DAFTAR PUSTAKA

.

Chang, Horng-Yie. 1998. Effects of Rapid on the Conductivity of Multiple Doped Ceria-Based Electrolyte. Journal of Power Sources. 196: 1704-1711.

Chew, S.Y., et all. 2008. Thin Nanostuctured LiMn2O4 Film by Flame Spray Deposition an In Situ Annealing Method. Journal of Power Sources. Vol.189. hal. 449 – 453.

Courtel, Fabrice M et al. 2011. Water Soluble Binders for MCMB Carbon Anodes fot Lithium Ion Batteries. Journal of Power Source.196 : 2128-2134. Cullity, B.D. 1972. Introduction to Magnetic Material. Addison - Wesley,

Publishing Company, Inc. USA.

C. Zhang, Y. Zhang, J. Wang, D. Wang, D. He, and Y. Zia. “Li4Ti5O12 prepared by a modified citric acid sol-gel method for lithium-ion battery”. Journal of Power Sources, vol. 236, pp. 118-125.

Guo-Rong, ZHANG Xin-long, PENG Zhong-dong. 2011. Preparation and electrochemical performance of tantalum-doped lithium titanate as anode

material for lithium-ion battery. , China. School of Metallurgical Science

and Engineering, Central South University, Changsha 410083. Herstedt, M. 2003. Towards Safer Lithium-Ion Batteries. Departement of Materials.

http://files.tested.com/upload/0/5/16904-lithium-ion-separator.gif, diakses tanggal 16 Maret 2016.

Lawrence H. Van Vlack. 1992. Ilmu dan Teknologi bahan, Erlangga, edisi 5 Linden, David. 2002. Handbook of Batteries. McGraw-Hill vol 1. New York. Nordh, Tim. 2013. Li4Ti5O12 as an anode material for Li ion batteries in situ XRD

and XPS studies. [Thesis]. Uppsala Universitet. Upteck k 13001.

Notter, D.A. Gauch, M. Widmer, R. 2010. Environ Sci Technol. 44 : 6550.

Scrosati, B. and Garche, J. 2010. Lithium batteries: Status, prospects and future. J. Power Sources. 195: 2419–2430.

Simon, D.R. 2007. Characterization of Li4Ti5O12 and LiMn2O4 spinel materials

treated with aqueous acidic solutions. University of Cincinnati

Netherlands.

Subhan, Achmad. 2011. Fabrikasi dan Karakterisasi Li4Ti5O12 Untuk Bahan Anoda Baterai Lithium Keramik. [Thesis]. Depok : Universitas Indonesia. Suci, P.S. 2015. Pengaruh Komposisi Lembaran Anoda LTO (Li4Ti5O12)

Terhadap Performa Sel Baterai Ion Lithium. [Skripsi]. Medan : Universitas Sumatera Utara.

Tarascon J-M, Armand M. 2001. Issues and Challenges Facing Rechargeable Lithium Batteries. 414: 359-67.

Triwibowo, Joko. 2011. Rekayasa Bahan LixTMnxFez (PO4)3 sebagai Katoda Solid Polymer Battery (SPB) Lithium. [Tesis]. Universitas Indonesia: Depok.

Wakihara, M. 2001. Material Science and Engineering. R33:109.

Wang, J. 2000. Analytical Electrochemistry. Chapter 2. John Wiley & Sons. Wen, R. 2012. Nanostructured Li4Ti5O12 as Anode Material for Lithium Ion

Batteries. [Thesis]. University of New South Wales.

Winter, M and Ralph, J. Brodd. 2004. What Are Batteries, Fuel Cells, and Supercapacitors?. Washington. 104 μ 4β45−4β6λ.

Xiangcheng Sun, Manu Hegde, Yuefei Zhang, Min He, Lin Gu, Yongqing Wang, Jie Shu, Pavle V. Radovanovic, and Bo Cui. 2014. Structure and Electrochemical Properties of Spinel Li4Ti5O12 Nanocomposites as

Anode for Lithium-Ion Battery. Int. J. Electrochem. Sci.9: 1583 – 1596.

Yao, Yupeng. 2003. Carbon Based Anode Materials Lithium Ion Batteries. [Thesis]. University of Wollongong: Institute For Superconducting & Electronic Materials, Faculty of Engineering.

Yurong Ren, Peng Lu, Xiaobing Huang, Shibiao Zhou, Yuandao Chen, Beiping Liu, Fuqiang Chu, Jianning Ding. 2015. In-situ synthesis of nano-Li4Ti5O12/C composite as an anode material for Li-ion batteries. Solid

State Ionics 274 (2015) 83–87

Zhao, xin et al. 2011. In Plane Vacancy Enabled High Power Si Graphene Composite Electrode For Lithium Ion Batteries. Journal of advanced

energy materials.