Difference between revisions of "Energy"

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(Nuclear power)
(Nuclear power)
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{{wp|Nuclear_fission|Nuclear fission}} (currently employed). {{wp|Nuclear_reprocessing|Nuclear reprocessing}} by the {{wp|Fast_breeder_reactor|Fast breeder reactor}} reduces the amount of waste, increases efficiency. <BR> Prospective: {{wp|Fusion_power|nuclear fusion}}, accelerator-driven thorium-fuelled {{wp|Energy_amplifier|energy amplifier}}, and {{wp|Traveling_wave_reactor|Travelling wave reactor}}
 
{{wp|Nuclear_fission|Nuclear fission}} (currently employed). {{wp|Nuclear_reprocessing|Nuclear reprocessing}} by the {{wp|Fast_breeder_reactor|Fast breeder reactor}} reduces the amount of waste, increases efficiency. <BR> Prospective: {{wp|Fusion_power|nuclear fusion}}, accelerator-driven thorium-fuelled {{wp|Energy_amplifier|energy amplifier}}, and {{wp|Traveling_wave_reactor|Travelling wave reactor}}
  
Question of waste disposal. 1GW of nuclear generates only a modest 20 tons of waste, but this waster is dangerous.  
+
Question of waste disposal. 1GW of nuclear generates only a modest 20 tons of waste. So if all our energy came from nuclear fission, we'd have 300,000 tons of waste (very dense, occupying a relatively small volume). However, this waste is dangerous.  
  
 
Decommissioned warheads can be used as fuel.
 
Decommissioned warheads can be used as fuel.

Revision as of 05:28, 2 July 2010

The sun (image from SOHO spacecraft)

The human race currently requires 15 terawatts of energy[1]. This is a laughably tiny amount of energy compared to what is available around us: 72 terawatts of available wind energy at ground level[2], 150 terawatts in the jet streams[3], 44.2 terawatts of geothermal energy [4], 2 terawatts of easily-exploitable wave power[5] and 174,000 terawatts of solar energy[6]. We clearly have tens of thousands of times the energy we need, the key is our ability to harness this energy. This article explores existing and emerging technologies for doing this.

The energy available from solar and geothermal alone far exceed our current and likely future energy requirements and could sustain humanity indefinitely. The amount of energy that falls on the earth from the sun in a minute is what humans currently use in a year across all nations and industries.

Steadily increasing energy efficiency 11px-Wikipedia_logo.jpg due to improved system design and increasing cultural awareness should become a significant factor in our energy usage.

The issue currently is commercial economics. The bottom line is that with the current economic framework it is still 'cheaper' to pump oil out of the ground and burn it to produce power than use other more plentiful, renewable and environmentally benign sources. These alternative energy sources are sitting right in front of us waiting to be harnessed. It may be that open-source methods can by-pass the incumbent economic system to enable plentiful, environmentally-friendly power.

A word on decentralization: some scenarios imagine our renewable electricity in the future coming from giant solar farms, wind farms and other renewable sources. However, for such farms to meet our needs, they have to cover an area the size of the USA ref. This is simply not feasible and would require bulldozing large areas of wilderness. However, solar, wind and geothermal energy can be very effective at a small scale. Each building, or group of buildings, can generate its own electricity on-site by putting solar panels on the roof, third-generation photovoltaics embedded in windows [7], a wind turbine or small geothermal generators. It is likely that our electricity in the future will mostly come from such decentralized sources, supplemented by the occasional larger energy-farm, such as a wave power generator next to a coastal city.

We have these major sources of energy available to us, in no particular order and not including fossil fuels that we currently rely on for the majority of our energy today:

Generating energy

Solar

Because the amount of energy falling on the Earth from the Sun is ridiculously abundant, it is likely that solar power will form the bulk of our energy in a post-scarcity society, with the other sources mentioned here supplementing it. Ray Kurzweil has said [8], "If we could convert .03% of the sunlight that falls on the Earth into energy we could meet all of our projected needs for 2030" and he has predicted that solar power will meet all our needs by 2026 [9]
Solar two cropped.jpg


If most buildings covered their roofs with solar panels, using currently available technology, we could meet nearly all of our energy requirements without the need for supplementary forms of energy or centralized energy farms. It is also possible to create solar cells that are integrated into ordinary-looking windows (see Ubiquitous PV)

However, things are getting even better: solar technology is becoming cheaper, more efficient and more accessible. Modern off-the-shelf solar panels convert about 15% or 20% of the light to electricity, but there are prototypes that convert as much as 43%. When these become mainstream, solar power will be a very attractive option. Using nanotechnology, it is theoretically possible to create solar panels with an efficiency of 60.3%[10]

[1] 11px-Wikipedia_logo.jpg photovoltaics 11px-Wikipedia_logo.jpg, solar thermal 11px-Wikipedia_logo.jpg (such as power tower & [11], ocean thermal energy conversion 11px-Wikipedia_logo.jpg, SHPEGS and solar updraft tower 11px-Wikipedia_logo.jpg). Prospective: Space solar power 11px-Wikipedia_logo.jpg including solar power satellite 11px-Wikipedia_logo.jpg, ubiquitous PV and stratospheric solar array

  • Dye-sensitized cells
  • Thin-layer photovoltaics
  • Ubiquitous PV
  • Nanocrystals

Wind

Wind power lends itself easily to decentralization: turbines can be put on top of any building, taking up zero extra space. By putting the turbines on a tall pole, they reach the faster winds available higher up. Large-scale wind farms also take up very little space, as the diameter of the pole is the only bit that takes up land; the business-end of the machinery is up out of the way and the land in between wind turbines can be used for agriculture or any other purpose.

