Vibrational and optical spectroscopies integrated with environmental transmission electron microscopy

Ultramicroscopy

Volumn 150, Issue , 2015, Pages 10-15

  Picher, Matthieu ^a,b   Mazzucco, Stefano ^a,b,c   Blankenship, Steve ^a   Sharma, Renu ^a  

^a NATIONAL INSTITUTE OF STANDARDS AND TECHNOLOGY   (United States)

^b University of Maryland   (United States)

^c Velocix Limited   (United Kingdom)

Author keywords

Cathodoluminescence; Environmental scanning transmission electron microscopy; Raman spectroscopy; TEM sample temperature measurement

Indexed keywords

CATHODOLUMINESCENCE; ELECTRONS; OPTICAL SYSTEMS; PHOTOLUMINESCENCE SPECTROSCOPY; RAMAN SPECTROSCOPY; SCANNING ELECTRON MICROSCOPY; TEMPERATURE MEASUREMENT; TRANSMISSION ELECTRON MICROSCOPY;

CRITICAL ELEMENTS; ENVIRONMENTAL SCANNING; ENVIRONMENTAL TRANSMISSION ELECTRON MICROSCOPY; FREE-SPACE OPTICAL SYSTEMS; LOCAL TEMPERATURE; OPTICAL SPECTROSCOPY; SAMPLE TEMPERATURE; SPECTROSCOPY DATA;

HIGH RESOLUTION TRANSMISSION ELECTRON MICROSCOPY;

ARTICLE; CATHODOLUMINESCENCE; ENVIRONMENTAL TRANSMISSION ELECTRON MICROSCOPY; LUMINESCENCE; OPTICAL INSTRUMENTATION; OPTICS; PHOTOLUMINESCENCE; RAMAN SPECTROMETRY; SIGNAL NOISE RATIO; TEMPERATURE MEASUREMENT; TRANSMISSION ELECTRON MICROSCOPY;

EID: 84918800688     PISSN: 03043991     EISSN: 18792723     Source Type: Journal    
DOI: 10.1016/j.ultramic.2014.11.023     Document Type: Article

References (31)

