Cathodoluminescence

1: Tchernycheva M, Neplokh V, Zhang H, Lavenus P, Rigutti L, Bayle F, Julien FH,
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2: Meuret S, Tizei LH, Cazimajou T, Bourrellier R, Chang HC, Treussart F, Kociak
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3: Engelsen DD, Harris PG, Ireland TG, Fern GR, Silver J. Contrast and decay of
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4: Furukawa T, Fukushima S, Niioka H, Yamamoto N, Miyake J, Araki T, Hashimoto M.
Rare-earth-doped nanophosphors for multicolor cathodoluminescence nanobioimaging
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5: Ramakrishna PV. Cathodoluminescence properties of gadolinium-doped CaMoO(4):Eu
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6: Bischak CG, Hetherington CL, Wang Z, Precht JT, Kaz DM, Schlom DG, Ginsberg
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7: Witkowski BS, Wachnicki L, Gieraltowska S, Reszka A, Kowalski BJ, Godlewski M.
Low-Temperature Cathodoluminescence Investigations of High-Quality Zinc Oxide
Nanorods. Microsc Microanal. 2015 Jun;21(3):564-9. doi:
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8: Atre AC, Brenny BJ, Coenen T, García-Etxarri A, Polman A, Dionne JA. Nanoscale
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9: Shang C, Zhao J, Wang X, Xia H, Kang H. Investigation on the
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10: Watanabe K, Nagata T, Wakayama Y, Sekiguchi T, Erdélyi R, Volk J. Band-gap
deformation potential and elasticity limit of semiconductor free-standing
nanorods characterized in situ by scanning electron
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11: Losquin A, Zagonel LF, Myroshnychenko V, Rodríguez-González B, Tencé M,
Scarabelli L, Förstner J, Liz-Marzán LM, García de Abajo FJ, Stéphan O, Kociak M.
Unveiling nanometer scale extinction and scattering phenomena through combined
electron energy loss spectroscopy and cathodoluminescence measurements. Nano
Lett. 2015 Feb 11;15(2):1229-37. doi: 10.1021/nl5043775. Epub 2015 Jan 20. PubMed
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12: Hu L, Yan J, Kim Y, Fei G, Watanabe K, Sekiguchi T, Zhang L, Fang X.
Cathodoluminescence and photoconductive characteristics of single-crystal ternary
CdS/CdSe/CdS biaxial nanobelts. Small. 2015 Apr;11(13):1531-6. doi:
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13: Niioka H, Fukushima S, Ichimiya M, Ashida M, Miyake J, Araki T, Hashimoto M.
Correlative cathodoluminescence and near-infrared fluorescence imaging for
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Nov;63 Suppl 1:i29. doi: 10.1093/jmicro/dfu073. PubMed PMID: 25359828.
14: Boffelli M, Zhu W, Back M, Sponchia G, Francese T, Riello P, Benedetti A,
Pezzotti G. Oxygen hole states in zirconia lattices: quantitative aspects of
their cathodoluminescence emission. J Phys Chem A. 2014 Oct 23;118(42):9828-36.
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15: Liu BD, Yang B, Dierre B, Sekiguchi T, Jiang X. Local defect-induced
red-shift of cathodoluminescence in individual ZnS nanobelts. Nanoscale. 2014 Nov
7;6(21):12414-20. doi: 10.1039/c4nr04464a. PubMed PMID: 25238442.
16: Yoshikawa M, Seki H, Inoue K, Nanen Y, Kimoto T. Characterization of
inhomogeneity in silicon dioxide films on 4H-silicon carbide epitaxial substrate
using a combination of Fourier transform infrared and cathodoluminescence
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17: Fukushima S, Furukawa T, Niioka H, Ichimiya M, Miyake J, Ashida M, Araki T,
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18: Zhang H, Aharonovich I, Glenn DR, Schalek R, Magyar AP, Lichtman JW, Hu EL,
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19: Narváez AC, Weppelman IG, Moerland RJ, Liv N, Zonnevylle AC, Kruit P,
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20: Huang J, Huang Z, Yi S, Liu Y, Fang M, Zhang S. Fe-catalyzed growth of
one-dimensional α-Si3N4 nanostructures and their cathodoluminescence properties.
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21: Tizei LH, Zagonel LF, Tencé M, Stéphan O, Kociak M, Chiaramonte T, Ugarte D,
Cotta MA. Spatial modulation of above-the-gap cathodoluminescence in InP
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22: Leto A, Zhu W, Matsubara M, Pezzotti G. Bioinertness and fracture toughness
evaluation of the monoclinic zirconia surface film of Oxinium™ femoral head by
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23: Le Shim E, Kim JM, Okhlopkova AA, Kang CJ, Choi YJ, Cho JH.
