The Market for Thin Film Batteries is Expected for Be Worth $11 Billion Dollars by 2012.DUBLIN, Ireland -- Research and Markets (http://www.researchandmarkets.com/reports/c33555) has announced the addition of Nanotechnology and Thin Film Nicad Battery Market Opportunities, Strategies, and Forecasts, 2006 To 2012 to their offering. There is a $50B battery market worldwide in 2005. Within that market is a place for evolution of next generation devices; of which include thin film NiCad batteries. These technologies depend on the further evolution of nanotechnology. Thin film batteries (TFB TFB Texas Farm Bureau TFB Total Fire Ban (Australia) TFB Time for Bed TFB Tactile Feedback TFB Two for Breakfast (hospitality industry) TFB Trust Fund Brat TFB Tethered Float Breakwater ) are positioned to become the next generation of lithium batteries for portable electronic applications. Research has showed the chemistry of turning the hazardous liquid lithium ion A rechargeable battery technology introduced in 1991 that provides greater charge per pound than nickel metal hydride. In 1993, Toshiba introduced the first notebook in the U.S. with a Li-ion battery. into a solid, creating the ability to use lithium ion as an ink or particle that in not hazardous. Results obtained in the laboratory are being translated into commercial products. Thin film solid-state batteries are because the lithium ion that is implemented as a liquid electrolyte electrolyte (ĭlĕk`trəlīt'), electrical conductor in which current is carried by ions rather than by free electrons (as in a metal). in traditional batteries is replaced with a solid form of the chemical. Thin film solid-state batteries are constructed by depositing the components of the battery as thin films (less than 5um) on a substrate. The typical structure of a thin film solid-state battery can be illustrated in a schematic cross section. A sputtered LiPON electrolyte film covers the cathode and a portion of the substrate up to the anode anode (ăn`ōd), electrode through which current enters an electric device. In electrolysis, it is the positive electrode in the electrolytic cell. anode Terminal or electrode from which electrons leave a system. current collector in order to insulate in·su·late tr.v. in·su·lat·ed, in·su·lat·ing, in·su·lates 1. To cause to be in a detached or isolated position. See Synonyms at isolate. 2. the substrate from direct contact with the anode. For a thin film lithium battery, a thin layer of lithium metal is thermally evaporated evaporated reduced in volume by evaporation; concentrated to a denser form. on LiPON as the anode. For a thin film lithium ion battery, a thin layer of Sn3N4 (deposited by sputtering A popular method for adhering thin films onto a substrate. Sputtering is done by bombarding a target material with a charged gas (typically argon) which releases atoms in the target that coats the nearby substrate. It all takes place inside a magnetron vacuum chamber under low pressure. of Sn target in N2 environment) is used as the anode. Finally, the battery is sealed. Next-generation, ultra-thin rechargeable batteries are for card-type applications. Nano energy devices are thinner than a piece of paper. When embedded in micro devices it acts as an autonomous power source, enabling new functions. Micro battery devices support the development of next generation self-powered micro systems. A battery is one of two kinds of electrochemical electrochemical /elec·tro·chem·i·cal/ (-kem´i-k'l) pertaining to interaction or interconversion of chemical and electrical energies. e·lec·tro·chem·i·cal adj. devices that convert the energy released in a chemical reaction directly into electrical energy. In a battery, the reactants are stored close together within the battery itself. In a fuel cell the reactants are stored externally. Both thin film batteries and micro fuel cells promise to further evolve during the forecast period. This conversion of chemical energy to electrical energy is potentially 100% efficient, whereas the conversion of chemical energy to mechanical energy via a thermal conversion (e.g., internal combustion of gasoline in cars) always results in heat transfer losses limiting the intrinsic efficiency. The effective surface area of an electrode electrode, terminal through which electric current passes between metallic and nonmetallic parts of an electric circuit. In most familiar circuits current is carried by metallic conductors, but in some circuits the current passes for some distance through a can be increased without increasing its physical size by making its surface porous and using materials with very fine particle size Particle size, also called grain size, refers to the diameter of individual grains of sediment, or the lithified particles in clastic rocks. The term may also be applied to other granular materials. . This can increase the effective surface area of the electrodes Electrodes Tiny wires in adhesive pads that are applied to the body for ECG measurement. Mentioned in: Electrocardiography by 1000 to 100,000 times enabling higher current rates to be achieved. In this manner, nanotechnology holds enormous promise for this market. Nanoparticles can be developed that are used to make a surface very porous and increase the effective surface area of the electrodes. High capacity cells require large volumes of electrolyte that must be accommodated between the electrodes. This has a double effect in reducing the cell power handling capability. The electrodes must be smaller and further apart to make space for the extra electrolyte and hence they can carry less current. Increased volume of the electrolyte means it takes longer for the chemical actions associated with charging and discharging to propagate prop·a·gate v. 1. To cause an organism to multiply or breed. 2. To breed offspring. 3. To transmit characteristics from one generation to another. 4. completely through the electrolyte to complete the chemical conversion process. Thin film battery markets in the trial stage in 2005 are anticipated to reach 10 billion units, $11 billion dollars by 2012. The market driving forces are those of wide expansion of portable devices in that time frame. Market development depends on volume capacity. High volume makes the price per unit less to manufacture. With 3.5 billion cell phone users and 67 billion RFID tags per year anticipated in that time frame, it is anticipated that the volumes will be in place to create commercial demand for thin film batteries. Key Topics --THIN FILM BATTERY MARKET SHARES --THIN FILM BATTERY MARKET FORECASTS --Thin Film Battery Market Positioning --Impact Of Nanotechnology --Thin Film Battery For Cell Phones --Thin Film Solid-State Battery Construction --THIN FILM BATTERY FOR SMART CARDS Example of widely used contactless smart cards are Hong Kong's Octopus card, Paris' Calypso/Navigo card and Lisbon' LisboaViva card, which predate the ISO/IEC 14443 standard. The following tables list smart cards used for public transportation and other electronic purse applications. --BATTERY DEPENDS ON CHEMICAL ENERGY --THIN FILM BATTERY FOR PORTABLE PC'S --SMART ACTIVE LABELS --THIN FILM BATTERY FOR IMPLANTABLE MEDICAL DEVICES --BATTERY-ASSISTED TAGS --THIN FILM BATTERY FOR RFID TAGS --CELL CONSTRUCTION --NAMING STANDARDS FOR CELL IDENTIFICATION --POLYMER FILM SUBSTRATE Companies Mentioned --Energizer Holding Excellatron --Infinite Power Solutions ITN ITN n abbr (Brit) (= Independent Television News) → chaîne de télévision commerciale ITN (Brit) n abbr (TV) (= Independent Television News) → Energy Systems --Johnson Research Thin Folm Battery Products --KSW Microtec --Mpower Solutions Procter & Gamble Company --Ultralife Batteries VoltaLife Corporation --Excellatron --ITN Energy Systems --KSW Microtec --Procter & Gamble Company --VoltaLife Corporation For more information visit http://www.researchandmarkets.com/reports/c33555 |
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