Tailor Made Carbon and Graphite Based Anode Materials for Lithium Ion Batteries Heribert Walter, Battery+Storage 2013
Agenda SGL Group at a Glance Anode Materials Overview Material Synthesis and Modification New Generation Anodes: Carbon/Graphite composites Summary Page 2
Company Profile SGL Group is one of the world s largest manufacturers of carbon-based products Comprehensive portfolio ranging from carbon and graphite products to carbon fibers and composites 47 production sites worldwide Sales of ~ 1.7 bn in 2012 Head office in Wiesbaden/Germany Approx. 6,700 employees worldwide Listed on MDAX Service network covering more than 100 countries Page 3
Light Weight & Energy Systems SGL s Contribution to E-Mobility Light Weight with Carbon Fiber Composites C- Fiber CF- Fabric C-coating Plus Plus Source: BMW Electro- Mobility graphite 10 µm Anode graphite Gas Diffusion Layer Energy Systems Li-Ion Batteries & Fuel Cells Page 4
Joint Forces for Best Solutions More than 10 Years Cooperation World Largest Anode Production & Leading Edge Technology Know How Page 5
Anode Material Requirements Success of Carbon Based Anodes Technical Requirements of a good anode material: Large reversible capacity Small irreversible capacity Safety High rate capability Compatibility with electrolyte and binders Reason of commercial success of C-based anode: LIB anode material world market size Low cost material Carbon based LTO Artificial graphite Good cycling stability (SEI, excellent reversible capacity theoretical 372 mah/g) Lightweight Electrochemical potential close to metallic Li Natural graphite Yano Research Institute, 2012 Page 6
Carbon and Graphite Based Anode Materials Overview Graphite Amorphous Carbon Natural Artificial Hard Carbon Soft Carbon Mesophase Spheroidized graphite Carbon coated graphite Si/Sn- carbon composites Other carbon based materials like carbon fibers, expanded graphite, graphene, graphite foils Page 7
First cycle efficiency (%) Typical Production Processes Raw Material Raw material Heat treatment Milling and rounding Carbon coating 100 90 Graphite (i.e. Coke) Natural Graphite 80 70 60 50 40 30 Hard Carbon (i.e. Resin) Soft Carbon (i.e. Pitch) Order and disorder XRD turbostratic disorder, amount of rhombohedral graphite,stacking faults, crystallite dimension 20 10 Raman R=I D / I G 0 180 200 220 240 260 280 300 320 340 360 380 First cycle discharge capacity (mah/g) C-rate, cycling stability, capacity Page 8
Discharge Capacity (mah/g) Typical Production Processes Heat Treatment Raw material Heat treatment Milling and rounding Carbon coating Temperature 800 C 1200 C 1400 C 2200 C 370 360 Theoretical limit Natural graphite >2400 C 350 340 Carbon 330 Amorphous Carbon 320 310 Graphite Graphite 300 78 80 82 84 86 88 90 92 94 96 98 100 Graphitization Degree (%) Graphitization degree is determined via raw material and process temperature Page 9
Lithium Storage in Amorphous Carbons Disordered Structure Amorphous Carbon Structure Intercalation or adsorption of Li + Ions soft carbon hard carbon Carbonization temperature <2500 C Only intercalation type used for real applications, typical capacities < 300 mah/g Page 10
Lithium Intercalation into Graphite Ordered Structure Crystal hexagonal graphite structure Li + intercalation into the graphite planes Basal Plane Surface Prismatic Surface Graphitization temperature >2500 C Theoretical capacity 372 mah/g Typical capacity 330-360 mah/g Page 11
Specific Capacity in mah/g Typical Production Process Milling and Rounding Raw material Heat treatment Milling and rounding Carbon coating Li + 375 Li + 325 275 225 175 125 75 Medium D 50 Value ( i.e. 20 µ m) very small D 50 value ( i.e. 10 µ m) Graphite with medium particle size Graphite with very small particle size Li + Li + 25 0 slow Log (Dis. - )/Charging Time 1 quick Particle size distribution and shape Consumer EV HEV d50 between 10 and 30 µm d90< 70 µm avoid large amount of fine particle fraction Page 12
Coulumbic Efficiency (%) Typical Production Process Carbon Coating Raw material Heat treatment Milling and rounding Carbon coating 96 95 94 93 Source: Hitachi Chemicals 92 91 Surface Area 90 BET specific surfare area and active surface area 89 0 1 2 3 4 5 Surface Area (m 2 /g) Irreversible capacity, rate capability Page 13
From Process to Properties Process Overview Materials and Tools Raw materials Coke base Pre-treatment Grinding and crushing Graphitisation process Procedure / Furnace Temp. and duration Post-treatment Grinding and crushing Morphology tailoring Chemical modification Coating Materials Properties Structure 2H/3R ratio Turbostratic disorder Lattice defects Morphology Particle shape Particle size Particle size distribution BET surface area Porosity Chemistry Surface chemistry Lattice doping Electrochemical Performance Reversible capacity Irreversible capacity Cycling stability Rate capability PC tolerance Ageing behaviour Self-Discharge Electrode Processability Safety Page 14
Anode Material for Automotive Application Comparison of Different Material Material Item Energy Life Power Safety Cost BPEV HEV Artificial graphite (MAG) Artificial Graphite (Low Cost) Natural Graphite (w/ coating) ++ + - + - - + + + + + + -- + - ++ Meso carbon - ++ ++ ++ - - Hard Carbon (Amorphous) Soft Carbon (Amorphous) - - ++ ++ ++ - - - + ++ ++ + Source Hitachi Page 15
Theoretical Cell Capacity (mah/g) Carbon-Silicon Composites 160 150 140 e.g. cathode: LiCoO 2 Need for high capacity anodes to improve the overall cell capacity 130 120 110 100 90 Kap Zelle Kap Kap Anode Anode Kap Kap Kath. Kath. Lithium Ion Batteries, N. Dimov, Saga University Silicon-Carbon Composites are promising next generation anode materials 80 0 500 1000 1500 2000 2500 3000 3500 4000 Potential vs. Li/Li + LTO Graphite Carbon Sn-M-C Composites Anode Capacity (mah/g) Sn C-Si Composites Si Highest benefit to cell capacity is for anode material up to 1000 mah/g with the actual cathodes higher than 80% carbon Li-Metal 1000 2000 3000 Capacity (mah/g) Adopted from: A. Lamm, Ausblick Batterie-und zelltechnologie Li-Ionen aus Sicht der Automobilindustrie, 26.09.2012 Page 16
Carbon-Silicon Composites Drawback of pure silicon anodes: Extreme volume expansion during lithiation/delithiation of about 300% (graphite 6-10%) leads to cracking of Si particles and electrode Poor Cycling stability Advantage of Carbon-Silicon Composite Anodes Carbon C/Si-Composites: Silicon nanoparticles within a carbon matrix Compensate the volume expansions of silicon Good electronic and ionic conductivity Nano-Si Protect the silicon from contact with the electrolyte Page 17
Summary Graphite anode accounts for over 95% of current anode market (Yano report) Carbon and Graphite properties can be tailored to meet battery requirements by adapting the raw materials and production processes Next generation anodes are most likely C-Si based. The carbonaceous material (80C / 20 Si) to guarantee overall electrode performances To get optimum cell capacity the target anode capacity is <1000 mah/g. Thus amorphous carbon will be the dominant element in composites Take away: Carbon and graphite are the anodes of today, tomorrow and the day after tomorrow! Page 18
Thank You for your Attention! www.sglcarbon.com heribert.walter@sglcarbon.de