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51800. Chen, J., Jin, Y., Effect of water volume on the growthof silver nanoparticles promoted by ultraviolet, AdvancedMaterials Research 96, 55 (2010)801. Amendola, V; Bakr, OM; Stellacci, F A Study of theSurface Plasmon Resonance of Silver Nanoparticles bythe Discrete Dipole Approximation Method: Effect ofShape, Size, Structure, and Assembly, PLASMONICS5 (1): 85 (2010)802. Sau, T.K., Rogach, A.L., Jackel, F., Klar, T.A.,Feldmann, J. Properties and applications of colloidalnonspherical noble metal nanoparticles, 2010 AdvancedMaterials 22 (16), pp. 1805-1825803. Calandra, P., Ruggirello, A., Pistone, A., Liveri, V.T.Structural and Optical Properties of Novel SurfactantCoated TiO2-Ag Based Nanoparticles, (2010) Journalof Cluster Science, 21 (4) pp. 767-778.804. Yang, P., Portales, H., Pilenia, M.-P. 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Greensynthesis of sucralose-capped silver nanoparticles forfast colorimetric triethylamine detection, 2013, Sensorsand Actuators, B: Chemical 178 , pp. 1-9814. Kusada, K., Kobayashi, H., Yamamoto, T., Matsumura,S., Sumi, N., Sato, K., Nagaoka, K., Kubota,Y; Kitagawa, H. Discovery of face-centered-cubicruthenium nanoparticles: Facile size-controlled synthesisusing the chemical reduction method, 2013, J AmChem. Soc 135 (15) , pp. 5493-5496815. Walekar, L.S., Gore, A.H., Anbhule, P.V., Sudarsan,V., Patil, S.R., Kolekar, G.B. A novel colorimetricprobe for highly selective recognition of Hg 2+ ionsin aqueous media based on inducing the aggregationof CPB-capped AgNPs: Accelerating direct detectionfor environmental analysis, 2013, Analytical Methods5 (20) , pp. 5501-5507Artículo:Reconstruction of quasi-1D In/Si(111) systems: Chargeand spin density waves versus bonding, X. López-Lozano,A. Krivosheeva, A. Stekolnikov, L. Meza-Montes, CeciliaNoguez, J. Furtmueller, and F. Bechstedt, PhysicalReview B 73, 035430 (2006)Lo citan (32):816. Fleischer K, Chandola S, Esser N, McGilp JF; Opticalproperties of indium nanowires - an adsorption study,Phys Status Solidi (b) 242, 2655 (2005)817. Crain, J.N., Himpsel, F.J., Low-dimensional electronicstates at silicon surfaces, Applied Physics A 82, 431(2006)818. A. A. Saranin, A. V. Zotov, M. Kishida, Y. Murata, S.Honda, M. Katayama, K. Oura, D. V. Gruznev, A. Visikovskiy,H. Tochihara , Reversible phase transitionsin the pseudomorphic 7 × 3-hex in layer on Si(111),Phys. Rev. B 74, 035436 (2006)819. B S. Mendoza, F. Nastos, N. Arzate, J. E. Sipe, Layerby-layeranalysis of the linear optical response of cleanand hydrogenated Si(100) surfaces, Phys. Rev. B 74,075318 (2006)820. Yeom, HW, Comment on “Soft phonon, dynamicalfluctuations, and a reversible phase transition: Indiumchains on silicon”, Phys Rev Lett 97, 189701 (2006)821. A. A. Stekolnikov, K. Seino, F. Bechstedt, S. Wippermann,W. G. Schmidt, A. Calzolari, M. BuongiornoNardelli, Hexagon versus Trimer Formation in In Nanowireson Si(111): Energetics and Quantum Conductance,Phys. Rev. Lett. 98, 026105 (2007)822. M. Hashimoto, Y. Fukaya, A. Kawasuso, A. Ichimiya,Surface structure of In/Si(1 1 1) studied by reflectionhigh-energy positron diffraction, Surface Science 601,5192 (2007)823. S. Wippermann, W.G. Schmidt, A. Calzolari, M.Buongiorno Nardelli, A.A. Stekolnikov, K. Seino, F.Bechstedt, Quantum conductance of In nanowireson Si(111) from first principles calculations, SurfaceScience 601 4045 (2007)824. J-H Cho, J-Y Lee, First-principles calculation of theatomic structure of one-dimensional indium chains onSi(111): Convergence to a metastable structure, Phys.Rev. B 76, 033405 (2007)825. D. V. Gruznev, D. A. Olyanich, D. N. Chubenko, A.V. Zotov, A. A. Saranin, 4 × 1 to 7 × 3 transitionin the In/Ge xSi 1−x (111) system induced by varyingthe substrate lattice constant, Phys. Rev. B 76, 073307(2007)826. Y B Losovyj, M Klinke, E Cai, I Rodriguez, J Zhang,L. Makinistian, A. G. Petukhov, E. A. Albanesi, P.Galiy, Y Fiyala, J Liu, P. A. Dowben, The electronicstructure of surface chains in the layered semiconductorIn4Se3(100), Appl. Phys. Lett. 92, 122107 (2008)827. Wippermann S, Koch N, Schmidt WG; Adatominducedconductance modification of in nanowires:Potential-well scattering and structural effects, PhysRev Lett 100, 106802 (2008)828. C Liu, T Inaoka, S Yaginuma, T Nakayama, M Aono,T Nagao, Disappearance of the quasi-one-dimensionalplasmon at the metal-insulator phase transition of indiumatomic wires, Phys Rev B 77, 205415 (2008)829. Y. Fukaya, M. Hashimoto, A. Kawasuso, A. Ichimiya,Surface structure of Si(111)-(8×2)-In determinedby reflection high-energy positron diffraction, SurfaceScience 602, 2448 (2008)
52830. Hashimoto, M., Fukaya, Y., Kawasuso, A., Ichimiya,A. Quasi-one-dimensional In atomic chains on Si(1 11) at low temperature studied by reflection high-energypositron diffraction and scanning tunneling microscopy,Applied Surface Science 254, 7733 (2008)831. A. A. Stekolnikov, J. Furthmüller, and F. Bechstedt,Pt-induced nanowires on Ge(001): Ab initio study,Phys. Rev. B 78, 155434 (2008)832. Wippermann S, Schmidt WG; Optical anisotropy ofthe In/Si(1 1 1)(4 x 1)/(8 x 2) nanowire array, SurfaceScience 603, 247 (2008)833. Kawasuso, A; Fukaya, Y; Hashimoto, M; Ichimiya, A;Narita, H; Matsuda, I, Atomic Scale Study of SurfaceStructures and Phase Transitions with ReflectionHigh-Energy Positron Diffraction, Positron and PositroniumChemistry 607, 94 (2009)834. Zhang, H., Li, Y., Li, B., Fang, X., Ji, H., Wang, B.,Zeng, C., Hou, J.G., Templated growth of quasi-onedimensional molecular structures on Si(1 1 1)-(4 x 1)-In surface, Surface Science 603, L70 (2009)835. Chandola S, Hinrichs K, Gensch, M; Esser, N; Wippermann,S; Schmidt, WG; Bechstedt, F; Fleischer, K;McGilp, JF , Structure of Si(111)-In Nanowires Determinedfrom the Midinfrared Optical Response, Phys.Rev. Lett. 102, 226805 (2009)836. Snijders, P.C., Weitering, H.H., Colloquium: Electronicinstabilities in self-assembled atom wires, Reviews ofModern Physics 82, 307 (2010)837. Sauer, S; Fuchs, F; Bechstedt, F; Blumenstein, C; Schafer,J First-principles studies of Au-induced nanowireson Ge(001), PHYSICAL REVIEW B 81 (7): Art. No.075412 FEB 2010838. Wippermann, S; Koch, N; Blankenburg, S; Gerstmann,U; Sanna, S; Rauls, E; Hermann, A; Schmidt, WGUnderstanding Electron Transport in Atomic Nanowiresfrom Large-Scale Numerical Calculations, HIGHPERFORMANCE COMPUTING ON VECTOR SYS-TEMS 2009 : 233-242 2010839. Speiser, E; Chandola, S; Hinrichs, K; Gensch, M; Cobet,C; Wippermann, S; Schmidt, WG; Bechstedt, F;Richter, W; Fleischer, K; McGilp, JF; Esser, N Metalinsulatortransition in Si(111)-(4 x 1)/(8 x 2)-In studiedby optical spectroscopy, HYSICA STATUS SOLI-DI B-BASIC SOLID STATE PHYSICS 247 (8): 2033-2039 AUG 2010840. Wippermann, S; Schmidt, WG Entropy ExplainsMetal-Insulator Transition of the Si(111)-In NanowireArray, PHYSICAL