Cathodoluminescence of ZnO nanostructure arrays hydrothermally grown on the
patterned seed layers using a polystyrene-sphere-based lithographic method. J
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24: Naresh-Kumar G, Bruckbauer J, Edwards PR, Kraeusel S, Hourahine B, Martin RW,
Kappers MJ, Moram MA, Lovelock S, Oliver RA, Humphreys CJ, Trager-Cowan C.
Coincident electron channeling and cathodoluminescence studies of threading
dislocations in GaN. Microsc Microanal. 2014 Feb;20(1):55-60. doi:
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25: Furukawa T, Niioka H, Ichimiya M, Nagata T, Ashida M, Araki T, Hashimoto M.
High-resolution microscopy for biological specimens via cathodoluminescence of
Eu- and Zn-doped Y2O3 nanophosphors. Opt Express. 2013 Nov 4;21(22):25655-63.
doi: 10.1364/OE.21.025655. PubMed PMID: 24216790.
26: Huang J, Huang Z, Liu Y, Fang M, Chen K, Huang Y, Huang S, Ji H, Yang J, Wu
X, Zhang S. β-Sialon nanowires, nanobelts and hierarchical nanostructures:
morphology control, growth mechanism and cathodoluminescence properties.
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27: Yuan F, Liu B, Wang Z, Yang B, Yin Y, Dierre B, Sekiguchi T, Zhang G, Jiang
X. Synthesis, microstructure, and cathodoluminescence of [0001]-oriented GaN
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28: Liu X, Liu Y, Yan D, Zhu H, Liu C, Liu W, Xu C, Liu Y, Zhang H, Wang X. A
multiphase strategy for realizing green cathodoluminescence in
12CaO·7Al2O3-CaCeAl3O7:Ce3+,Tb3+ conductive phosphor. Dalton Trans. 2013 Dec
14;42(46):16311-7. doi: 10.1039/c3dt51958a. PubMed PMID: 24061503.
29: Liu B, Bando Y, Dierre B, Sekiguchi T, Golberg D, Jiang X. Solid solution,
phase separation, and cathodoluminescence of GaP-ZnS nanostructures. ACS Appl
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30: Watanabe K, Nakamura Y, Ichikawa M. Conductive optical-fiber STM probe for
local excitation and collection of cathodoluminescence at semiconductor surfaces.
Opt Express. 2013 Aug 12;21(16):19261-8. doi: 10.1364/OE.21.019261. PubMed PMID:
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31: Hu T, Liu B, Yuan F, Wang Z, Huang N, Zhang G, Dierre B, Hirosaki N,
Sekiguchi T, Bando Y, Golberg D, Jiang X. Triangular ZnO nanosheets: synthesis,
crystallography and cathodoluminescence. J Nanosci Nanotechnol. 2013
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32: Woo JY, Lee J, Lee H, Lee N, Oh JH, Do YR, Han CS. Visible
cathodoluminescence of quantum dot films by direct irradiation of electron beam
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33: Rodríguez-Lazcano Y, Correcher V, Garcia-Guinea J. Thermo- and
cathodoluminescence properties of lepidolite. Spectrochim Acta A Mol Biomol
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34: Bigelow NW, Vaschillo A, Camden JP, Masiello DJ. Signatures of Fano
interferences in the electron energy loss spectroscopy and cathodoluminescence of
symmetry-broken nanorod dimers. ACS Nano. 2013 May 28;7(5):4511-9. doi:
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35: Zhu W, Wu Y, Leto A, Du J, Pezzotti G. Cathodoluminescence and Raman
spectroscopic analyses of Nd- or Yb-doped Y2O3 transparent ceramics. J Phys Chem
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36: Estrin Y, Rich DH, Kretinin AV, Shtrikman H. Influence of metal deposition on
exciton-surface plasmon polariton coupling in GaAs/AlAs/GaAs core-shell nanowires
studied with time-resolved cathodoluminescence. Nano Lett. 2013 Apr
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37: Wilson NC, MacRae CM, Torpy A, Davidson CJ, Vicenzi EP. Hyperspectral
cathodoluminescence examination of defects in a carbonado diamond. Microsc
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38: Gaillou E, Post JE, Rose T, Butler JE. Cathodoluminescence of natural,
plastically deformed pink diamonds. Microsc Microanal. 2012 Dec;18(6):1292-302.
