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Microscopy Techniques for Analysis of Nickel Metal Hydride Batteries Constituents

Published online by Cambridge University Press:  09 December 2015

Graham J.C. Carpenter*
Affiliation:
CanmetMaterials, Natural Resources Canada, 555 Booth St., Ottawa, ON, Canada, K1A 0G1
Zbigniew Wronski
Affiliation:
Department of Mechanical and Mechatronics Engineering, University of Waterloo, Waterloo, ON, Canada, N2L 3G1
*
*Corresponding author. graham.carpenter@physics.org
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Abstract

With the need for improvements in the performance of rechargeable batteries has come the necessity to better characterize cell electrodes and their component materials. Electron microscopy has been shown to reveal many important features of microstructure that are becoming increasingly important for understanding the behavior of the components during the many charge/discharge cycles required in modern applications. The aim of this paper is to present an overview of how the full suite of techniques available using transmission electron microscopy (TEM) and scanning transmission electron microscopy was applied to the case of materials for the positive electrode in nickel metal hydride rechargeable battery electrodes. Embedding and sectioning of battery-grade powders with an ultramicrotome was used to produce specimens that could be readily characterized by TEM. Complete electrodes were embedded after drying, and also after dehydration from the original wet state, for examination by optical microscopy and using focused ion beam techniques. Results of these studies are summarized to illustrate the significance of the microstructural information obtained.

Type
Materials Applications and Techniques
Copyright
© Microscopy Society of America 2015 

