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811702. Zhao, Y., Xu, L., Kuang, H., Wang, L., Xu, C. Asymmetricand symmetric PCR of gold nanoparticles: Apathway to scaled-up self-assembly with tunable chirality,J. Materials Chemistry 22 (12) , pp. 5574-5580,20121703. Tsukuda, T. Toward an atomic-level understanding ofsize-specific properties of protected and stabilized goldclusters, Bulletin of the Chemical Society of Japan 85(2) , pp. 151-168, 20121704. Hakkinen, H The gold-sulfur interface atthe nanoscale, Nature Chem., 4 (6):443-455;10.1038/NCHEM.1352 JUN 20121705. Persechini, L., McGilp, J.F. Chiral second-harmonicgeneration from small organic molecules at surfaces,(2012) Physica Status Solidi (B) Basic Research, 249(6) pp. 1155-1159.1706. Liu, HL; Ye, YJ; Chen, J; Lin, DY; Jiang, Z; Liu, ZJ;Sun, B; Yang, LB; Liu, JH In Situ Photoreduced SilverNanoparticles on Cysteine: An Insight into the Originof Chirality, Chemistry-A European J., 18 (26):8037-8041; 10.1002/chem.201200397 JUN 20121707. Bochicchio, D; Ferrando, R Structure and thermal stabilityof AgCu chiral nanoparticles, European Phys J.D, 66 (5):10.1140/epjd/e2012-30054-0 MAY 20121708. An, Z., Yamaguchi, M. Chiral recognition in aggregationof gold nanoparticles grafted with helicenes, 2012,Chemical Communications 48 (59) , pp. 7383-73851709. Kumar, S., Jin, R. Water-soluble Au 25(Capt) 18 nanoclusters:Synthesis, thermal stability, and opticalproperties, 2012, Nanoscale 4 (14) , pp. 4222-42271710. Srivastava, A. K.; Yadev, Rishikesh; Rai, V.; Ganguly,T N; Deb, SK Surface Plasmon Resonance in GoldNanoparticles, Soli Satate Phys, PTS 1 AND 2 BookSeries: AIP Conference Proceedings Volume: 1447 Pages:305-306 DOI: 10.1063/1.4710001 20121711. Xie, J., Duan, Y., Che, S., Chirality of metal nanoparticlesin chiral mesoporous silica, 2012, AdvancedFunctional Materials 22 (18) , pp. 3784-37921712. Yan, W., Xu, L., Xu, C., Ma, W., Kuang, H., Wang,L., Kotov, N.A. Self-assembly of chiral nanoparticlepyramids with strong R/S optical activity, 2012, J. theAmerican Chemical Society 134 (36) , pp. 15114-151211713. Berta, M., Loppinet, B., Vlassopoulos, D., Askounis,A., Koutsos, V., Pastoriza-Santos, I., Liz-Marzan, L.M.Tailoring the properties of grafted silver nanoprismcomposites, 2012, Polymer (United Kingdom) 53 (25), pp. 5771-57781714. Maoz, BM; van der Weegen, R; Fan, ZY; Govorov,AO; Ellestad, G; Berova, N; Meijer, EW; Markovich,G Plasmonic Chiroptical Response of Silver NanoparticlesInteracting with Chiral Supramolecular Assemblies,J. Am. Chem. Soc., 134 (42):17807-17813;10.1021/ja309016k OCT 24 20121715. Hakkinen, H Ligand-Protected Gold Nanoclusters asSuperatoms-Insights from Theory and Computations,Editor(s): Johnston RL; Wilcoxon JP, Metal Nanopart.and Nanoalloys, 3 129-157; 10.1016/B978-0-08-096357-0.00004-2 2012, in Frontiers of Nanoscience1716. Johnston, RL Metal Nanoparticles and Nanoalloys,Editor(s): Johnston RL; Wilcoxon JP, in Metal Nanopart.and Nanoalloys, 3 1-42; 10.1016/B978-0-08-096357-0.00006-6 2012, Frontiers of Nanoscience1717. Xie, JJ; Che, SA Chirality of Anisotropic Metal Nanowireswith a Distinct Multihelix, Chemistry-A EuropeanJ., 18 (50):15954-15959; 10.1002/chem.201203017DEC 20121718. Ock, K.-S., Dembereldorj, U., Park, J., Ganbold, E.-O., Kim, S., Shin, H.-C., Joo, S.-W. Temperaturedependentstructural change of D-penicillamine-cappedchiral gold nanoparticles investigated by infrared spectroscopy,2013, Spectrochimica Acta - Part A: Molecularand Biomolecular Spectroscopy 102 , pp. 419-4241719. Artemyev, M., Krutokhvostov, R., Melnikau, D., Oleinikov,V., Sukhanova, A., Nabiev, I. Low-field magneticcircular dichroism in silver and gold colloidal nanoparticlesof different sizes, shapes, and aggregationstates, 2012, Proceedings of SPIE - The InternationalSociety for Optical Engineering 8457 , art. no. 8457291720. Zeng, T., Zhang, X.