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Investigation of Electron Momentum Density in Carbon Nanotubes Using Transmission Electron Microscopy

Published online by Cambridge University Press:  04 September 2019

Zhenbao Feng*
Affiliation:
School of Physics Science and Information Technology, Shandong Key Laboratory of Optical Communication Science and Technology, Liaocheng University, Liaocheng 252059, China
Hefu Li
Affiliation:
School of Physics Science and Information Technology, Shandong Key Laboratory of Optical Communication Science and Technology, Liaocheng University, Liaocheng 252059, China
Zongliang Wang
Affiliation:
School of Physics Science and Information Technology, Shandong Key Laboratory of Optical Communication Science and Technology, Liaocheng University, Liaocheng 252059, China
Xiaoyan Zhang
Affiliation:
School of Physics Science and Information Technology, Shandong Key Laboratory of Optical Communication Science and Technology, Liaocheng University, Liaocheng 252059, China
Hengshuai Li
Affiliation:
School of Mechanical and Automotive Engineering, Liaocheng University, Liaocheng 252059, China
Haiquan Hu
Affiliation:
School of Physics Science and Information Technology, Shandong Key Laboratory of Optical Communication Science and Technology, Liaocheng University, Liaocheng 252059, China
Dangsheng Su
Affiliation:
Dalian National Laboratory for Clean Energy, Dalian Institute of Chemical Physics, Chinese Academy of Sciences, Dalian 116023, China
*
*Author for correspondence: Zhenbao Feng, E-mail: fengzhenbao@lcu.edu.cn
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Abstract

Valence Compton profiles (CPs) of multiwall (MWCNTs) and single-wall carbon nanotubes (SWCNTs) were obtained by recording electron energy-loss spectra at large momentum transfer in the transmission electron microscope, a technique known as electron Compton scattering from solids (ECOSS). The experimental MWCNT/SWCNT results were compared with that of graphite. Differences between the valence CPs of MWCNTs and SWCNTs were observed, and the SWCNT CPs indicate a greater delocalization of the ground-state charge density compared to graphite. The results clearly demonstrate the feasibility and potential of the ECOSS technique as a complementary tool for studying the electronic structure of materials with nanoscale spatial resolution.

Type
Materials Applications
Copyright
Copyright © Microscopy Society of America 2019 