REVIEW LETTERS 105 (12):Art. No. 126102 SEP 17 2010841. Goryl, G; Toton, D; Tomaszewska, N; Prauzner-Bechcicki, JS; Walczak, L; Tejeda, A; Taleb-Ibrahimi,A; Kantorovich, L; Michel, EG; Kolodziej, JJ Structureof the indium-rich InSb(001) surface, PHYSICALREVIEW B 82 (16): Art. No. 165311 OCT 7 2010842. Fukaya, Y., Hashimoto, M., Kawasuso, A., Ichimiya,A. Structure and phase transition of low-dimensionalmetals on Si(111) surfaces studied by reflection highenergypositron diffraction, (2010) Journal of Physics:Conference Series, 225, art. no. 012008843. Schmidt, WG; Babilon, M; Thierfelder, C; Sanna,S; Wippermann, S Influence of Na adsorption onthe quantum conductance and metal-insulator transitionof the In-Si(111)(4x1)-(8x2) nanowire array,PHYSICAL REVIEW B 84 (11): 10.1103/Phys-RevB.84.115416 SEP 14 2011844. Schmidt, W.G., Wippermann, S., Sanna, S., Babilon,M., Vollmers, N.J., Gerstmann, U. In-Si(111)(4x1)/(8x2) nanowires: Electron transport, entropy,and metal-insulator transition, Physica StatusSolidi (B) Basic Research 249 (2) , pp. 343-359 2012845. Kim, H.-J., Cho, J.-H. Driving force of phase transitionin indium nanowires on Si(111), 2013, PhysicalReview Letters 110 (11), art. no. 116801846. Schmidt, W.G., Rauls, E., Gerstmann, U., Sanna, S.,Landmann, M., Rohrmuller, M., Riefer, A., Wippermann,S. 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.Cecilia NoguezCURRICULUM VITAE9 de
Page 3 and 4: XII. Citas capturadas (2007) 25A. C
Page 5 and 6: 1985-1990 LICENCIATURA: FísicaInst
Page 7 and 8: 2013 Conferencia Mapping Structural
Page 9 and 10: 62. Pláticas invitadas nacionales
Page 11 and 12: 2002 Plática en el Planetario de M
Page 13 and 14: 10E. Organización de reuniones cie
Page 15 and 16: 122004/07 Efecto casimir en materia
Page 17 and 18: 145 publicaciones en el Phys. Rev.
Page 19 and 20: 16Centro de Investigaciones en Opti
Page 21 and 22: J. of Comp. and Theo. Nanoscience 1
Page 23 and 24: 63. Surface Plasmons on Metal Nanop
Page 25 and 26: 29. Propiedades electrónicas de la
Page 27 and 28: 3. Estudio teórico de nanotubos de
Page 29 and 30: 269. V. Kochergin, V. Zaporojtchenk
Page 31 and 32: 2874. Shkrebtii AI, Esser N, Richte
Page 33 and 34: 30143. Losio R, Altmann KN, Himpsel
Page 35 and 36: 32201. Tuncer E, Nettelblad B, Guba
Page 37 and 38: 34267. V. Bastys, I. Pastoriza-Sant
Page 39 and 40: 36335. Blaber, M.G., Harris, N., Fo
Page 41 and 42: 38402. Liu, P; Cui, H; Wang, CX; Ya
Page 43 and 44: 40465. Chen, CC; Yu, BH; Liu, P; Li
Page 45 and 46: 42523. Zhang, L., Zheng, S., Kim, K
Page 47 and 48: 44579. Dandapat, A; Pramanik, S; By
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Page 51 and 52: 48706. Railing Chang and P. T. Leun
Page 53: 50771. Babapour, A; Yang, B; Bahang
Page 57 and 58: 54of Silver Nanoparticles Embedded
Page 59 and 60: 56The effect of volume fraction, 20
Page 61 and 62: 58997. Henry, Kiely, Sir Thomas , R
Page 63 and 64: 601062. Shang, L., Qin, C., Jin, L.
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Page 77 and 78: 74OPTICS, 14 (12):10.1088/2040-8978
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Page 83 and 84: 801668. Gautier, C; Burgi, T Vibrat
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Page 89 and 90: 861843. T M. Fitzgerald, M A. Marci
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Page 95 and 96: 92Map of the Structural and Optical
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