The low-temperature chemical synthesis of Li 4 Ti 5 O 12 powder for Li-ion battery anodes ChemCYS 2016 – Blankenberge – 17/03/2016 D. De Sloovere, N. Peys,

Slides:



Advertisements
Similar presentations
Zinc Air Batteries By: Ana Brar.
Advertisements

Polymer graphite composite anodes for Li-ion batteries Basker Veeraraghavan, Bala Haran, Ralph White and Branko Popov University of South Carolina, Columbia,
NPRE 498 Energy Storage Systems Garrett Gusloff 11/21/2014
Filippo Parodi /Paolo Capobianco (Ansaldo Fuel Cells S.p.A.)
Materials for Electrochemical Energy Conversion
0.65 V Identifying Redox Active Molecules to Understand Electrochemistry of Functionalized Silicon Anodes for Lithium-ion Batteries Kate Scholz with Laura.
Molten Salt Method of Preparation and Optimization of TiO 2 Phases Chan Tze Yang, Aloysius 1,2, M.V. Reddy 2,3 *, S. Adams 3 and B.V.R. Chowdari 2 1 SRP.
Biological Engineering Electrochemistry & Virus-Templated Electrodes F. John Burpo Biomolecular Materials Laboratory Massachusetts Institute of Technology.
Silicon Nanowires for Rechargeable Li-Ion Batteries Onur Ergen, Brian Lambson, Anthony Yeh EE C235, Spring 2009.
Battery University online: Brief history of the battery.
Structural and energy storage studies of Copper Oxide Mei Shiyuan 1, M.V. Reddy 2, 3*, S. Adams 3, B.V.R.Chowdan 2 1 SRP student, Hwa Chong Institution,
Materials for Electrochemical Energy Conversion
Electrochemical Characterization of Li-ion Batteries for Hybrid Application Ageing Study Abdilbari Shifa Mussa, Rakel Wreland Lindström, Mårten Behm,
THT is the Original Company for ARC & Battery pioneered ARC for over 20 years Pioneered Li Battery for over 10 years Sales, service, support worldwide.
Chapter 21: Electrochemistry
To combust or not to combust, that’s the question Wouter Marchal.
Studies on Capacity Fade of Spinel based Li-Ion Batteries by P. Ramadass, A. Durairajan, Bala S. Haran, R. E. White and B. N. Popov Center for Electrochemical.
Department of Chemical Engineering University of South Carolina by Hansung Kim and Branko N. Popov Department of Chemical Engineering Center for Electrochemical.
Please Pick Up  Chemical Reactions Problem Set..
A. Rivera Defects in Materials, IRI, TUDelft
Capacity Fade Studies of LiCoO 2 Based Li-ion Cells Cycled at Different Temperatures Bala S. Haran, P.Ramadass, Ralph E. White and Branko N. Popov Center.
Nanoscale Electrode Development for Fundamental Studies of Mixed Ionic and Electronic Conductors as High Temperature Fuel Cell Components Jeevitha Evanjeline.
Please Pick Up  Chemical Reactions Problem Set..
Chapter 19 Electrochemistry
DFG Priority Programme SPP 1473, WeNDeLIB:
Electrochemistry Ch. 17. Moving Electrons What kind of chemical reaction relates to the concept of electricity? What kind of chemical reaction relates.
EE235 Nanofabrication John Gerling High-performance lithium battery anodes using silicon nanowires.
PH0101 UNIT-5 LECTURE 7 Introduction Types of battery Lithium battery
CHAPTER 1: INTRODUCTION TO MATTER
Nanotechnology for Future Batteries
Journal Club Shu Jinbo Direct Synthesis of Self-Assembled Ferrite/Carbon Hybrid Nanosheets for High Performance Lithium-Ion Battery Anodes.
Fabrication of copper/single-walled carbon nanohorn hybrid material by microwave irradiation Parichat Thipayang, Kunio Shinohara, Chantamanee Poonjarernsilp,
Section 18.1 Electron Transfer Reactions 1.To learn about metal-nonmetal oxidation–reduction reactions 2.To learn to assign oxidation states Objectives.
Chapter 21: Electrochemistry III Chemical Change and Electrical Work 21.6 Corrosion: A Case of Environmental Electrochemistry 21.7 Electrolytic Cells:
Studies on Direct Methanol Fuel Cell: An electro-chemical energy conversion device Jay Pandey Research Scholar Department of Chemical Engineering Indian.
Oxidation and Reduction Reactions that involve electron transfer Batteries and chemistry.
Electrochemistry. Electrochemical Cells  Electrons are transferred between the particles being oxidized and reduced  Two types –Spontaneous = Voltaic.
Oxidation and Reduction
Synthesis Rutile titania nanofibers are synthesized using electrospinning and sol-gel coating techniques. A large sheet of nylon-6 nanofibers are synthesized.
CESE November 13, 2009 Jai Prakash Center for Electrochemical Science and Engineering Department of Chemical and Biological Engineering Illinois Institute.
INGAS 6-months Meeting, Prague, Czech Republic, May 2009 INGAS INtegrated GAS Powertrain 1 Institute of Catalysis and Surface Chemistry Polish Academy.
NANO BATTERIES By Soumya Yadala UNIVERSITY OF TULSA.
Theoretical Study of the Flame Synthesis of Titanium Dioxide Nanoparticles Kui Ting Lam, Doug DePrekel, Kevin Ngo, Phu Vo, and Yingbin Ge Department of.
Nanotechnology and the Lithium-ion Battery. Batteries in General –Electrolyte –Electrodes –Anode –Cathode Nanotechnology and the Lithium-ion Battery.
Kinetics. Kinetics - rates of chemical reactions and the mechanisms by which they occur Rate of a chemical reaction - change in the concentration of products.
Changing Matter Physical & Chemical Changes. Matter has properties Two basic types of properties that we can associate with matter. Physical properties.
Cells and Batteries A cell is a unit which includes two electrodes and one electrolyte.
Investigation of electrode materials with 3DOM structures Antony Han Chem 750/7530.
Oxidation-Reduction Dr. Ron Rusay Fall 2001 © Copyright 2001 R.J. Rusay.
Electrochemical Cells in Actions Batteries and Fuel Cells Chapter 15.
 Introduction  Literature Review  Motivation  Experimental  Results and Discussion  Conclusion  Future work  References 2.
Types of Chemical Reactions
Electrochemistry Oxidation-Reduction Dr. Ron Rusay Spring 2004 © Copyright 2004 R.J. Rusay.
AL Chemistry Summer Project Standard enthalpy changes Group 6 (produced by Chen William and Lam Yu Wing)
Chemistry of Life Chapter 2. All Living Things Use Energy Energy in living things is converted from 1 form to another (chemical-physical-thermal etc.)
Chemistry in Biology  The activation energy is the minimum amount of energy needed for reactants to form products in a chemical reaction.  Exothermic.
Noble Metals as Catalysts Oxidation of Methanol at the anode of a DMFC Zach Cater-Cyker 4/20/2006 MS&E 410.
LOGO Water Gas Shift Reaction Over Au/Ce x Ti y O 2 Cheng Wan.
Recent advantages in low temperature proton exchange membrane fuel cells in Russia: materials development and application features March 31, 2015 Andrey.
Electrochemistry Oxidation-Reduction Dr. Ron Rusay Spring 2004 © Copyright 2004 R.J. Rusay.
Photovoltaic Systems Engineering
A. Rivera Defects in Materials, IRI, TUDelft
Aging of Lithium Ion Batteries
JINGYU SI Mechanical Engineering Department
AQA GCSE Energy changes
Nat. Rev. Mater. doi: /natrevmats
He-Qun Dai1,2, Hao Xu1,2, Yong-Ning Zhou2, Fang Lu1, and Zheng-Wen Fu
Photovoltaic Systems Engineering
TABLE I – HEAT OF REACTION
Lithium Sulfur Batteries
Presentation transcript:

The low-temperature chemical synthesis of Li 4 Ti 5 O 12 powder for Li-ion battery anodes ChemCYS 2016 – Blankenberge – 17/03/2016 D. De Sloovere, N. Peys, C. De Dobbelaere, M.K. Van Bael, A. Hardy

Contents  Why Li 4 Ti 5 O 12 ?  Low-temperature processing  Precursor synthesis  Results  Conclusion 2

Why Li 4 Ti 5 O 12 ? 3 Cheng, F., Liang, J., Tao, Z., Chen, J. (2011). Functional Materials for Rechargeable batteries. Adv. Mater., 23,

Why Li 4 Ti 5 O 12 ?  Li-ion batteries offer high energy density  Quick commercialization after introduction of graphite as anode material  Increased safety because of lower volume expansion  Problem at the end of Li insertion Tarascon & Armand (2001). Issues and challenges facing rechargeable lithium batteries. Nature, 414,

Why Li 4 Ti 5 O 12 ?  Advantages of LTO as anode  Extremely flat working potential at 1.55 V  Avoids reduction of electrolyte on anode surface  Circumvents formation SEI  Zero-strain insertion material  Good cycling stability  Theoretical capacity of 175 mAh g -1 5

Why Li 4 Ti 5 O 12 ?  Solid-state synthesis + Easy -Irregular and inhomogeneous products -600 – 1000 °C  Sol-gel synthesis + Molecular mixing: homogeneity -Up to 800 °C 6 Han, S. W., Ryu, J. H., Jeong, J. & Yoon, D. H. Solid-state synthesis of Li4Ti5O12 for high power lithium ion battery applications. J. Alloys Compd. 570, 144–149 (2013). Zhang, S. S. The effect of the charging protocol on the cycle life of a Li-ion battery. J. Power Sources 161, 1385–1391 (2006).

