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Using TEM Operando Methods to Understand Energy Storage

  • C. Barry Carter (a1) (a2) (a3), Matthew T. Janish (a1), Katherine L. Jungjohann (a2) and Grant Norton (a4)
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References

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[1] Huggins, RA (2009). Advanced Batteries: Materials Science Aspects. Springer, US.
[2] Goodenough, JB & Kim, YU Chem Mater 22 (2010). p. 587.
[3] Zhang, Q, et al, Nano letters 10 (2010). p. 3243.
[4] Zhao, K, et al, Nano letters 11 (2011). p. 2962.
[5] Chan, CK, et al, Nature Nanotechnol 3 (2008). p. 31.
[6] Liu, XH, et al, Nano letters 11 (2011). p. 2251.
[7] Liu, XH, et al, Nano letters 11 (2011). p. 3991.
[8] Huang, JY, et al, Science 330 (2010). p. 1515.
[9] Janish, MT, et al, Journal of Materials Science 51 (2015). p. 589.
[10] Janish, MT & Carter, CB Scripta Materialia 107 (2015). p. 22.
[11] Yu, YJ, et al, Acs Applied Materials & Interfaces 6 (2014). p. 5884.
[12] Hu, YM, et al, Electrochimica Acta 186 (2015). p. 271.
[13] Wang, X, et al, Adv Functional Mater 22 (2012). p. 2682.
[14] Cui, L-F, et al, Nano letters 9 (2009). p. 491.
[15] MTJ would like to acknowledge GAANN Fellowship from the Department of Education. This work was performed at Sandia National Laboratory at the Center for Integrated Nanotechnologies, a DOE-BES supported national user facility, and in the Materials Characterization Department. Sandia is a multiprogram laboratory operated by Sandia Corporation, a Lockheed Martin Company, for the US Department of Energy under contract DEAC04-94AL85000.

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