1. Sharma R. An environmental transmission electron microscope for in situ synthesis and characterization of nanomaterials. J. Materials Res. 2005, 20:1695-1707.
2. Hansen T.W., Wagner J.B., Dunin-Borkowski R.E. Aberration corrected and monochromated environmental transmission electron microscopy: challenges and prospects for materials science. Mater. Sci. Technol. 2010, 26:1338-1344.
3. Gai P.L., Boyes E.D. Advances in atomic resolution in situ environmental transmission electron microscopy and 1Å aberration corrected in situ electron microscopy. Microsc. Res. Tech. 2009, 72:153-164.
4. Chenna S., Banerjee R., Crozier P.A. Atomic-scale observation of the Ni activation process for partial oxidation of methane using in situ environmental TEM. ChemCatChem 2011, 3:1051-1059.
5. Simonsen S.B., Chorkendorff I., Dahl S., Skoglundh M., Sehested J., Helveg S. Direct observations of oxygen-induced platinum nanoparticle ripening studied by in situ TEM. J. Am. Chem. Soc. 2010, 132:7968-7975.
6. Yoshida H., Kuwauchi Y., Jinschek J.R., Sun K., Tanaka S., Kohyama M., Shimada S., Haruta M., Takeda S. Visualizing gas molecules interacting with supported nanoparticulate catalysts at reaction conditions. Science 2012, 335:317-319.
7. Hofmann S., Sharma R., Ducati C., Du G., Mattevi C., Cepek C., Cantoro M., Pisana S., Parvez A., Cervantes-Sodi F. In situ observations of catalyst dynamics during surface-bound carbon nanotube nucleation. Nano Lett. 2007, 7:602-608.
8. Egerton R., Li P., Malac M. Radiation damage in the TEM and SEM. Micron 2004, 35:399-409.
9. Picher M., Anglaret E., Arenal R., Jourdain V. Self-deactivation of single-walled carbon nanotube growth studied by in situ raman measurements. Nano Lett. 2009, 9:542-547.
10. Yeo B.S., Bell A.T. In situ Raman study of nickel oxide and gold-supported nickel oxide catalysts for the electrochemical evolution of oxygen. J. Phys. Chem. C 2012, 116:8394-8400.
11. Sherif E.-S.M., Erasmus R., Comins J. In situ Raman spectroscopy and electrochemical techniques for studying corrosion and corrosion inhibition of iron in sodium chloride solutions. Electrochim. Acta 2010, 55:3657-3663.
12. Viera G., Huet S., Boufendi L. Crystal size and temperature measurements in nanostructured silicon using Raman spectroscopy. J. Appl. Phys. 2001, 90:4175-4183.
13. Cuscó R., Alarcón-Lladó E., Ibanez J., Artús L., Jiménez J., Wang B., Callahan M.J. Temperature dependence of Raman scattering in ZnO. Phys. Rev. B 2007, 75:165202.
14. Fantini C., Jorio A., Souza M., Strano M., Dresselhaus M., Pimenta M. Optical transition energies for carbon nanotubes from resonant Raman spectroscopy: environment and temperature effects. Phys. Rev. Lett. 2004, 93:147406.
15. Vendelbo S., Kooyman P., Creemer J., Morana B., Mele L., Dona P., Nelissen B., Helveg S. Method for local temperature measurement in a nanoreactor for in situ high-resolution electron microscopy. Ultramicroscopy 2013, 133:72-79.
16. Miller B.K., Crozier P.A. System for In situ UV-visible illumination of environmental transmission electron microscopy samples. Microsc. Microanal. 2013, 19:461-469.
17. Kim J.S., LaGrange T., Reed B.W., Taheri M.L., Armstrong M.R., King W.E., Browning N.D., Campbell G.H. Imaging of transient structures using nanosecond in situ TEM. Science 2008, 321:1472-1475.
18. Xiang B., Hwang D.J., In J.B., Ryu S.-G., Yoo J.-H., Dubon O., Minor A.M., Grigoropoulos C.P. In situ TEM near-field optical probing of nanoscale silicon crystallization. Nano Lett. 2012, 12:2524-2529.
19. Zagonel L.F., Mazzucco S., Tencé M., March K., Bernard R., Laslier B., Jacopin G., Tchernycheva M., Rigutti L., Julien F.H., Songmuang R., Kociak M. Nanometer scale spectral imaging of quantum emitters in nanowires and its correlation to their atomically resolved structure. Nano Lett. 2010, 11:568-573.
20. M. Kociak, L.F. Zagonel, M. Tence, S. Mazzucco, Flexible cathodoluminescence detection system and microscope employing such a system, Google Patents, 2011.
21. M. Kociak, L.F. Zagonel, M. Tence, S. Mazzucco, Adjustable cathodoluminescence detection system and microscope employing such a system, Google Patents, 2011.
22. Tizei L., Kociak M. Spatially resolved quantum nano-optics of single photons using an electron microscope. Phys. Rev. Lett. 2013, 110:153604.
23. Richter H., Wang Z., Ley L. The one phonon Raman spectrum in microcrystalline silicon. Solid State Commun. 1981, 39:625-629.
24. Dresselhaus M., Dresselhaus G., Jorio A., Souza Filho A., Saito R. Raman spectroscopy on isolated single wall carbon nanotubes. Carbon 2002, 40:2043-2061.
25. Dresselhaus M.S., Dresselhaus G., Saito R., Jorio A. Raman spectroscopy of carbon nanotubes. Phys. Rep. 2005, 409:47-99.
26. Biercuk M., Llaguno M.C., Radosavljevic M., Hyun J., Johnson A.T., Fischer J.E. Carbon nanotube composites for thermal management. Appl. Phys. Lett. 2002, 80:2767-2769.
27. Chiashi S., Murakami Y., Miyauchi Y., Maruyama S. Temperature dependence of Raman scattering from single-walled carbon nanotubes: undefined radial breathing mode peaks at high temperatures. Jpn. J. Appl. Phys. 2008, 47:2010.
28. Mahfoud Z., Dijksman A.T., Javaux Cm, Bassoul P., Baudrion A.-L., Plain J.r.m, Dubertret B., Kociak M. Cathodoluminescence in a scanning transmission electron microscope: a nanometer-scale counterpart of photoluminescence for the study of II-VI quantum dots. J. Phys. Chem. Lett. 2013, 4:4090-4094.
29. Edwards P.R., Martin R.W. Cathodoluminescence nano-characterization of semiconductors. Semicond. Sci. Technol. 2011, 26:064005.
30. Vesseur E.J.R., de Waele R., Kuttge M., Polman A. Direct observation of plasmonic modes in Au nanowires using high-resolution cathodoluminescence spectroscopy. Nano Lett. 2007, 7:2843-2846.
31. Jaffrennou P., Barjon J., Lauret J.-S., Attal-Trétout B., Ducastelle F., Loiseau A. Origin of the excitonic recombinations in hexagonal boron nitride by spatially resolved cathodoluminescence spectroscopy. J. Appl. Phys. 2007, 102:116102.