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==Lead section==
==Lead section==
===Ist Proposal by Apteva===
===Original===
(September 2008)

'''Solar energy''' refers to the utilization of the [[radiant energy]] from the [[Sun]]. '''Solar power''' is used interchangeably with solar energy, but refers more specifically to the conversion of sunlight into [[electricity]] by [[photovoltaics]], concentrating solar thermal devices, or by an experimental technology such as a [[solar chimney]] or [[solar pond]].
'''Solar energy''' refers to the utilization of the [[radiant energy]] from the [[Sun]]. '''Solar power''' is used interchangeably with solar energy, but refers more specifically to the conversion of sunlight into [[electricity]] by [[photovoltaics]], concentrating solar thermal devices, or by an experimental technology such as a [[solar chimney]] or [[solar pond]].


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Solar [[distillation]] and [[disinfection]] techniques produce [[potable water]] for millions of people worldwide. Simple applications include [[clothesline]]s and [[solar cookers]] which concentrate sunlight for cooking, drying and [[pasteurization]]. More sophisticated technologies concentrate sunlight for high-temperature material testing, metal [[smelting]] and industrial [[chemical]] production. A range of experimental [[solar vehicle]]s provide ground, air and sea transportation.
Solar [[distillation]] and [[disinfection]] techniques produce [[potable water]] for millions of people worldwide. Simple applications include [[clothesline]]s and [[solar cookers]] which concentrate sunlight for cooking, drying and [[pasteurization]]. More sophisticated technologies concentrate sunlight for high-temperature material testing, metal [[smelting]] and industrial [[chemical]] production. A range of experimental [[solar vehicle]]s provide ground, air and sea transportation.


===2nd Proposal by Apteva===
===Proposal===
'''Solar energy''' uses the [[light]] and [[heat|radiant heat]] from the [[Sun]] which powers [[Earth]]'s [[climate]] and [[weather]] and sustains [[life]]. Since [[ancient times]] it has been harnessed for human use through a range of technologies. Solar [[non-ionizing radiation|radiation]] along with secondary solar resources such as [[wind power|wind]] and [[wave power|wave]] power, [[hydroelectricity]] and [[biomass]] account for most of the available [[renewable energy]] on Earth.

The term '''solar power''' is used interchangeably with solar energy, but refers more specifically to the conversion of sunlight into [[electricity]] by [[photovoltaics]], concentrating solar thermal devices, or by an experimental technology such as a [[solar chimney]] or [[solar pond]].

Solar energy technologies can provide [[daylighting]] and thermal comfort in [[passive solar|passive]] buildings, [[potable water]] via [[distillation]] and [[disinfection]], [[solar hot water | hot water]] and space heating, space cooling by [[absorption]] or vapor-compression [[refrigeration]], thermal [[Solar cooking | energy for cooking]], high temperature process heat for industrial purposes, and [[solar vehicles|transportation]].

===Consensus version===
(22:04, 7 October 2008)
(22:04, 7 October 2008)


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Solar energy technologies can provide daylighting and thermal comfort in passive buildings; potable water via distillation and disinfection; water and space heating; space cooling by absorption or vapor-compression refrigeration; high temperature process heat for industrial purposes; and electrical generation by thermal or photovoltaic means.
Solar energy technologies can provide daylighting and thermal comfort in passive buildings; potable water via distillation and disinfection; water and space heating; space cooling by absorption or vapor-compression refrigeration; high temperature process heat for industrial purposes; and electrical generation by thermal or photovoltaic means.


===Interim===
===Latest proposal (make changes below, use only after everyone agrees)===
(formerly identified as "current version")

'''Solar energy''' uses the [[light]] and [[heat|radiant heat]] from the [[Sun]] which powers [[Earth]]'s [[climate]] and [[weather]] and sustains [[life]]. Since [[ancient times]] it has been harnessed for human use through a range of technologies. Solar [[non-ionizing radiation|radiation]] along with secondary solar resources such as [[wind power|wind]] and [[wave power|wave]] power, [[hydroelectricity]] and [[biomass]] account for most of the available [[renewable energy]] on Earth.

