Chen, and Yiping Zhao, "Nanoscale conical Swiss roll with broadband visible and near-IR circular dichroism," Advanced Optical Materials 3, 342 - 346 (2015).
Yiping Zhao, "Dynamic shadowing growth and its energy applications," Frontiers in Energy Research, doi: 10.3389/fenrg.2014.00038 (2014).
George K. Larsen, Yizhuo He, Whitney Ingram, Ethan T. LaPaquette, Jing Wang, and Yiping Zhao, "The fabrication of three-dimensional plasmonic chiral structures by dynamic shadowing growth," Nanoscale 6, 9467–9476 (2014).
Kun Yao, Ryan Toole, Pradip Basnet, and Yiping Zhao, “Highly sensitive double-layered nanorod array gas sensors prepared by oblique angle deposition,” Appl. Phys. Lett. 104, 073110 (2014).
George K. Larsen, Yizhuo He, Jin Wang, and Yiping Zhao, "Scalable fabrication of composite Ti/Ag plasmonic helices: controlling morphology and optical activity by tailoring material properties," Adv. Opt. Mat. 2, 245–249 (2014).
Yizhuo He, Junxue Fu, and Yiping Zhao, "Oblique angle deposition and its applications in plasmonics," Frontiers of Physics 9, 47–59 (2014).
C. Y. Song, G. K. Larsen, and Y.-P. Zhao, "Anisotropic Resistivity of Tilted Silver Nanorod Arrays: Experiments and Modeling," Appl. Phys. Lett. 102, 233101 (2013).
Pradip Basneta, George K. Larsena, Ravirajsinh P. Jadeja, Yen-Con Hung, and Yiping Zhao, "α-Fe2O3 Nanocolumns and Nanorods Fabricated by Electron Beam Evaporation for Visible Light Photocatalytic and Antimicrobial Applications," ACS App. Mater. Interfaces 5, 2085–2095(2013).
J.P. Singh, Thomas E. Lanier, Hao Zhu, William M. Dennis, Ralph A. Tripp, and Yiping Zhao, "Highly sensitive and transparent surface enhanced Raman scattering substrates made by active coldly condensed Ag nanorod arrays," J. Phys. Chem. C 116, 20550 (2012).
Yuping He, Cameron Brown, Cynthia A. Lundgren, and Yiping Zhao, "The growth of CuSi composite nanorod arrays by oblique angle co-deposition, and their structural, electrical, and optical properties," Nanotechnology 23, 365703 (2012).
Yuping He, Cameron Brown, Yizhuo He, Jianguo Fan,Cynthia A. Lundgrenc and Yiping Zhao, "Porous three-dimensional nanorod arrays through selective chemical etching of nanocomposites," Chem. Com. 48, 7741-7743 (2012).
George K. Larsen, Bob C. Fitzmorris, Claudia Longo, Jin Z. Zhang, and Yiping Zhao, "Nanostructured Homogenous CdSe/TiO2 Composite Visible Light Photoanodes Fabricated by Oblique Angle Codeposition," Journal of Materials Chemistry 22, 14205-14218 (2012).
Hao Zhu, Wei Cao, George K. Larsen, Ryan Toole, and Yiping Zhao, “Tilting angle of nanocolumnar films fabricated by oblique angle deposition,”Journal of Vacuum Science and Technology B 30, 030606 (2012).
J. P. Singh, HsiaoYun Chu, Justin Abell, Ralph A. Tripp, and Yiping Zhao, “Flexible and mechanical strain resistant large area SERS active substrates,” Nanoscale 4, 3410-3414 (2012).
Qin Zhou, Xian Zhang, Yu Huang, Zhengcao Li,Yiping Zhao, and Zhengjun Zhang, "Enhanced SERS performance by folding Silver nanorods," Appl. Phys. Lett. 100, 113101 (2012).