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39: Stevens-Kalceff M, MacRae C, Wight S. Introduction: special issue on
cathodoluminescence. Microsc Microanal. 2012 Dec;18(6):1211. doi:
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40: Edwards PR, Jagadamma LK, Bruckbauer J, Liu C, Shields P, Allsopp D, Wang T,
Martin RW. High-resolution cathodoluminescence hyperspectral imaging of nitride
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41: Gucsik A, Nishido H, Ninagawa K, Ott U, Tsuchiyama A, Kayama M, Simonia I,
Boudou JP. Cathodoluminescence microscopy and spectroscopy of micro- and
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42: Erdman N, Nielsen C, Robertson VE. Shedding new light on
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43: MacRae CM, Wilson NC, Torpy A, Davidson CJ. Hyperspectral cathodoluminescence
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44: Leeman WP, MacRae CM, Wilson NC, Torpy A, Lee CT, Student JJ, Thomas JB,
Vicenzi EP. A study of cathodoluminescence and trace element compositional zoning
in natural quartz from volcanic rocks: mapping titanium content in quartz.
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45: Stevens-Kalceff MA, Liu Z, Riesen H. Cathodoluminescence microanalysis of
irradiated microcrystalline and nanocrystalline samarium doped BaFCl. Microsc
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46: Wendler JE, Wendler I, Rose T, Huber BT. Using cathodoluminescence
spectroscopy of cretaceous calcareous microfossils to distinguish biogenic from
early-diagenetic calcite. Microsc Microanal. 2012 Dec;18(6):1313-21. doi:
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47: Glenn DR, Zhang H, Kasthuri N, Schalek R, Lo PK, Trifonov AS, Park H,
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cathodoluminescence from nanoparticles with distinguishable colours. Sci Rep.
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48: Götze J. Application of cathodoluminescence microscopy and spectroscopy in
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49: Demers H, Poirier-Demers N, Phillips MR, de Jonge N, Drouin D.
Three-dimensional electron energy deposition modeling of cathodoluminescence
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50: Coenen T, Polman A. Polarization-sensitive cathodoluminescence Fourier
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51: Lei M, Fu XL, Yang HJ, Wang YG, Zhang YB, Li PG. Solvothermal route to
S-deficient CoS nanoplates and their cathodoluminescence and magnetic properties.
J Nanosci Nanotechnol. 2012 Mar;12(3):2586-90. PubMed PMID: 22755094.
52: Myroshnychenko V, Nelayah J, Adamo G, Geuquet N, Rodríguez-Fernández J,
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53: Gustafsson A, Hillerich K, Messing ME, Storm K, Dick KA, Deppert K, Bolinsson
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54: Matyssek C, Schmidt V, Hergert W, Wriedt T. The T-Matrix method in electron
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55: Onuma T, Kagamitani Y, Hazu K, Ishiguro T, Fukuda T, Chichibu SF.
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57: Topaksu M, Correcher V, Garcia-Guinea J, Topak Y, Göksu HY. Comparison of
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58: Kostova I, Tormo L, Crespo-Feo E, Garcia-Guinea J. Study of coal and graphite
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59: Tsai CC, Li GH, Lin YT, Chang CW, Wadekar P, Chen QY, Rigutti L, Tchernycheva
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60: Bok J, Schauer P. LabVIEW-based control and data acquisition system for
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61: Nichols G. Applications of cathodoluminescence spectroscopy and imaging in
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62: Barnard ES, Coenen T, Vesseur EJ, Polman A, Brongersma ML. Imaging the hidden
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63: Schwarz C, Lin Y, Shathkin M, Flitsiyan E, Chernyak L. Cathodoluminescence
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64: Edwards PR, Sleith D, Wark AW, Martin RW. Mapping Localized Surface Plasmons
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65: Coenen T, Vesseur EJ, Polman A, Koenderink AF. Directional emission from
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66: Yan X, Zou C, Chen R, Li S, Yang J, Alyamani A, Bian J, Haemmerle E, Gao W.
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68: Namazu T, Yamashita N, Kakinuma S, Nishikata K, Naka N, Matsumoto K, Inoue S.
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69: González A, Herrera M, Valenzuela J, Escobedo A, Pal U. Cathodoluminescence
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70: Kizuka T. Position-selective emission control of cathodoluminescence using
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71: Lee SM, Choi KC, Kim DH, Jeon DY. Localized surface plasmon enhanced
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72: Nogales E, Méndez B, Piqueras J. Assessment of waveguiding properties of
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74: De Winter DA, Lebbink MN, Wiggers De Vries DF, Post JA, Drury MR. FIB-SEM
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