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References

Ball, M.D., Malis, T.F. & Steele, D. (1984). Ultramicrotomy as a specimen preparation technique for analytical electron microscopy. In Analytical Electron Microscopy - 1984, Williams, D.B. & Joy, D.C. (Eds), pp. 189–192. San Francisco, CA: San Francisco Press.Google Scholar
Carpenter, G.J.C. (2014). Modification of a Gatan PIPS for thin film deposition. Microsc Today 22, 3639.Google Scholar
Carpenter, G.J.C. & Wronski, Z.S. (1998). Application of field-emission TEM/STEM to studies of nickel hydride battery materials. In Proceedings of the EURAM-11 Eleventh European Conference on Electron Microscopy, Dublin, Ireland, August 26–30. Electron Microscopy 96, Committee European Societies of Microscopy (Ed.), pp. II-131–132. Brussels: CESM.Google Scholar
Carpenter, G.J.C. & Wronski, Z.S. (1999). Nanocrystalline NiO and NiO-Ni(OH)2 composite powders prepared by thermal and mechanical dehydroxylation of nickel hydroxide. Nanostruct Mater 11, 6780.CrossRefGoogle Scholar
Carpenter, G.J.C. & Wronski, Z.S. (2004). The characterization of nanostructured CVD Ni powders using transmission electron microscopy. J Nanopart Res 6 215221.Google Scholar
Carpenter, G.J.C., Wronski, Z.S. & Phaneuf, M.W. (2004). A TEM study of nanopores and embrittlement of CVD nickel foam. Mater Sci Technol 20, 14211426.CrossRefGoogle Scholar
Casas-Cabanas, M., Canales-Vazquez, J., Rodriguez-Carvajal, J. & Palacin, M.R. (2007). Deciphering the structural transformations during nickel oxyhydroxide electrode operation. J Am Chem Soc 129, 58405842.Google Scholar
Dalmas, C. & Tessier, C. (1997). Stacking faults in the structure of nickel hydroxide: A rationale of its high electrochemical activity. J Mater Chem 7, 14391443.Google Scholar
Glauert, A.M. & Lewis, P.R. (1998). Biological Specimen Preparation for Transmission Electron Microscopy. Cambridge, UK: University Press.Google Scholar
Kiani, M.A., Mousavi, M.F. & Ghasemi, S. (2010). Size effect investigation on battery performance: Comparison between micro- and nano-particles of β-Ni(OH)2 as nickel battery cathode material. J Power Sources 195, 57945800.Google Scholar
Li, J., Shangguan, E., Guo, D., Tian, M., Wang, Y., Li, Q., Chang, Z., Yuan, X.-Z. & Wang, H. (2014). Synthesis, characterization and electrochemical performance of high-density aluminum substituted α-nickel hydroxide cathode material for nickel-based rechargeable batteries. J Power Sources 270, 121130.Google Scholar
Martineau, D. & Wronski, Z.S. (1999). Real-time and in-situ swelling of nickel hydroxide pasted electrodes during cycling. J New Mat Elect Syst 2, 233238.Google Scholar
Olurin, O.B., Wilkinson, D.S., Weatherly, G.C., Pasurin, V. & Shu, J. (2003). Strength and ductility of as-plated and sintered CVD nickel foams. Composites Science and Technology 63, 23172329.Google Scholar
Phaneuf, M. (2005). FIB for materials science application – A review. In Introduction to Focused Ion Beams, Giannuzzi L.A. & Stevie F.A. (Eds.), pp. 143172 New York, NY, USA: Springer. Retrieved 14 July 2015 from http://link.springer.com/chapter/10.1007%2F0-387-23313-X_8.Google Scholar
Phaneuf, M. (2015 a). Sectioning and imaging battery electrodes without mechanical pre-preparation, Fibics, Inc., Ottawa, Canada. Retrieved 11 November 2015 from http://www.fibics.com/fib/application/sectioning-and-imaging-battery-electrodes-without-mechanical-pre-preparation/30/.Google Scholar
Phaneuf, M. (2015 b). Private communication, Fibics, Inc., Ottawa.Google Scholar
Qian, D., Ma, C., More, K.L., Meng, Y.S. & Chi, M. (2015). Advanced analytical electron microscopy for lithium-ion batteries. NPG Asia Mater 7, e193.Google Scholar
Shangguan, E., Chang, Z., Tang, H., Yuan, X.-Z. & Wang, H. (2010). Synthesis and characterization of high-density non-spherical Ni(OH)2 cathode material for Ni-MH batteries. Int J Hydrogen Energy 35, 97169724.Google Scholar
Shehata, M.T. & Carpenter, G.J.C. (1996). Microstructural characterization methodologies for Ni/Ni(OH)2 powders for battery applications. Microstruct Sci 23, 207213.Google Scholar
Wronski, Z.S. (2001). Materials for rechargeable batteries and clean hydrogen energy sources. Int Mater Rev 46, 152.Google Scholar
Wronski, Z.S., Brown, J., Carpenter, G.J.C., Cousineau, E.J.-C., Jackman, J.A., Mcmahon, G., Shehata, M.T., Mikhail, S. & Kalal, P. (1996 a). Surface and physical properties of fine battery-grade Ni powders manufactured by the Inco chemical vapour deposition process: An integrated characterization study. CANMET Report MTL No. 95-12, April, Natural Resources Canada, Ottawa, pp. 1–64.Google Scholar
Wronski, Z.S., Brown, J. & Pandya, K. (2001). X ray absorption XANES and EXAFS study of NiCo(OH)2 active mass in the nickel positive electrode of the nickel metal hydride cell, In NSLS (2001) Activity Report: Beamline 11A, Corwin, M.A. (Ed.), p. 685. Upton, NY: NSLS-National Synchrotron Light Source, Brookhaven National Laboratory.Google Scholar
Wronski, Z.S., Carpenter, G.J.C. & Kalal, P.J. (1996 b). An integrated characterization approach for ranking nickel hydroxides designed for high-performance positive electrodes in batteries for electric vehicles. In Proceedings of the Electrochemical Society Meeting on Exploratory Research & Development of Batteries for Electric & Hybrid Vehicles, San Antonio, TX, October 6–11. Electrochemical Proceedings, Vol 96-14, Adams W.A., Ladgrebe A.R., Scrosati B. (Eds.), pp. 177188. Pennington, NJ, USA: The Electrochemical Society.Google Scholar
Wronski, Z.S., Carpenter, G.J.C. & Martineau, D. (2000). Layered nanocrystals and mesostructured battery powders: Maximizing energy and power density in layered Ni hydroxides. In Extended Abstracts 198th Electrochemical Society Meeting, Phoenix, AZ, October 22–27, Vol 2000-2. p. 252. Pennington, NJ, USA: The Electrochemical Society.Google Scholar
Wronski, Z.S., Carpenter, G.J.C., Martineau, D. & Kalal, P. (1997). Microstructure, morphology and disorder in spherical Ni hydroxides for pasted nickel electrodes in high energy density rechargeable alkaline batteries. In Proceedings of the Electrochemical Society Meeting on Batteries for Portable Applications and Electric Vehicles, Paris, August 31–September 5. Electrochemical Society Proceedings, Vol 97-18, Holmes C.F. & Landgrebe A.R. (Eds.), pp. 804811. Pennington, NJ, USA: The Electrochemical Society.Google Scholar
Wronski, Z.S., Martineau, D. & Carpenter, G.J.C. (2003). Layered nanocrystals for electrochemical power sources: Nanostructured Ni hydroxides for the positive electrode in NiMH cells, Extended Abstracts 203rd Electrochemical Society Meeting – Le Palais des Congres Paris, France, April 27–May 2, Vol 2003-1, p. 1674. Retrieved 11 November 2015 from http://www.electrochem.org/dl/ma/203/pdfs/1674.pdf.Google Scholar
Yuan, G., Huang, S., Li, Y., Wang, H. (2010). Synthesis and characterization of spherical nonstoichiometric Ni(OH)x (x = 2.03-2.10) as electrode materials. J Power Sources 195, 50945100.Google Scholar
Zhang, W., Theil, K., Jorgensen, P.S., Thyden, K., Bentzen, J.J., Abdellahi, E., Sudireddi, B.R., Chen, M. & Bowen, J.R. (2013). Transmission electron microscopy specimen preparation method for multiphase porous functional ceramics. Microsc Microanal 19, 501505.Google Scholar