Micropower

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Micropower describes the use of very small electric generators and prime movers or devices to convert heat or motion to electricity, for use close to the generator. [1] The generator is typically integrated with microelectronic devices and produces "several watts of power or less." [2] These devices offer the promise of a power source for portable electronic devices which is lighter weight and has a longer operating time than batteries.

Contents

Microturbine technology

The components of any turbine engine — the gas compressor, the combustion chamber, and the turbine rotor — are fabricated from etched silicon, much like integrated circuits. The technology holds the promise of ten times the operating time of a battery of the same weight as the micropower unit, and similar efficiency to large utility gas turbines. Researchers at Massachusetts Institute of Technology have thus far succeeded in fabricating the parts for such a micro turbine out of six etched and stacked silicon wafers, and are working toward combining them into a functioning engine about the size of a U.S. quarter coin. [3]

Researchers at Georgia Tech have built a micro generator 10 mm wide, which spins a magnet above an array of coils fabricated on a silicon chip. The device spins at 100,000 revolutions per minute, and produces 1.1 watts of electrical power, sufficient to operate a cell phone. Their goal is to produce 20 to 50 watts, sufficient to power a laptop computer. [4]

Scientists at Lehigh University are developing a hydrogen generator on a silicon chip that can convert methanol, diesel, or gasoline into fuel for a microengine or a miniature fuel cell. [5]

Professor Sanjeev Mukerjee of Northeastern University's chemistry department is developing fuel cells for the military that will burn hydrogen to power portable electronic equipment, such as night vision goggles, computers, and communication equipment. In his system, a cartridge of methanol would be used to produce hydrogen to run a small fuel cell for up to 5,000 hours. It would be lighter than rechargeable batteries needed to provide the same power output, with a longer run time. Similar technology could be improved and expanded in future years to power automobiles. [6]

The National Academies' National Research Council recommended in a 2004 report that the U.S. Army should investigate such micropower sources for powering electronic equipment to be carried by soldiers in the future, since batteries sufficient to power the computers, sensors, and communications devices would add considerable weight to the burden of infantry soldiers. [7]

The Future Warrior Concept of the U.S. Army envisions a 2- to 20-watt micro turbine fueled by a liquid hydrocarbon being used to power communications and wearable heating/cooling equipment for up to six days on 10 ounces of fuel. [8]

Other microgenerator/nanogenerator technologies

Professor Orest Symko of the University of Utah physics department and his students developed Thermal Acoustic Piezo Energy Conversion (TAPEC), devices of a cubic inch (16 cubic centimeters), or so, which convert waste heat into acoustic resonance and then into electricity. It would be used to power microelectromechanical systems, or MEMS. The research was funded by the U.S. Army. Symko was to present a paper at the Acoustical Society of America. [9] June 8, 2007. Researchers at MIT developed the first micro-scale piezoelectric energy harvester using thin film PZT in 2005. [10] Arman Hajati and Sang-Gook Kim invented the Ultra Wide-Bandwidth micro-scale piezoelectric energy harvesting device by exploiting the nonlinear stiffness of a doubly clamped microelectromechanical systems (MEMS) resonator. The stretching strain in a doubly clamped beam shows a nonlinear stiffness, which provides a passive feedback and results in amplitude-stiffened Duffing mode resonance. [11]