Yuping He, Bo Yang, Kaikun Yang,Cameron Brown,Ramaraja Ramasamy,Howard Wang,Cynthia Lundgren,and Yiping Zhao, "Designing Si-based nanowall arrays by dynamic shadowing growth to tailor the performance of Li-ion battery anodes," Journal of Materials Chemistry 22, 8294-8303 (2012).
Y.-P. Zhao, Y.-P. He, and C. Brown, "Composition dependent nanocolumn tilting angle during the oblique angle co-deposition," Appl. Phys. Lett. 100, 033106 (2012).
X. J. Wang, A. M. Haider, J. L. Abell, Y.-P. Zhao, and Z. M. Zhang, "Anisotropic diffraction from inclined Silver nanorod arrays on grating templates," Nanoscale and Microscale Thermophysical Engineering 16, 18-36 (2012).
C.-Y. Song, J. L. Abell, Y. -P. He, S. H. Murph, Y. -P. Cui, and Y. -P. Zhao, "Gold-modified Silver nanorod arrays: growth dynamics and improved SERS properties," Journal of Materials Chemistry 22, 1150-1159 (2012).
C.-Y. Song, J. Chen, J. L. Abell, Y.-P. Cui, and Y.-P. Zhao, "Ag-SiO2 core-shell nanorod arrays: morphological, optical, SERS, and wetting properties," Langmuir 28, 1488–1495 (2012).
Y.-P. He and Y.-P. Zhao, "Advanced multi-component nanostructures designed by dynamic shadowing growth," Nanoscale 3, 2361-2375 (2011).
Yuping He, Jianguo Fan, and Yiping Zhao, “Engineering a Well-Aligned Composition-Graded CuSi Nanorod Array by an Oblique Angle Co-Deposition Technique,” Crystal Growth & Design 10, 4954–4958 (2010).
Y.-P. He and Y.-P. Zhao, “Mg nanostructures tailored by glancing angle deposition,” Crystal Growth & Design 10， 440–448 (2010).
Y.-P. He, Z.-Y. Zhang, C. Hoffmann, and Y.-P. Zhao, “Embedding Ag nanoparticles into MgF2 nanorod arrays ,” Advanced Functional Materials 18, 1676–1684 (2008).
J.-X. Fu, Y.-P. He, and Y.-P. Zhao, “Fabrication of heteronanorod structures by dynamic shadowing growth,” IEEE Sensors 8, 989–997 (2008).
Y.-P. He, Y.-P. Zhao, and J.-S. Wu, “The effect of Ti doping on the growth of Mg nanostructures by oblique angle co-deposition ,” Appl. Phys. Lett. 92, 063107 (2008).
Y. He, J. Fu, Y. Zhang, Y. Zhao, L. Zhang, A. Xia, and J. Cai, "Multilayered Si/Ni nanosprings and their magnetic properties," Small 3, 153–160 (2007).
J.-G. Fan and Y.-P. Zhao, “Direct deposition of aligned nanorod array onto cylindrical objects,” J. Vac. Sci. Technol. B 23, 947–953 (2005).
T. Karabacak, J. P. Singh, Y.-P. Zhao, G.-C. Wang, and T.-M. Lu, “Scaling during shadowing growth of isolated nanocolumns ,” Phys. Rev. B 68, 125408 (2003).
D.-X. Ye, Y.-P. Zhao, G.-R. Yang, Y.-G. Zhao, G.-C. Wang, and T.-M. Lu, “Manipulating the column tilt angles of nanocolumnar films by glancing angle deposition, ” Nanotechnology 13, 615–618 (2002).
Y.-P. Zhao, D.-X. Ye, G.-C. Wang, and T.-M. Lu, “Novel nano-column and nano-flower arrays by glancing angle deposition, ” Nano Letters 2, 351–354 (2002).
Y.-P. Zhao, D.-X. Ye, Pei-I Wang, G.-C. Wang, and T.-M. Lu, “Fabrication Si nano-columns and square springs on self-assembly colloid substrates, ” International Journal of Nanoscience 1, 87 (2002).