Size-controlled highly luminescent silicon nanocrystals: A superlattice approach M Zacharias, J Heitmann, R Scholz, U Kahler, M Schmidt, J Bläsing Applied Physics Letters 80 (4), 661-663, 2002 | 1087 | 2002 |
Formation of nanotubes and hollow nanoparticles based on Kirkendall and diffusion processes: a review HJ Fan, U Gösele, M Zacharias small 3 (10), 1660-1671, 2007 | 1046 | 2007 |
Semiconductor nanowires: from self‐organization to patterned growth HJ Fan, P Werner, M Zacharias small 2 (6), 700-717, 2006 | 978 | 2006 |
Monocrystalline spinel nanotube fabrication based on the Kirkendall effect H Jin Fan, M Knez, R Scholz, K Nielsch, E Pippel, D Hesse, M Zacharias, ... Nature materials 5 (8), 627-631, 2006 | 770 | 2006 |
Classification and control of the origin of photoluminescence from Si nanocrystals S Godefroo, M Hayne, M Jivanescu, A Stesmans, M Zacharias, ... Nature nanotechnology 3 (3), 174-178, 2008 | 648 | 2008 |
Nanowire‐based sensors NS Ramgir, Y Yang, M Zacharias small 6 (16), 1705-1722, 2010 | 440 | 2010 |
Influence of surface diffusion on the formation of hollow nanostructures induced by the Kirkendall effect: the basic concept HJ Fan, M Knez, R Scholz, D Hesse, K Nielsch, M Zacharias, U Gösele Nano letters 7 (4), 993-997, 2007 | 425 | 2007 |
Silicon nanocrystals: size matters J Heitmann, F Müller, M Zacharias, U Gösele Advanced Materials 17 (7), 795-803, 2005 | 393 | 2005 |
Nanocrystalline-silicon superlattice produced by controlled recrystallization L Tsybeskov, KD Hirschman, SP Duttagupta, M Zacharias, PM Fauchet, ... Applied Physics Letters 72 (1), 43-45, 1998 | 347 | 1998 |
Blue luminescence in films containing Ge and nanocrystals: The role of defects M Zacharias, PM Fauchet Applied Physics Letters 71 (3), 380-382, 1997 | 320 | 1997 |
Crystallization of amorphous superlattices in the limit of ultrathin films with oxide interfaces M Zacharias, P Streitenberger Physical Review B 62 (12), 8391, 2000 | 292 | 2000 |
Template‐assisted large‐scale ordered arrays of ZnO pillars for optical and piezoelectric applications HJ Fan, W Lee, R Hauschild, M Alexe, G Le Rhun, R Scholz, A Dadgar, ... Small 2 (4), 561-568, 2006 | 255 | 2006 |
Excitons in Si nanocrystals: confinement and migration effects J Heitmann, F Müller, L Yi, M Zacharias, D Kovalev, F Eichhorn Physical Review B 69 (19), 195309, 2004 | 245 | 2004 |
Thermal crystallization of amorphous superlattices M Zacharias, J Bläsing, P Veit, L Tsybeskov, K Hirschman, PM Fauchet Applied physics letters 74 (18), 2614-2616, 1999 | 237 | 1999 |
Si rings, Si clusters, and Si nanocrystals—different states of ultrathin layers LX Yi, J Heitmann, R Scholz, M Zacharias Applied Physics Letters 81 (22), 4248-4250, 2002 | 236 | 2002 |
Quantum confinement in nanoscale silicon: The correlation of size with bandgap and luminescence J Von Behren, T Van Buuren, M Zacharias, EH Chimowitz, PM Fauchet Solid state communications 105 (5), 317-322, 1998 | 204 | 1998 |
Arrays of vertically aligned and hexagonally arranged ZnO nanowires: a new template-directed approach HJ Fan, W Lee, R Scholz, A Dadgar, A Krost, K Nielsch, M Zacharias Nanotechnology 16 (6), 913, 2005 | 201 | 2005 |
Enhanced surface-excitonic emission in ZnO/Al2O3 core–shell nanowires JP Richters, T Voss, DS Kim, R Scholz, M Zacharias Nanotechnology 19 (30), 305202, 2008 | 200 | 2008 |
Fracture strength and Young’s modulus of ZnO nanowires S Hoffmann, F Östlund, J Michler, HJ Fan, M Zacharias, SH Christiansen, ... Nanotechnology 18 (20), 205503, 2007 | 194 | 2007 |
Multilevel charge storage in silicon nanocrystal multilayers TZ Lu, M Alexe, R Scholz, V Talelaev, M Zacharias Applied Physics Letters 87 (20), 2005 | 187 | 2005 |