Professor Zhong Lin Wang of the Georgia Institute of Technology said his team of investigators had developed a "nanometer-scale generator ... based on arrays of vertically aligned zinc oxide nanowires that move inside a "zigzag" plate electrode." Built into shoes, it could generate electricity from walking to power small electronic devices. It could also be powered by blood flow to power biomedical devices. [12] Per an account of the device which appeared in the journal Science, bending of the zinc oxide nanowire arrays produces an electric field by the piezoelectric properties of the material. The semiconductor properties of the device create a Schottky barrier with rectifying capabilities. The generator is estimated to be 17% to 30% efficient in converting mechanical motion into electricity. This could be used to power biomedical devices that have wireless transmission capabilities for data and control. [13] A later development was to grow hundreds of such nanowires on a substrate that functioned as an electrode. On top of this was placed a silicon electrode covered with a series of platinum ridges. Vibration of the top electrode caused the generation of direct current. [14] A report by Wang was to appear in the August 8, 2007 issue of the journal "Nano Letters," saying that such devices could power implantable biomedical devices. The device would be powered by flowing blood or a beating heart. It could function while immersed in body fluids, and would get its energy from ultrasonic vibrations. [15] Wang expects that an array of the devices could produce 4 watts per cubic centimeter. [16] Goals for further development are to increase the efficiency of the array of nanowires, and to increase the lifetime of the device, which as of April 2007 was only about one hour. [17] By November 2010 Wang and his team were able to produce 3 volts of potential and as much as 300 nanoamperes of current, an output level 100 times greater than was possible a year earlier, from an array measuring about 2 cm by 1.5 cm. [18]

The windbelt is a micropower technology invented by Shawn Frayne. It is essentially an aeolian harp, except that it exploits the motion of the string produced by aeroelastic flutter to create a physical oscillation that can be converted to electricity. It avoids the losses inherent in rotating wind powered generators. Prototypes have produced 40 milliwatts in a 16 km/h wind. Magnets on the vibrating membrane generate currents in stationary coils. [19] [20]

Piezoelectric nanofibers in clothing could generate enough electricity from the wearer's body movements to power small electronic devices, such as iPods or some of the electronic equipment used by soldiers on the battlefield, based on research by University of California, Berkeley Professor Liwei Lin and his team. One million such fibers could power an iPod, and would be altogether as large as a grain of sand. Researchers at Stanford University are developing "eTextiles" — batteries made of fabric — that might serve to store power generated by such technology. [21]

Thermal resonator technology allows generation of power from the daily change of temperature, even when there is no instantaneous temperature difference as needed for thermoelectric generation, and no sunlight as needed for photovoltaic generation. A phase change material such as octadecane is selected which can change from solid to liquid when the ambient temperature changes a few degrees celsius. In a small demonstration device created by chemical engineering professor Michael Strano and seven others at MIT, a 10 degree celsius daily change produced 350 millivolts and 1.3 milliwatts. The power levels envisioned could power sensors and communication devices. [22] [23]

See also

Related Research Articles

<span class="mw-page-title-main">Electricity generation</span> Process of generating electrical power

Electricity generation is the process of generating electric power from sources of primary energy. For utilities in the electric power industry, it is the stage prior to its delivery to end users or its storage.

<span class="mw-page-title-main">Electrochemical cell</span> Electro-chemical device

An electrochemical cell is a device capable of either generating electrical energy from chemical reactions or using electrical energy to cause chemical reactions. The electrochemical cells which generate an electric current are called voltaic or galvanic cells and those that generate chemical reactions, via electrolysis for example, are called electrolytic cells. A common example of a galvanic cell is a standard 1.5 volt cell meant for consumer use. A battery consists of one or more cells, connected in parallel, series or series-and-parallel pattern.

<span class="mw-page-title-main">Fuel cell</span> Device that converts the chemical energy from a fuel into electricity

A fuel cell is the electrochemical cell that converts the chemical energy of a fuel and an oxidizing agent into electricity through a pair of redox reactions. Fuel cells are different from most batteries in requiring a continuous source of fuel and oxygen to sustain the chemical reaction, whereas in a battery the chemical energy usually comes from substances that are already present in the battery. Fuel cells can produce electricity continuously for as long as fuel and oxygen are supplied.

Energy harvesting is the process by which energy is derived from external sources, and then stored for use by small, wireless autonomous devices, like those used in wearable electronics, condition monitoring, and wireless sensor networks.

An atomic battery, nuclear battery, radioisotope battery or radioisotope generator is a device which uses energy from the decay of a radioactive isotope to generate electricity. Like nuclear reactors, they generate electricity from nuclear energy, but differ in that they do not use a chain reaction. Although commonly called batteries, they are technically not electrochemical and cannot be charged or recharged. They are very costly, but have an extremely long life and high energy density, and so they are typically used as power sources for equipment that must operate unattended for long periods of time, such as spacecraft, pacemakers, underwater systems and automated scientific stations in remote parts of the world.