The term '''solar power''' is used interchangeably with solar energy, but refers more specifically to the conversion of sunlight into [[electricity]] by [[photovoltaics]], concentrating solar thermal devices, or by an experimental technology such as a [[solar chimney]] or [[solar pond]].

Solar energy technologies can provide [[daylighting]] and thermal comfort in [[passive solar|passive]] buildings, [[potable water]] via [[distillation]] and [[disinfection]], [[solar hot water | hot water]] and space heating, space cooling by [[absorption]] or vapor-compression [[refrigeration]], thermal [[Solar cooking | energy for cooking]], high temperature process heat for industrial purposes, and [[solar vehicles|transportation]].

===Revised Proposal===


'''Solar energy''' uses the [[light]] and [[heat|radiant heat]] from the [[Sun]], that powers [[Earth]]'s [[climate]] and [[weather]] and sustains [[life]]. Since [[ancient times]] it has been harnessed for human use with a variety of technologies. Solar [[non-ionizing radiation|radiation]] along with secondary solar resources such as [[wind power|wind]] and [[wave power|wave]] power, [[hydroelectricity]] and [[biomass]] account for most of the available [[renewable energy]] on Earth.
'''Solar energy''' uses the [[light]] and [[heat|radiant heat]] from the [[Sun]], that powers [[Earth]]'s [[climate]] and [[weather]] and sustains [[life]]. Since [[ancient times]] it has been harnessed for human use with a variety of technologies. Solar [[non-ionizing radiation|radiation]] along with secondary solar resources such as [[wind power|wind]] and [[wave power|wave]] power, [[hydroelectricity]] and [[biomass]] account for most of the available [[renewable energy]] on Earth.
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< add a third or third and fourth paragraph >
< add a third or third and fourth paragraph >


===Consensus version with updates===
===Consensus version===
17:44, 14 October 2008 (UTC)


'''Solar energy''' is the [[light]] and [[heat|radiant heat]] from the [[Sun]] that influences [[Earth]]'s [[climate]] and [[weather]] and sustains [[life]]. '''Solar power''' is the rate of solar energy at a point in time; it is sometimes used as a [[synonym]] for solar energy or more specifically to refer to electricity generated from solar radiation. <ref>California Energy Commission Glossary</ref>. Since [[ancient times]] solar energy has been harnessed for human use through a range of technologies. Solar [[non-ionizing radiation|radiation]] along with secondary solar resources such as [[wind power|wind]] and [[wave power|wave]] power, [[hydroelectricity]] and [[biomass]] account for most of the available flow of [[renewable energy]] on Earth.
'''Solar energy''' is the [[light]] and [[heat|radiant heat]] from the [[Sun]] that influences [[Earth]]'s [[climate]] and [[weather]] and sustains [[life]]. '''Solar power''' is the rate of solar energy at a point in time; it is sometimes used as a [[synonym]] for solar energy or more specifically to refer to electricity generated from solar radiation. Since [[ancient times]] solar energy has been harnessed for human use through a range of technologies. Solar [[non-ionizing radiation|radiation]] along with secondary solar resources such as [[wind power|wind]] and [[wave power|wave]] power, [[hydroelectricity]] and [[biomass]] account for most of the available flow of [[renewable energy]] on Earth.