-L., Niu, H.-Y., Ma, Y.-R., Li, W.-H., Cai, Y.-Q. In situ growth of gold nanoparticles ontopolydopamine-encapsulated magnetic microspheres forcatalytic reduction of nitrobenzene, 2013, Applied CatalysisB: Environmental 134-135 , pp. 26-331721. X Yang, L Gan, L Han, D Li, J Wang, E Wang Facilepreparation of chiral penicillamine protected gold nanoclustersand their applications in cell imaging, ChemComm 49 (23):2302-2304 20131722. Matczyszyn, K; Olesiak-Banska, J DNA as scaffoldingfor nanophotonic structures, J Nanophotonics, 610.1117/1.JNP.6.064505 SEP 4 20121723. Wang, Y; Xu, J; Wang, YW; Chen, HY Emergingchirality in nanoscience, CHEMICAL SOCIETY RE-VIEWS, 42 (7):2930-2962; 20131724. Wang, P; Chen, L; Wang, RY; Ji, YL; Zhai, DW; Wu,XC; Liu, Y; Chen, KQ; Xu, HX Giant optical activityfrom the radiative electromagnetic interactions inplasmonic nanoantennas, 2013, Nanoscale 5 (9) , pp.3889-38941725. Valev, V.K., Baumberg, J.J., Sibilia, C., Verbiest, T.Chirality and chiroptical effects in plasmonic nanostructures:Fundamentals, recent progress, and outlook,2013, Advanced Materials 25 (18) , pp. 2517-25341726. Shen, X., Asenjo-Garcia, A., Liu, Q., Jiang, Q., GarcíaDe Abajo, F.J., Liu, N., Ding, B. Three-dimensionalplasmonic chiral tetramers assembled by DNA origami,2013, Nano Letters 13 (5) , pp. 2128-21331727. Nergiz, S.Z., Slocik, J.M., Naik, R.R., Singamaneni, S.Surface defect sites facilitate fibrillation: An insightinto adsorption of gold-binding peptides on Au(111),2013, Physical Chemistry Chemical Physics 15 (28) ,pp. 11629-116331728. Liu, W., Zhu, Z., Deng, K., Li, Z., Zhou, Y., Qiu, H.,Gao, Y., (...), Tang, Z. Gold nanorod at Chiral mesoporoussilica core-shell nanoparticles with unique opticalproperties, 2013, Journal of the American ChemicalSociety 135 (26) , pp. 9659-96641729. Fan, Z., Zhang, H., Govorov, A.O. Optical propertiesof chiral plasmonic tetramers: Circular dichroism andmultipole effects, 2013, Journal of Physical ChemistryC 117 (28) , pp. 14770-14771730. Xu, L., Hao, C., Yin, H., Liu, L., Ma, W., Wang,L., Kuang, H., Xu, C. Plasmonic core-satellites nanostructureswith high chirality and bioproperty, 2013,Journal of Physical Chemistry Letters 4 (14) , pp. 2379-23841731. Cao, T., Jin, S., Wang, S., Zhang, D., Meng, X., Zhu,M. A comparison of the chiral counterion, solvent, andligand used to induce a chiroptical response from Au25- nanoclusters, 2013, Nanoscale 5 (16) , pp. 7589-75951732. González-Campo, A., Amabilino, D.B. Biomolecules atinterfaces: Chiral, naturally, 2013, Topics in CurrentChemistry 333 , pp. 109-1561733. Kuang, H., Chen, X., Hao, C., Ma, W., Xu, L., Xu,C. Immuno-driven plasmonic oligomer sensor for theultrasensitive detection of antibiotics, 2013, RSC Advances3 (38) , pp. 17294-172991734. Yan, W., Ma, W., Kuang, H., Liu, L., Wang, L., Xu, L.,Xu, C. Plasmonic chirogenesis from gold nanoparticlessuperstructures, 2013, Journal of Physical Chemistry C117 (34) , pp. 17757-177651735. Song, C., Liu, X., Liu, D., Ren, C., Yang, W., Deng,J. Optically active particles of chiral polymers, 2013,Macromolecular Rapid Communications 34 (18) , pp.1426-1445
