X-ray photoelectron spectroscopy study of the interaction of lithium with graphene
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Lyubov G. Bulusheva
Abstract
Graphene-like nanostructures, solely or in combination with redox active compounds, are an important component of battery electrodes. Design of effective electrode materials requires a deep understanding of electrochemical reactions occurring at graphene surfaces. The methods of X-ray photoelectron spectroscopy (XPS) are very helpful in such research, providing the composition of studied samples and electronic state of individual elements. In this chapter, we demonstrate advantages of XPS for monitoring of chemical vapor deposition graphene growth and lithium penetration under graphene layers, disclosing of interactions with metals and interface states.
References
[1] Tarascon J-M, Armand M. Issues and challenges facing rechargeable lithium batteries. Nature. 2001;414:359–67.10.1038/35104644Suche in Google Scholar PubMed
[2] An SJ, Li J, Daniel C, Mohanty D, Nagpure S, Wood DL, III. The state of understanding of the lithium-ion-battery graphite solid electrolyte (SEI) and its relationship to formation cycling. Carbon. 2016;105:52–76.10.1016/j.carbon.2016.04.008Suche in Google Scholar
[3] Lu XY, Jin XH, Sun J. Advances of graphene application in electrode materials for lithium ion batteries. Science China. 2015;58:1829–40.10.1007/s11431-015-5927-8Suche in Google Scholar
[4] Dong Y, Wu Z-S, Ren W, Cheng H-M, Bao X. Graphene: a promising 2D material for electrochemical energy storage. Science Bulletin. 2017;62:724–40.10.1016/j.scib.2017.04.010Suche in Google Scholar
[5] Oswald S, Mikhailova D, Scheiba F, Reichel P, Fiedler A, Ehrenberg H. XPS investigations of electrolyte/electrode interactions for various Li-ion battery materials. Anal Bioanal Chem. 2011;400:691–6.10.1007/s00216-010-4646-zSuche in Google Scholar PubMed
[6] Leroy S, Blanchard F, Dedryvere R, Martinez H, Carre B, Lemordant D, Gonbeau D. Surface film formation on a graphite electrode in Li-ion batteries: AFM and XPS study. Surf Interface Anal. 2005;37:773–81.10.1002/sia.2072Suche in Google Scholar
[7] Oswald S, Nikolowski K, Ehrenberg H. XPS investigations of valence changes during cycling of LiCrMnO4-based cathodes in Li-ion batteries. Surf Interface Anal. 2010;42:916–21.10.1002/sia.3296Suche in Google Scholar
[8] Hüfner S. Photoelectron spectroscopy, principles and applications. Berlin/Heidelberg/New York: Springer, 1996. ISBN: 3-540-41802-4.10.1007/978-3-662-03209-1Suche in Google Scholar
[9] Varykhalov A, Sánchez-Barriga J, Shikin AM, Biswas C, Vescovo E, Rybkin A, Marchenko D, Rader O. Electronic and magnetic properties of quasifreestanding graphene on Ni. Phys Rev Lett. 2008;101:157601.10.1103/PhysRevLett.101.157601Suche in Google Scholar PubMed
[10] Grüneis A, Kummer K, Vyalikh DV. Dynamics of graphene growth on a metal surface: a time-dependent photoemission study. New J Phys. 2009;11:073050.10.1088/1367-2630/11/7/073050Suche in Google Scholar
[11] Grüneis A, Vyalikh DV. Tunable hybridization between electronic states of graphene and a metal surface. Phys Rev B. 2008;77:193401.10.1103/PhysRevB.77.193401Suche in Google Scholar
[12] Usachov DY, Fedorov AV, Vilkov OY, Petukhov AE, Rybkin AG, Ernst A, et al. Large-scale sublattice asymmetry in pure and boron-doped graphene. Nano Lett. 2016;16:4535.10.1021/acs.nanolett.6b01795Suche in Google Scholar PubMed
[13] Kataev EY, Itkis DM, Fedorov AV, Senkovskiy BV, Usachov DY, Verbitskiy NI, et al. Oxygen reduction by lithiated graphene and graphene-based materials. ACS Nano. 2015;9:320–6.10.1021/nn5052103Suche in Google Scholar PubMed
[14] Blume R, Rosenthal D, Tessonnier J-P, Li H, Knop-Gericke A, Schlögl R. Characterizing graphitic carbon with X-ray photoelectron spectroscopy: a step-by-step approach. Chem Cat Chem. 2015;7:2871–81.10.1002/cctc.201500344Suche in Google Scholar
[15] Varykhalov A, Marchenko D, Sánchez-Barriga J, Scholz MR, Verberck B, Trauzettel B, Wehling TO, Cabone C, Rader O. Intact dirac cones at brocken sublattice symmetry: photoemission study of graphene on Ni and Co. Phys Rev X. 2012;2:041017.Suche in Google Scholar
[16] Lee CM, Yang S-H, Mun B-J, Ross PN, Jr. Surface structure of lithiated graphite by X-ray photoelectron diffraction. Surf Sci. 2001;477:126–32.10.1016/S0039-6028(00)01106-7Suche in Google Scholar
[17] Wertheim GK, Th PM, Van Attekum M, Basu S. Electronic structure of lithium graphite. Solid State Commun. 1980;33:1127–30.10.1016/0038-1098(80)91089-3Suche in Google Scholar
[18] Schröder UA, Petrović M, Gerber T, Martínez-Galera AJ, Grånäs E, Arman MA, Herbig C, et al. Core level shifts of intercalated graphene. 2D Mater. 2017;4:015013.10.1088/2053-1583/4/1/015013Suche in Google Scholar
