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Nanotechnology for Future Batteries

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Presentation on theme: "Nanotechnology for Future Batteries"— Presentation transcript:

1 Nanotechnology for Future Batteries
Yaroslav Aulin

2 Outline Introduction Li-ion batteries and nanotechnology
Other nanobatteries Conclusions "Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009

3 How do batteries work? - anode (-) cathode (+) electrolyte + current
© 2009 Yaroslav Aulin "Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009

4 Parameters to be improved
Stored energy per mass(volume) Power Recharge time Lifetime Cost Safety Environmental sustainability J.Thomas, Nature Materials 2, (2003) "Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009

5 Moore’s law-not for batteries
Image courtesy: Intel Corporation 18650 Li ion cell "Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009

6 … Batteries’ timeline now 5..10 years from now
M. Armand & J.-M. Tarascon, Nature 451, (2008)  "Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009

7 Li-ion batteries "Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009

8 Conventional Li-ion batteries
Anode: graphite Cathode: LiCoO2 electrolyte: a solution of LiPF6 in EC-DMC LiCoO2 Graphite "Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009

9 Problems Graphite – low specific capacity for Li storage
LiCoO2-high cost Liquid electrolyte Solution: nanomaterials "Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009

10 Anode "Energy & Nano" - Top Master in Nanoscience Symposium
17 June 2009

11 Anode Unlithiated material Fully lithiated material
Gravimetric capacity (mAhg-1) Volumetric capacity (mAhcc-1) Al LiAl 993 1.374 Si Li21Si5 4008 2.323 Sn Li22Sn5 994 2.025 Sb Li3Sb 660 1.881 C, graphite LiC6 372 0.760 Gravimetric (volumetric) capacity- charge that could be stored per unit mass(volume) of the material "Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009

12 Anode Si High gravimetric capacity
Problem: the volume of Si changes by 400% upon cycling Solution: nanostructured electrodes "Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009

13 Anode Schematic of morphological change that occur in Si during electrochemical cycling C.K. Chan et. al. Nature Nanotechnology 3, (2008) "Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009

14 Anode Structural evolution of Si NWs during lithiation
graphite Capacity vs cycle number data for Si NW electrode compared to graphite C.K. Chan et. al. Nature Nanotechnology 3, (2008) "Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009

15 Cathode "Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009

16 Cathode Problems: insulator, low Li ion diffusion
LiFePO4 Cheap, environmentally benign, reasonable capacity(110 mAhg-1 versus 130 mAhg-1 for LiCoO2) Problems: insulator, low Li ion diffusion M. Armand & J.-M. Tarascon, Nature 414, (2001)  Solution: carbon-coated nanoparticles "Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009

17 Cathode Cycling behavior and SEM image of carbon coated nanoparticulate LiFePO4 electrode C.Z. Lu et al. Journal of Power Sources 189 (2009) "Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009

18 Cathode Sample Thickness of pellet (mm) Resistance (kΩ)
Conductivity (S cm−1) LFP (0 wt.% HC) 1.06 3.97 × 10−8 LFP (6.0 wt.% HC) 0.77 8.32 3.45 × 10−4 LFP (8.0 wt.% HC) 0.88 6.78 3.70 × 10−4 LFP (10 wt.% HC) 0.55 8.67 4.63 × 10−4 LFP (12 wt.% HC) 0.63 6.95 5.04 × 10−4 C.Z. Lu et al. Journal of Power Sources 189 (2009) "Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009

19 Electrolyte "Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009

20 Solid state polymer electrolytes
All solid state construction Simplicity of manufacture Wide variety of shapes and sizes Higher energy density No leak-outs and internal short-circuits Problem: poor ionic conductivity Solution: nanocomposite polymer electrolytes "Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009

21 Solid state polymer electrolytes
S. Panero et al. Journal of Power Sources 129 (2004) Influence of ZrO2 nanoparticles on ionic conductivity of P(EO)20LiCF3SO3 "Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009

22 Solid state polymer electrolytes
Problems remaining: better understanding of ionic conductivity of polymers is required electrode-electrolyte interface "Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009

23 "Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009

24 … http://www.sandia.gov/ M. Armand & J.-M. Tarascon,
Nature 451, (2008) "Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009

25 Conclusions Progress in nanoscience and nanotechnology will allow to design new types of batteries based on nanomaterials and having improved properties: increased capacity, improved charge-discharge characteristics, reduced power cost, lower weight and smaller size, better environmental sustainability Nanostructured electrodes and solid polymer electrolytes are the materials that will drastically improve conventional Li-ion batteries "Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009

26 Acknowledgements I would like to thank prof. Paul van Loosdrecht for supervising me during this project "Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009

27 Thank you for your attention! Questions?
"Energy & Nano" - Top Master in Nanoscience Symposium 17 June 2009

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