821736. Ben-Moshe, A., Maoz, B.M., Govorov, A.O., Markovich,G. Chirality and chiroptical effects in inorganicnanocrystal systems with plasmon and exciton resonances,2013, Chemical Society Reviews 42 (16) , pp.7028-70411737. Koktan, J., Rezanka, P., Matejka, P., Kral, V. Stanovenipomeru enantiomeru L- a D-cysteinu pomocinanocastic stribra — [Determination of the ratio ofenantiomers L-and D-cysteine using silver nanoparticles],2013, Chemicke Listy 107 (SPEC. ISSUE 2) , pp.s240-s242ArtículoTheoretical Study of Surface Plasmon Resonances inHollow Gold-Silver Double-shell Nanostructures, C.E.Román-Velźquez, Cecilia Noguez, J.J. Zhang, J. PhysicalChemistry A 113 4068 – 4074 (2009)Lo citan (10):1738. Bakshi, MS, A Simple Method of Superlattice Formation:Step-by-Step Evaluation of Crystal Growthof Gold Nanoparticles through Seed-Growth Method,Langmuir 25, 12697 (2009)1739. Q Zha, R Q Snurr, Self-Diffusion Studies of BinaryMixtures in NaX Zeolites Using Pulsed Field GradientNMR and a Maxwell-Stefan Model, J. Phys. Chem. A113, 3904 (2009)1740. 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, Plasmonics 5(1): 85 (2010)1741. JZ Zhang Biomedical Applications of Shape-ControlledPlasmonic Nanostructures: A Case Study of HollowGold Nanospheres for Photothermal Ablation Therapyof Cancer, J. Phys. Chem. Lett. 1, 686 (2010) (Perspective).1742. Chen, B; Jiao, XL; Chen, DR Fabrication of hollowcubic Ag microboxes with net-like nanofiber structuresand their surface plasmon resonance, Crystengcomm13 (1): 204-211 20111743. Hooshmand N, Jain PK, El-Sayed MA Plasmonic SpheroidalMetal Nanoshells Showing Larger Tunabilityand Stronger Near Fields Than Their Spherical Counterparts:An Effect of Enhanced Plasmon Coupling, J.Phys. Chem. 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Hidalgo, A.Sánchez-Castillo, I.L. Garzón, Cecilia Noguez, Eur.Phys. J. D 52, 179 – 182 (2009).Lo citan (6):1751. M R. Provorse, C M. Aikens, Origin of Intense ChiropticalEffects in Undecagold Subnanometer Particles, J.Am. Chem. Soc. 132, 1302 (2010)1752. Shukla, N., Bartel, M.A., Gellman, A.J. Enantioselectiveseparation on chiral Au nanoparticles, 2010 J. theAmerican Chemical Society 132 (25), pp. 8575-85801753. Gautier, C; Burgi, T, Vibrational Circular Dichroismof Adsorbed Molecules: BINAS on Gold Nanoparticles,J. Phys. Chem. C 114 (38): 15897-15902 SEP 30 20101754. Morton, S.M., Silverstein, D.W., Jensen, L. Theoreticalstudies of plasmonics using electronic structure methods,2011 Chemical Reviews 111 (6), pp. 3962-39941755. Burgess, RW; Keast, VJ TDDFT Study of the OpticalAbsorption Spectra of Bare and Coated Au(55) andAu(69) Clusters, J. Phys. Chem. C 115 (43): 21016-21021 20111756. 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.Cecilia NoguezCURRICULUM VITAE9 de
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XII. Citas capturadas (2007) 25A. C
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1985-1990 LICENCIATURA: FísicaInst
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2013 Conferencia Mapping Structural
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62. Pláticas invitadas nacionales
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2002 Plática en el Planetario de M
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10E. Organización de reuniones cie
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122004/07 Efecto casimir en materia
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145 publicaciones en el Phys. Rev.
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16Centro de Investigaciones en Opti
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J. of Comp. and Theo. Nanoscience 1
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63. Surface Plasmons on Metal Nanop
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29. Propiedades electrónicas de la
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3. Estudio teórico de nanotubos de
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269. V. Kochergin, V. Zaporojtchenk
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2874. Shkrebtii AI, Esser N, Richte
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