[19] Zhang L, Ye Y, Cheng D, Pan H, Zhu J. Intercalation of Li at graphene/Cu interface. J Phys Chem C. 2013;117:9259–65.10.1021/jp401290fSuche in Google Scholar
[20] Oswald S. Binding energy referencing of XPS in alkali metal-based battery materials research (I): basic model investigations. App Surf Sci. 2015;351:492–503.10.1016/j.apsusc.2015.05.029Suche in Google Scholar
[21] Lapteva LL, Fedoseeva YV, Gevko PN, Smirnov DA, Gusel'nikov AV, Bulusheva LG, Okotrub AV. X-ray spectroscopy study of lithiated graphite obtained by thermal deposition of lithium. J Struct Chem. 2017;58:1173–9.10.1134/S0022476617060154Suche in Google Scholar
[22] Bulusheva LG, Kanygin MA, Arkhipov VE, Popov KM, Fedoseeva YV, Smirnov DA, Okotrub AV. In situ X-ray photoelectron spectroscopy study of lithium interaction with graphene and nitrogen-doped graphene films produced by chemical vapor deposition. J Phys Chem C. 2017;121:5108–14.10.1021/acs.jpcc.6b12687Suche in Google Scholar
[23] Wang H, Maiyalagan T, Wang X. Review on recent progress in nitrogen-doped graphene: synthesis, characterization and its potential applications. ACS Catal. 2012;2:781–94.10.1021/cs200652ySuche in Google Scholar
[24] Itkis DM, Velasco-Velez JJ, Knop-Gericke A, Vyalikh A, Avdeev MV, Yashina LV. Probing operating electrochemical interfaces by photons and neutrons. Chem Electro Chem. 2015;2:1427–45.10.1002/celc.201500155Suche in Google Scholar
[25] Stoltze P, Nørskov JK. Bridging the” pressure gap” between ultrahigh-vacuum surface physics and high-pressure catalysis. Phys Rev Lett. 1985;55:2502.10.1103/PhysRevLett.55.2502Suche in Google Scholar
[26] Siegbahn H, Svensson S, Lundholm M. A new method for ESCA studies of liquid-phase samples. J Electron Spectr Rel Phenom. 1981;24:205–13.10.1016/0368-2048(81)80007-2Suche in Google Scholar
[27] Ogletree DF, Bluhm H, Lebedev G, Fadley CS, Hussain Z, Salmeron M. A differentially pumped electrostatic lens system for photoemission studies in the millibar range. Rev Sci Ins. 2002;73:3872–7.10.1063/1.1512336Suche in Google Scholar
[28] Kaya S, Ogasawara H, Näslund LA , Forsell JO, Casalongue HS, Miller DJ, Nilsson A. Ambient-pressure photoelectron spectroscopy for heterogeneous catalysis and electrochemistry. Cat Tod. 2013;205:101–5.10.1016/j.cattod.2012.08.005Suche in Google Scholar
[29] Klyushin A, Arrigo R, Pfeifer V, Jones T, Velasco-Velez JJ , Knop-Gericke A. Catalyst electronic surface structure under gas and liquid environments, 2013.Suche in Google Scholar
[30] Kolmakov A, Dikin DA, Cote LJ, Huang J, Abyaneh MK, Amati M, Kiskinova M. Graphene oxide windows for in situ environmental cell photoelectron spectroscopy. Nat Nanotechnol. 2011;6:651-7.10.1038/nnano.2011.130Suche in Google Scholar PubMed
[31] Velasco-Velez JJ, Pfeifer V, Hävecker M, Schlögl R, Knop-Gericke A. Photoelectron spectroscopy at the graphene-liquid interface reveals the electronic structure of an electrodeposited cobalt/graphene electrocatalyst. Angew Chem Int Ed. 2015;54:14554–810.1002/anie.201506044Suche in Google Scholar PubMed
[32] Velasco-Vélez JJ, Pfeifer V, Hävecker M, Wang R, Centeno A, Zurutuza A, Schlögl R, Knop-Gericke A. Atmospheric pressure X-ray photoelectron spectroscopy apparatus: bridging the pressure gap. Rev Sci Instr. 2016;87:053121.10.1063/1.4951724Suche in Google Scholar PubMed
© 2018 Walter de Gruyter GmbH, Berlin/Boston
Artikel in diesem Heft
- Electrodes: definitions and systematisation – a crystallographers view
- Synthesis of metallic nanoparticles by microplasma
- X-ray photoelectron spectroscopy study of the interaction of lithium with graphene
- Neutron methods for tracking lithium in operating electrodes and interfaces
- Synthesis and characterization of size-controlled atomically precise gold clusters
- Magnetic resonance spectroscopy approaches for electrochemical research
- Metastability of the boron-vacancy complex in silicon: Insights from hybrid functional calculations
- Homogeneously catalyzed hydrogenation and dehydrogenation reactions – From a mechanistic point of view
- Size and Shape Controlled Synthesis of Pd Nanocrystals
Artikel in diesem Heft
- Electrodes: definitions and systematisation – a crystallographers view
- Synthesis of metallic nanoparticles by microplasma
- X-ray photoelectron spectroscopy study of the interaction of lithium with graphene
- Neutron methods for tracking lithium in operating electrodes and interfaces
- Synthesis and characterization of size-controlled atomically precise gold clusters
- Magnetic resonance spectroscopy approaches for electrochemical research
- Metastability of the boron-vacancy complex in silicon: Insights from hybrid functional calculations
- Homogeneously catalyzed hydrogenation and dehydrogenation reactions – From a mechanistic point of view
- Size and Shape Controlled Synthesis of Pd Nanocrystals