Solar energy technologies can provide electrical generation by [[heat engine]] or [[photovoltaic]] means, [[daylighting]] and space heating in [[passive solar|passive solar]] and [[active solar]] buildings, [[potable water]] via [[distillation]] and [[disinfection]], [[solar hot water | hot water]], space cooling by [[absorption]] or vapor-compression [[refrigeration]], thermal [[Solar cooking | energy for cooking]], and high temperature process heat for industrial purposes.
Solar energy technologies can provide electrical generation by [[heat engine]] or [[photovoltaic]] means, [[daylighting]] and space heating in [[passive solar|passive solar]] and [[active solar]] buildings, [[potable water]] via [[distillation]] and [[disinfection]], [[solar hot water | hot water]], space cooling by [[absorption]] or vapor-compression [[refrigeration]], thermal [[Solar cooking | energy for cooking]], and high temperature process heat for industrial purposes.


===Further changes (proposal)===
==Comments==

'''Solar energy''' uses the [[light]] and [[heat|radiant heat]] from the [[Sun]], which is the energy source for [[Earth]]'s [[climate]] and [[weather]] and sustains [[life]]. '''Solar power''', often used interchangeably with solar energy, refers to electricity generated from solar radiation. Since [[ancient times]] solar energy has been harnessed for human use through a range of technologies. Solar [[non-ionizing radiation|radiation]] along with secondary solar resources such as [[wind power|wind]] and [[wave power|wave]] power, [[hydroelectricity]] and [[biomass]] account for most of the available [[renewable energy]] on Earth.

Solar energy technologies can provide electrical generation by [[heat engine]] or [[photovoltaic]] means, [[daylighting]] and space heating in [[passive solar|passive solar]] and [[active solar]] buildings, [[potable water]] via [[distillation]] and [[disinfection]], [[solar hot water | hot water]], space cooling by [[absorption]] or vapor-compression [[refrigeration]], thermal [[Solar cooking | energy for cooking]], and high temperature process heat for industrial purposes.

== Table proposals ==

===From RfM===

{| class="wikitable" style="margin-left: 10px"
|-
!style="background-color: #cfb;" colspan="2;" |Yearly Energy Sources & Annual Energy Consumption
|-
|Solar <ref>Smil (2006), p. 12</ref><!-- Smil quotes an absorbed solar flux of 122 PW. Multiplying this number by the number of seconds in a year yields 3,850 ZJ. -->
|align=right|3850.00&nbsp;[[joule#SI multiples|ZJ]]
|-
|Wind <ref>{{cite web
| author=Archer, Cristina
| coauthor=Jacobson, Mark
| title=Evaluation of Global Wind Power
| publisher=Stanford
| url=http://www.stanford.edu/group/efmh/winds/global_winds.html
| accessdate=2008-06-03}}</ref>
|align=right|2.25&nbsp;ZJ
|-
|Biomass <ref>{{cite web
| publisher=Food and Agriculture Organization of the United Nations
| url=http://www.fao.org/docrep/w7241e/w7241e06.htm#TopOfPage
| title=Energy conversion by photosynthetic organisms
| accessdate=2008-05-25}}</ref>
|align=right|3.00&nbsp;ZJ
|-
|Electricity (2005) <ref>{{cite web
| publisher=[[Energy Information Administration]]
| url=http://www.eia.doe.gov/iea/elec.html
| title=World Total Net Electricity Consumption, 1980-2005
| accessdate=2008-05-25}}</ref>
|align=right| -0.06&nbsp;ZJ
|-
|Primary energy use (2005) <ref>{{cite web
| publisher=[[Energy Information Administration]]
| url=http://www.eia.doe.gov/pub/international/iealf/table18.xls
| title=World Consumption of Primary Energy by Energy Type and Selected Country Groups, 1980-2004
| accessdate=2008-05-17}}</ref><!-- converted from 462 quadrillion BTUs -->
|align=right| -0.49&nbsp;ZJ
|-
|}