Contents  Why Li 4 Ti 5 O 12 ?  Low-temperature processing  Precursor synthesis and processing  Results  Conclusion 7

Low-temperature processing  Combustion synthesis  Self-sustainable reaction leading to internal temperature build-up  High temperatures in sample vs. low processing temperature  By exothermic reaction between fuel and oxidizer 8 Patil, K.C. et al., Chemistry of nanocrystalline oxide materials, 2008, world scientific, Singapore

Low-temperature processing  Advantages  Cheap  Fast  Low processing temperatures  Disadvantages  Complex mechanism  Properties of the product depend on processing parameters  Gas flow rate  Atmosphere 9

Low-temperature processing Previous literature Solution combustion synthesis, but not low- temperature Prakash et al. (2010). Solution-Combustion Synthesized Nanocrystalline Li 4 Ti 5 O 12 As High-Rate Performance Li- Ion Battery Anode. Chem. Mater., 22, LiNO 3 GlycineLTO precTiO(NO 3 ) °C 10

Contents  Why Li 4 Ti 5 O 12 ?  Low-temperature processing  Precursor synthesis  Results  Conclusion 11

Precursor synthesis and processing H2OH2OH2OH2O LiNO 3 in H 2 O Hydrated Ti-oxide Reflux 80 o C Ti in H 2 O NH 3 NH 4 NO 3 pH = 7 Lactic acid 12

Contents  Why Li 4 Ti 5 O 12 ?  Low-temperature processing  Precursor synthesis  Results  Conclusion 13

TGA-DSC Sudden mass loss process High-temperature degradation TA instruments Q600, 100 ml min -1 dry air, 10 o C min -1 14

TGA-DSC: Theoretically optimized NH 4 NO 3 amount TA instruments Q600, 100 ml min -1 dry air, 10 o C min -1 Exothermic and endothermic reactions NH 4 NO 3 degrades endothermically at high heating rates Biamino, S. & Badini, C. (2004). Combustion synthesis of lanthanum chromite starting from water solutions: Investigation of process mechanism by DTA-TGA-MS. J. Eur. Cer. Soc., 24,

TGA-DSC: Reduced NH 4 NO 3 amount TA instruments Q600, 100 ml min -1 dry air, 10 o C min -1 NH 4 NO 3 is both necessary for and detrimental to combustion reaction! Larger exothermicity Evolved gases? 16

TGA-IR: analysis of evolved gases N2ON2O H2OH2O NO 2 CO 2 NH o C NH 3 : Endothermic NH 4 NO 3 degradation CO 2 : Exothermic fuel-oxidizer reaction NO 2 : Partial combustion or endothermic NH 4 NO 3 degradation 90 ml min -1 dry air, 10 o C min -1 N 2 O: Partial combustion or exothermic NH 4 NO 3 degradation Biamino, S. & Badini, C. (2004). Combustion synthesis of lanthanum chromite starting from water solutions: Investigation of process mechanism by DTA-TGA-MS. J. Eur. Cer. Soc., 24,

FTIR and XRD Shu, J. (2008). Study of the Interface Between Li 4 Ti 5 O 12 Electrodes and Standard Electrolyte Solution in V. Electrochem. Solid-State Lett., 11, A238-A240. Ti-O stretching: LTO N-O strech: NO 3 - H-O-H bending OH - strech There are still nitrates present after combustion LTO Li 2 TiO 3 * * Si substrate Rutile Anatase Presence of impurity phases 18

Electrochemistry  Voltage plateaus of LTO, anatase  Sloped profile due to amorphous material LTO Anatase Discharge capacity of 161 mAh/g 0,2 C 19

Contents  Why Li 4 Ti 5 O 12 ?  Low-temperature processing  Precursor synthesis  Results  Conclusion 20

Conclusion  NH 4 NO 3 reacts in exothermic reaction with fuel but degrades endothermically  Careful optimization required  LTO can be succesfully synthesized at 300 °C, albeit with impurities  The synthesized sample is electrochemically active 21

Acknowledgements  This research was supported by the FWO, the Research Foundation Flanders  XRD: Ken Elen  TG-IR: Wouter Marchal  Other colleagues of the IPC group 22

Feedback: Privacy Policy Feedback
Do Not Sell My Personal Information
About project: SlidePlayer Terms of Service

© 2024 SlidePlayer.com Inc. All rights reserved.