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References

Brydson, R (2001). Electron Energy Loss Spectroscopy, 1st ed. Oxford, UK: Bios, Section 3.5.Google Scholar
Castrucci, P, Scarselli, M, Crescenzi, M, Khakani, MA & Rosei, F (2010). Probing the electronic structure of carbon nanotubes by nanoscale spectroscopy. Nanoscale 2, 16111625.Google Scholar
Cooper, M & Leake, JA (1967). The Compton profiles of graphite and diamond. Phil Mag 15, 12011212.Google Scholar
Cooper, MJ (1985). Compton-scattering and electron momentum determination. Rep Prog Phys 48, 415481.Google Scholar
Cooper, MJ, Mijnarends, PE, Shiotani, N, Sakai, N & Bansil, A (2004). X-Ray Compton Scattering. New York: Oxford University Press.Google Scholar
Dresselhaus, MS, Dresselhaus, G & Avouris, P (2007). Carbon Nanotubes: Synthesis, Structure, Properties and Applications. Berlin: Springer-Verlag.Google Scholar
Eatemadi, A, Daraee, H, Karimkhanloo, H, Kouhi, M, Zarghami, N, Akbarzadeh, A, Abasi, M, Hanifehpour, Y & Joo, SW (2014). Carbon nanotubes: properties, synthesis, purification, and medical applications. Nanoscale Res Lett 9, 393.Google Scholar
Egerton, RF (2014). Choice of operating voltage for a transmission electron microscope. Ultramicroscopy 145, 85.Google Scholar
Feng, ZB, Lin, YM, Tian, CW, Hu, HQ & Su, DS (2019). Combined study of the ground and excited states in the transformation of nanodiamonds into carbon onions by electron energy-loss spectroscopy. Sci Rep 9, 3784.Google Scholar
Feng, ZB, Loffler, S, Eder, F, Su, DS, Meyer, JC & Schattschneider, P (2013). Combined study of the ground and unoccupied electronic states of graphite by electron energy-loss spectroscopy. J Appl Phys 114, 183716.Google Scholar
Feng, ZB, Sakurai, Y, Liu, JF, Su, DS & Schattschneider, P (2016). Anisotropy of electron Compton profiles of graphite investigated by electron energy-loss spectroscopy. Appl Phys Lett 108, 093108.Google Scholar
Feng, ZB, Yang, B, Lin, YM & Su, DS (2015). Investigation of the electron momentum density distribution of nanodiamonds by electron energy-loss spectroscopy. J Chem Phys 143, 211102.Google Scholar
Georgakilas, V, Perman, JA, Tucek, J & Zboril, R (2015). Broad family of carbon nanoallotropes: Classification, chemistry, and applications of fullerenes, carbon dots, nanotubes, graphene, nanodiamonds, and combined superstructures. Chem Rev 115, 47444822.Google Scholar
Hueso, LE, Pruneda, JM, Ferrari, V, Burnell, G, Valdes-Herrera, JP, Simons, BD, Littlewood, PB, Artacho, E, Fert, A & Mathur, ND (2007). Transformation of spin information into large electrical signals using carbon nanotubes. Nature 445, 410413.Google Scholar
Jonas, P & Schattschneider, P (1993). The experimental conditions for Compton scattering in the electron microscope. J Phys: Condens Matter 5, 71737188.Google Scholar
Manninen, S (2000). Compton scattering: present status and future. J Phys Chem Solids 61, 335340.Google Scholar
Manson, ST (1972). Inelastic collisions of fast charged-particles with atoms – ionization of aluminum L shell. Phys Rev A 6, 1013.Google Scholar
Matsuda, K, Nagao, T, Kajihara, Y, Inui, M, Tamura, K, Nakamura, J, Kimura, K, Yao, M, Itou, M, Sakurai, Y & Hiraoka, N (2013). Electron momentum density in liquid silicon. Phys Rev B 88, 115125.Google Scholar
Metz, C, Tschentscher, T, Suortti, P, Kheifets, AS, Lun, DR, Sattler, T, Schneider, JR & Bell, F (1999). Three-dimensional electron momentum densities of graphite and fullerene: a comparison. J Phys: Condens Matter 11, 39333942.Google Scholar
Meyer, JC, Eder, F, Kurasch, S, Skakalova, V, Kotakoski, J, Park, HJ, Roth, S, Chuvilin, A, Eyhusen, S, Benner, G, Krasheninnikov, AV & Kaiser, U (2012). Accurate measurement of electron beam induced displacement cross sections for single-layer graphene. Phys Rev Lett 108, 196102.Google Scholar
Mishra, MC, Kumar, R, Sharma, G, Vijay, YK & Sharma, BK (2011). Size dependent electron momentum density distribution in ZnS. Physica B 406, 43074311.Google Scholar
Moscovici, J, Loupias, G, Rabii, S, Erwin, S, Rassat, A & Fabre, C (1995). Compton profiles and electronic density in C60. Europhys Lett 31, 8793.Google Scholar
Okada, JT, Sit, PHL, Watanabe, Y, Barbiellini, B, Ishikawa, T, Wang, YJ, Itou, M, Sakurai, Y, Bansil, A, Ishikawa, R, Hamaishi, M, Paradis, PF, Kimura, K, Ishikawa, T & Nanao, S (2015). Visualizing the mixed bonding properties of liquid boron with high-resolution X-ray Compton scattering. Phys Rev Lett 114, 177401.Google Scholar
Okada, JT, Sit, PHL, Watanabe, Y, Wang, YJ, Barbiellini, B, Ishikawa, T, Itou, M, Sakurai, Y, Bansil, A, Ishikawa, R, Hamaishi, M, Masaki, T, Paradis, PF, Kimura, K, Ishikawa, T & Nanao, S (2012). Persistence of covalent bonding in liquid silicon probed by inelastic X-ray scattering. Phys Rev Lett 108, 067402.Google Scholar
Reed, WA, Eisenberger, P, Pandey, KC & Snyder, LC (1974). Electron momentum distributions in graphite and diamond and carbon-carbon bonding. Phys Rev B 10, 15071515.Google Scholar
Reiter, GF, Deb, A, Sakurai, Y, Itou, M, Krishnan, VG & Paddison, SJ (2013). Anomalous ground state of the electrons in nanoconfined water. Phys Rev Lett 111, 036803.Google Scholar
Sato, Y & Terauchi, M (2014). High-energy resolution electron energy-loss spectroscopy study of interband transitions characteristic to single-walled carbon nanotubes. Microsc Microanal 20, 807814.Google Scholar
Schattschneider, P & Exner, A (1995). Progress in electron Compton scattering. Ultramicroscopy 59, 241253.Google Scholar
Schattschneider, P, Jonas, P & Mandl, M (1991). Electron Compton-scattering on solids-a feasibility experiment on a peels system. Microsc Microanal Microstruct 2, 367375.Google Scholar
Senga, R, Pichler, T, Yomogida, Y, Tanaka, T, Kataura, H & Suenaga, K (2018). Direct proof of a defect-modulated gap transition in semiconducting nanotubes. Nano Lett 18, 39203925.Google Scholar
Sharma, G, Joshi, KB, Mishra, MC, Shrivastava, S, Vijay, YK & Sharma, BK (2011). Electron momentum density in multiwall carbon nanotubes. Physica E 43, 10841086.Google Scholar
Su, DS, Jonas, P & Schattschneider, P (1992). The multiple-scattering problem in electron Compton scattering on solids. Philos Mag B 66, 405418.Google Scholar
Su, DS & Schattschneider, P (1992). Deconvolution of angle-resolved electron energy-loss spectra. Philos Mag A 65, 11271140.Google Scholar
Suzuki, K, Barbiellini, B, Orikasa, Y, Go, N, Sakurai, H, Kaprzyk, S, Itou, M, Yamamoto, K, Uchimoto, Y, Wang, YJ, Hafiz, H, Bansil, A & Sakurai, Y (2015). Extracting the redox orbitals in Li battery materials with high-resolution X-ray compton scattering spectroscopy. Phys Rev Lett 114, 087401.Google Scholar
Williams, BG (1977). Compton Scattering. New York: McGraw-Hill.Google Scholar
Williams, BG & Bourdillon, AJ (1982). Localized Compton scattering using energy-loss spectroscopy. J Phys C Solid State 15, 68816890.Google Scholar
Williams, BG, Parkinson, GM, Eckhardt, CJ, Thomas, JM & Sparrow, T (1981). A new approach to the measurement of the momentum densities in solids using an electron microscope. Chem Phys Lett 78, 434438.Google Scholar
Williams, BG, Sparrow, TG & Egerton, RF (1984). Electron Compton scattering from solids. Proc R Soc Lond A 393, 409422.Google Scholar
Williams, BG & Thomas, JM (1983). Compton scattering as a technique for the study of solids. Intl Rev Phys Chem 3, 3982.Google Scholar
Zeynalov, E, Allen, NS, Salmanova, N & Vishnyakov, V (2019). Carbon nanotubes catalysis in liquid-phase aerobic oxidation of hydrocarbons: Influence of nanotube impurities. J Phys Chem Solids 127, 245251.Google Scholar
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