<span class="mw-page-title-main">Grid energy storage</span> Large scale electricity supply management

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<span class="mw-page-title-main">Electronic component</span> Discrete device in an electronic system

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<span class="mw-page-title-main">Dye-sensitized solar cell</span> Type of thin-film solar cell

A dye-sensitized solar cell is a low-cost solar cell belonging to the group of thin film solar cells. It is based on a semiconductor formed between a photo-sensitized anode and an electrolyte, a photoelectrochemical system. The modern version of a dye solar cell, also known as the Grätzel cell, was originally co-invented in 1988 by Brian O'Regan and Michael Grätzel at UC Berkeley and this work was later developed by the aforementioned scientists at the École Polytechnique Fédérale de Lausanne (EPFL) until the publication of the first high efficiency DSSC in 1991. Michael Grätzel has been awarded the 2010 Millennium Technology Prize for this invention.

Thermophotovoltaic (TPV) energy conversion is a direct conversion process from heat to electricity via photons. A basic thermophotovoltaic system consists of a hot object emitting thermal radiation and a photovoltaic cell similar to a solar cell but tuned to the spectrum being admitted from the hot object.

<span class="mw-page-title-main">Microgeneration</span> Small-scale heating and electric power creation

Microgeneration is the small-scale production of heat or electric power from a "low carbon source," as an alternative or supplement to traditional centralized grid-connected power.

Nanoelectronics refers to the use of nanotechnology in electronic components. The term covers a diverse set of devices and materials, with the common characteristic that they are so small that inter-atomic interactions and quantum mechanical properties need to be studied extensively. Some of these candidates include: hybrid molecular/semiconductor electronics, one-dimensional nanotubes/nanowires or advanced molecular electronics.

A nanowire battery uses nanowires to increase the surface area of one or both of its electrodes, which improves the capacity of the battery. Some designs, variations of the lithium-ion battery have been announced, although none are commercially available. All of the concepts replace the traditional graphite anode and could improve battery performance. Each type of nanowire battery has specific advantages and disadvantages, but a challenge common to all of them is their fragility.

<span class="mw-page-title-main">Ultrasonic nozzle</span>

Ultrasonic nozzles are a type of spray nozzle that use high frequency vibrations produced by piezoelectric transducers acting upon the nozzle tip that create capillary waves in a liquid film. Once the amplitude of the capillary waves reaches a critical height, they become too tall to support themselves and tiny droplets fall off the tip of each wave resulting in atomization.

Nanoball batteries are an experimental type of battery with either the cathode or anode made of nanosized balls that can be composed of various materials such as carbon and lithium iron phosphate. Batteries which use nanotechnology are more capable than regular batteries because of the vastly improved surface area which allows for greater electrical performance, such as fast charging and discharging.

A Nanogenerator is a type of technology that converts mechanical/thermal energy as produced by small-scale physical change into electricity. A Nanogenerator has three typical approaches: piezoelectric, triboelectric, and pyroelectric nanogenerators. Both the piezoelectric and triboelectric nanogenerators can convert mechanical energy into electricity. However, pyroelectric nanogenerators can be used to harvest thermal energy from a time-dependent temperature fluctuation.

Piezotronics effect is using the piezoelectric potential (piezopotential) created in materials with piezoelectricity as a “gate” voltage to tune/control the charge carrier transport properties for fabricating new devices. Neil A Downie showed how simple it was to build simple demonstrations on a macro-scale using a sandwich of piezoelectric material and carbon piezoresistive material to make an FET-like amplifying device and put it in a book of science projects for students in 2006. The fundamental principle of piezotronics was introduced by Prof. Zhong Lin Wang at Georgia Institute of Technology in 2007. A series of electronic devices have been demonstrated based on this effect, including piezopotential gated field-effect transistor, piezopotential gated diode, strain sensors, force/flow sensors, hybrid field-effect transistor, piezotronic logic gates, electromechanical memories, etc. Piezotronic devices are regarded as a new semiconductor-device category. Piezotronics is likely to have important applications in sensor, human-silicon technology interfacing, MEMS, nanorobotics and active flexible electronics.

