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NANOTECHNOLOGY IN ENERGY

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Rechargeable batteries ENERGY STORAGE. Hydrogen storage. Supercapacitors. Insulation ENERGY SAVING ... Rechargeable Batteries and Supercapacitors. Use: ... – PowerPoint PPT presentation

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Title: NANOTECHNOLOGY IN ENERGY


1
  • NANOTECHNOLOGY IN ENERGY
  • Draft RoadMaps on
  • Solar Cells
  • Thermoelectricity
  • Battaries and Supercapacitors
  • Heat Insulation/Conductance
  • Ottilia Saxl
  • THE INSTITUTE OF NANOTECHNOLOGY, UK
  • Jitka Kubatova
  • TECHNOLOGY CENTRE AS CR, CR
  • __________________________________________________
    _
  • The 3rd Czech Days for European Research, Prague,
    26 October 2005

2
  • The NanoRoadMap (NRM) project,
  • co-funded by the European Commission (EC), is
    aimed at roadmapping nanotechnology related
    applications in three different areas
  • Materials
  • Health Medical Systems
  • Energy
  • This presentation is related to the Energy
    sector.
  • It is based on 4 draft roadmaps elaborated by
    Ottilia Saxl, CEO of The Institute of
    Nanotechnology (IoN), UK, and her team.
  • It also utilizes the Sectoral report on Energy
    elaborated earlier within the NRM project by Esko
    Kauppinen from VTT Technical Research Centre of
    Finland.

3
  • List of energy-related applications of
    nanotechnology
  • Solar cells ENERGY CONVERSION
  • Fuel cells
  • Thermoelectricity
  • Rechargeable batteries ENERGY STORAGE
  • Hydrogen storage
  • Supercapacitors
  • Insulation ENERGY SAVING
  • Glazing technology for insulation
  • More efficient lighting
  • Combustion
  • For details see the Sectoral report ENERGY on
    www.nanoroadmap.it

4
  • Solar cells
  • Use
  • Electricity production for homes and villages in
    remote areas without a connection to the
    electricity grid
  • Powering electronic equipment in wireless
    applications
  • Function
  • Direct transformation of light in electric energy
  • Principle
  • Creation of electron-hole pairs by absorption of
    light and their separation on barriers
  • Functional materials
  • Predominantly silicon (single-crystalline,
    poly-crystalline, amorphous, thin films)
  • Thin film copper indium diselenide (CIS),cadmium
    telluride (CdTe)

5
  • Gallium arsenide (GaAs)
  • Dye sensitised cells (DSC)
  • Main production problems
  • High efficiency materials are costly.
  • Cheap materials show low efficiency.
  • Impact of nanotechnology
  • Nanoparticles, thin films, nanostructures and
    nanoporous materials have a large ratio of the
    surface to the bulk. This property has made them
    attractive for research leading to an improvement
    of the solar cells efficiency. Research topics
  • Thin film solar cells
  • Dye sensitised silicon solar cells
  • New dyes for DSCs
  • Light absorbing nanomaterials in electrically
    conductive polymers
  • Nanostructures (quantum wells and quantum dots)
    embedded in different inorganic and organic solar
    cells
  • Silicon or germanium nanocrystals as luminescence
    convertors

6
  • Experts opinion
  • At present nanotechnology impact on solar cells
    is in the basic research phase.
  • Thin films are seen as the most promising area
    for solar cells. By 2009 first applications and
    by 2014 current applications are expected.
  • Solar cells incorporating nanocrystalline
    materials is the further technology which can
    reach commercial applications by 2014.
  • Technologies including dye-based cells, quantum
    dots, fullerenes and carbon nanotubes are not
    expected to have applications by 2014.

7
  • Thermoelectricity
  • Use
  • Thermoelectric modules (featured with no moving
    parts, small size and light in weight) have been
    widely used for cooling, heating or electric
    power generation within medical, industrial,
    consumer, laboratory, electro-optic,
    telecommunications, military etc. areas.
    Refrigerators or power generator to reuse waste
    heat are examples as well as tiny generators
    reacting on the body heat.
  • Function
  • Transformation of thermal energy into electricity
  • Transformation of electric energy into thermal
    energy (heat, cold)
  • Principle
  • A junction of two materials having different
    thermal conductivities exposed to a thermal
    gradient is a source of electric current.
  • Passing electric current through such a junction
    results in cooling or heating.