One technology we may see in the near-future is flying wind turbines that exploit the reliable, high-speed winds of the stratospheric jet-streams.

Ocean

wave, tidal, ocean currents

The waves bobbing up and down endlessly are a source of practically infinite energy. While engineers have looked for a way to harness this energy to make electricity for decades, the first commercially viable wave farm was opened in 2008[12].

New slow water current energy technology allows us to turn the turbulence in little eddies and ripples of water into electricity. Ideal for small-scale generation from rivers and streams.

Hydro-electric

Nuclear power

Nuclear fission 11px-Wikipedia_logo.jpg (currently employed). Nuclear reprocessing 11px-Wikipedia_logo.jpg by the Fast breeder reactor 11px-Wikipedia_logo.jpg reduces the amount of waste, increases efficiency.
Prospective: nuclear fusion 11px-Wikipedia_logo.jpg, accelerator-driven thorium-fuelled energy amplifier 11px-Wikipedia_logo.jpg, and Travelling wave reactor 11px-Wikipedia_logo.jpg

Question of waste disposal. 1GW of nuclear generates only a modest 20 tons of waste. So if all our energy came from nuclear fission, we'd have 300,000 tons of waste (very dense, occupying a relatively small volume). However, this waste is dangerous.

Decommissioned warheads can be used as fuel.

Geothermal

shallow geothermal heat pumps 11px-Wikipedia_logo.jpg, volcanic related geothermal and deep geothermal - Enhanced geothermal systems 11px-Wikipedia_logo.jpg (EGS). See also Future of Geothermal Power (in the US) published by MIT 11px-Wikipedia_logo.jpg and Google's funding of enhanced geothermal [13]. Small-scale thermal (not electric) geothermal heat pumps are a great way to heat houses year-round in cold places.


Biomass (carbon-neutral)

biofuel (algae), compost methane, fermented crop waste, algae, sustainable wood, and clean burning of: organic waste, animal dung and rubbish

Bacteria

Certain species of bacteria (such as geobacter) deposit electrons onto electrodes placed in their environment. Much work is still being done on optimizing the systems, but microbial fuel cells already provide a cheap and very resilient form of energy. A $40 system developed by Dr. Peter Girguis and Dr. Helen White has shown itself capable of producing 96W of power[14]. This system used inexpensive charcoal electrodes and can run for years and years without maintenance. Since then, a new strain of geobacter bacteria has been developed that has a power output eight times greater than previously known strains[15].

Microbial fuel cells can be synergized 11px-Wikipedia_logo.jpg with composting toilets to create a system that disposes of human waste, fertilizes plants for food and also generates electricity.

Recapturing waste energy

Just like there are untapped reserves of money in the back of your couch, there are untapped reserves of energy in the ambient surroundings. Though not normally discussed by renewable energy afficionados, the random wasted energy that is floating around us as motion and heat can be considered a form of clean, renewable energy. Devices to capture this energy can be fitted to anything from a car to a computer.
Trochoidal gear engine technology can be attached to machines such as factory robots to recapture the heat they generate and turn it back into useful energy [16].
Piezoelectric crystals are crystals that generate electricity when shaken or squeezed. They have been used to recapture kinetic energy from the air flowing around a car [17] and in the suspension systems of cars.
Kinetic generators such as the nPower PEG generate electricity whenever they are moved. Even just keeping one in your pocket while walking provides clean energy. What if devices like this were routinely fitted to our vehicles?
Regenerative braking is now a standard feature in electric cars. Whenever you use the brakes of your car, you are taking away its kinetic energy. This is normally wasted, but with regenerative braking, is recaptured and used later. This can provide 10% of the car's energy needs.

Storing energy

Batteries

Capacitors

Nanoengineering is enabling more and more efficient capacitors

Fuel cells

Hydrogen economy

Using energy

As our technology advances, it is becoming more and more energy-efficient. According to Wikipedia's article on efficient energy use 11px-Wikipedia_logo.jpg, "up to 75% of the electricity used in the U.S. today could be saved with efficiency measures that cost less than the electricity itself". When considering the energy needs of a post-scarcity world, it is important to recognize that most of the things people want to do - heat a building, wash clothes, light their homes - can be achieved with a fraction of the energy we currently use: LEDs are rapidly replacing fluorescent and incandescent bulbs as a light-source and can provide the same illumination with a quarter the energy, better-designed cars with lighter materials can greatly reduce energy consumption for transport, and for every appliance from refrigerators to dishwashers to ovens, there are design tricks that can produce the same functionality while greatly reducing energy consumption.

In many environments, the need for using energy to heat or cool buildings can be reduced to zero by use of proper insulation and architectural design. A remarkable example of this is Persian windcatchers, which cool buildings by trapping cool winds while at the same time allowing hot air to rise out of the building. In the city of Yazd, these are used to freeze ice in the middle of the desert.

Post-scarcity of energy will arise when we have both halves of the equation: abundant production of energy, and non-wasteful use of it.