This article provides information on the following six methods of producing electric power.

  1. Friction: Energy produced by rubbing two material together.
  2. Heat: Energy produced by heating the junction where two unlike metals are joined.
  3. Light: Energy produced by light being absorbed by photoelectric cells, or solar power.
  4. Chemical: Energy produced by chemical reaction in a voltaic cell, such as an electric battery]].
  5. Pressure: Energy produced by compressing or decompressing specific crystals.
  6. Magnetism: Energy produced in a conductor that cuts or is cut by magnetic lines of force.

Silicon nanowires, also referred to as SiNWs, are a type of semiconductor nanowire most often formed from a silicon precursor by etching of a solid or through catalyzed growth from a vapor or liquid phase. Such nanowires have promising applications in lithium ion batteries, thermoelectrics and sensors. Initial synthesis of SiNWs is often accompanied by thermal oxidation steps to yield structures of accurately tailored size and morphology.

<span class="mw-page-title-main">Zhong Lin Wang</span> Physicist

Zhong Lin Wang is a Chinese-American physicist, materials scientist and engineer specialized in nanotechnology, energy science and electronics. He received his PhD from Arizona State University in 1987. He is the Hightower Chair in Materials Science and Engineering and Regents' Professor at the Georgia Institute of Technology, USA.

References

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  8. "Future Warrior Concept". Archived from the original on 2012-07-25. Retrieved 2012-06-05. U.S. Armay Natick Soldier Research, "Future Warrior Concept." retrieved June 20, 2007
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  11. Ultra-wide bandwidth piezoelectric energy harvesting Archived 2016-05-15 at the Portuguese Web Archive
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  13. Wang, Zhong Lin; Song, Jinhui (2006). "Piezoelectric nanogenerators based on zinc oxide nanowire arrays" (PDF). Science . 312 (5771): 242–246. Bibcode:2006Sci...312..242W. doi:10.1126/science.1124005. PMID   16614215. S2CID   4810693.
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  15. Atlanta, Georgia, July 19, 2007. From a (UPI) story. retrieved July 25, 2007
  16. Toon, John "Nanogenerator Provides Continuous Electrical Power. Device harvests energy from the environment to provide direct current." Press release, Georgia Institute of Technology, April 5, 2007. retrieved July 25, 2007
  17. "Nanogenerator Fueled by Vibrations. An array of zinc-oxide nanowires that generates current when vibrated with ultrasonic waves could provide a new way to power biological sensors and nanodevices." Technology Review. MIT. April 05, 2007. retrieved July 25, 2007
  18. "Nanogenerators grow strong enough to power small conventional electronic devices." ScienceDaily. Retrieved November 10, 2010, from https://www.sciencedaily.com/releases/2010/11/101108151416.htm
  19. "Windbelt - Third World Power - Wind Generator - Video - Breakthrough Awards - Popular Mechanics". Archived from the original on 2008-04-04. Retrieved 2008-06-18. Ward, Logan "Windbelt, Cheap Generator Alternative, Set to Power Third World; 2007 Breakthrough Awards; The Innovators: Shawn Frayne" Popular Mechanics, November 2007. Retrieved 18 June 2008.
  20. The Windbelt Technology Archived 2007-10-21 at the Wayback Machine
  21. Hsu, Tiffany,"One day your pants may power up your iPod." Los Angeles Times, reprinted in the Chicago Tribune, May 20, 2010. Retrieved May 20, 2010
  22. "System draws power from daily temperature swings,"Massachusetts Institute of Technology, ScienceDaily, 15 February 2018.
  23. Anton L. Cottrill, Albert Tianxiang Liu, Yuichiro Kunai, Volodymyr B. Koman, Amir Kaplan, Sayalee G. Mahajan, Pingwei Liu, Aubrey R. Toland, Michael S. Strano." Ultra-high thermal effusivity materials for resonant ambient thermal energy harvesting." Nature Communications, 2018; 9 (1) DOI: 10.1038/s41467-018-03029-x
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