8
  • Functional materials
  • TE materials should have low thermal
    conductivity, high electrical conductivity and
    high Seebeck coefficient (in mV/K).
  • Impact of nanotechnology
  • Nanomaterials and nanostructures decrease thermal
    conductivity, increase electrical conductivity
    and improve thermo power possibility ZT. Research
    topics
  • Super lattice structures BiTe /SbTe
  • Bi nanowires
  • Bi-Te compounds
  • New materials (skutterudites, clathrates)
  • Experts opinion
  • Nanotechnology will play an important role in
    thermoelectricity applications by 2014

9
  • New materials with high ZT will be identified and
    developed by 2009 with first applications
    (energy generation from waste heat in vehicles)
    by 2014.
  • The types of new materials are expected to be
    thin films, nanocrystalline materials,
    nanoparticles, nanowires and superlattices, with
    the thin films and nanocrystalline materials
    expected to be first into application.

10
  • Rechargeable Batteries and Supercapacitors
  • Use
  • Source of electrical energy in remote areas and
    for portable electronics, computers and cameras
  • Function
  • Storage of electrical energy
  • Principle
  • Batteries store electrical energy in a chemical
    form.
  • Supercapacitors store electrical energy as the
    charge of electrons in an electrochemical double
    layer on the surface.
  • Functional materials of the commercial products
  • Batteries - lithium-ion, nickel-cadmium (NiCd),
    nickel-metal-hydride (NiMH) and Li-polymer
  • Supercapacitors carbon, metal (nickel,
    manganese, ruthenium, iridium) oxides, electron
    conducting polymers

11
  • Main production or functional problems
  • Batteries can store lots of energy but the charge
    and discharge times are long. Lifetime is short.
    Wastes contain hazardous materials.
  • Conventional capacitors can be charged and
    discharged very quickly but store little energy.
  • Supercapacitors offer combination of good
    properties of batteries and capacitors, i.e. can
    store moderately high energy and can be
    discharged moderately quickly.
  • Impact of nanotechnology
  • Nanocrystalline materials and nanotubes greatly
    improve power density, lifetime and
    charge/discharge rates in batteries.
  • Nanotubes are used to replace the normal graphite
    of lithium-graphite-electrodes.
  • A new class of materials known as aerogels made
    of 10 nm particles creates a highly porous
    structure suitable for electrodes and battery
    structures.

12
  • In supercapacitors instead of metal plates,
    porous carbon electrodes are used. The extremely
    small pores give the material very large active
    internal surface.
  • For the same reason multi-walled carbon nanotubes
    as well as nanoporous metal (iron, nickel,
    molybdenum) oxides are used.
  • Experts opinion
  • Nanotechnology is expected to play an important
    role in rechargeable batteries and
    supercapacitors as early as 2009.
  • The main RD focus is expected to be on electrode
    development with some on electrolytes.

13
  • Heat Insulation/Conductance
  • Use
  • Insulating materials keep the temperature
    constant in an enclosed space
  • Function
  • Thermal insulation provides a resistance to the
    heat flow (heat conduction, convection,
    radiation) through the insulation material.
  • Principle
  • Low thermal conductivity materials (fibre glass,
    rock wool, porous materials, air) prevent heat to
    flow through the insulating barrier.
  • Reflective surfaces and coatings reflect heat
    coming from outside or inside back.

14
  • Impact of nanotechnology
  • Particles and pores of aerogels are smaller than
    the wavelength of light. Though very expensive
    they are suitable for insulation due to their low
    conductivity, low density, high porosity, high
    surface area and high dielectric constant.
  • Glazing technology is based on large area, low
    cost, multilayer thin film coatings. Smart
    Glazing terms a glass that reacts to its
    environment by altering its transparency and
    opacity. Smart Glazing can be classified as
    thermochromic, photochromic, electrochromic or
    gasochromic according to the environmental
    impact. Nanocoatings are made of indium-tin-oxide
    , ZnO, WO3, V2O5, LiNiO2 etc.
  • Experts opinion
  • Nanoparticles and thin films are expected to play
    the main role in electrochromic (switchable)
    coatings for glazing products.
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