===Correction to wind/solar data===


{| class="wikitable" style="margin-left: 10px"
|-
!style="background-color: #cfb;" colspan="2;" |Yearly energy resources & annual energy consumption
|-
|Solar <ref name=GCEP>[http://gcep.stanford.edu/research/exergycharts.html GCEP]</ref>
|align=right|2710.00&nbsp;[[joule#SI multiples|ZJ]]
|-
|Wind <ref name=GCEP/>
|align=right|27.45&nbsp;ZJ
|-
|Biomass <ref>{{cite web
| publisher=Food and Agriculture Organization of the United Nations
| url=http://www.fao.org/docrep/w7241e/w7241e06.htm#TopOfPage
| title=Energy conversion by photosynthetic organisms
| accessdate=2008-05-25}}</ref>
|align=right|3.00&nbsp;ZJ
|-
|Electricity (2005) <ref>{{cite web
| publisher=[[Energy Information Administration]]
| url=http://www.eia.doe.gov/iea/elec.html
| title=World Total Net Electricity Consumption, 1980-2005
| accessdate=2008-05-25}}</ref>
|align=right| -0.06&nbsp;ZJ
|-
|Primary energy use (2005) <ref>{{cite web
| publisher=[[Energy Information Administration]]
| url=http://www.eia.doe.gov/pub/international/iealf/table18.xls
| title=World Consumption of Primary Energy by Energy Type and Selected Country Groups, 1980-2005
| accessdate=2008-10-20}}</ref><!-- converted from 462.798 quadrillion BTUs -->
|align=right| -0.49&nbsp;ZJ
|-
|}

===Proposal 1===

{| class="wikitable" style="margin-left: 10px"
|-
!style="background-color: #cfb;" colspan="2;" |Energy resources and consumption
|-
|Solar <ref name=GCEP>[http://gcep.stanford.edu/research/exergycharts.html GCEP]</ref>
|align=right|86,000.00&nbsp;[[watt#Terawatt|TW]]
|-
|Wind <ref name=GCEP/>
|align=right|870.00&nbsp;TW
|-
|Biomass <ref>{{cite web
| publisher=Food and Agriculture Organization of the United Nations
| url=http://www.fao.org/docrep/w7241e/w7241e06.htm#TopOfPage
| title=Energy conversion by photosynthetic organisms
| accessdate=2008-05-25}}</ref>
|align=right|90.00&nbsp;TW
|-
|Electricity (2005) <ref>{{cite web
| publisher=[[Energy Information Administration]]
| url=http://www.eia.doe.gov/iea/elec.html
| title= World Total Net Electricity Consumption (Billion Kilowatthours), 1980-2005
| accessdate=2008-10-20}}</ref><!-- converted from 15,746.54 Billion Kilowatthours -->
|align=right| -1.80&nbsp;TW
|-
|Primary energy use (2005) <ref>{{cite web
| publisher=[[Energy Information Administration]]
| url=http://www.eia.doe.gov/pub/international/iealf/table18.xls
| title=World Consumption of Primary Energy by Energy Type and Selected Country Groups, 1980-2005
| accessdate=2008-10-20}}</ref><!-- converted from 462.798 quadrillion BTUs -->
|align=right| -15.47&nbsp;TW
|-
|}

===Proposal 2===
{| class="wikitable" style="margin-left: 10px" align="right"
|style="background-color: LightGray" colspan="1;" | Source and Use
|style="background-color: LightGray" colspan="1;" | Total Physical Suppy
|style="background-color: LightGray" colspan="1;" | Technical Potential
|-
|style = "background-color: Lavender" |Solar
|style = "background-color: Lavender" align="Center"|3,850&nbsp;[[joule#SI multiples|ZJ]] <ref>Smil (2006), p. 12</ref><!-- Smil quotes an absorbed solar flux of 122 PW. Multiplying this number by the number of seconds in a year yields 3,850 ZJ. -->
|style = "background-color: Lavender" align="Center"|3.38&nbsp;ZJ <ref>{{cite web
| publisher=Energy Policy
| url=http://www.igitur-archive.library.uu.nl/chem/2007-0621-201307/NWS-E-2006-225.pdf
| title=Renewable energy sources: Their global potential for the first-half of the 21st century at a global level: An integrated approach
| author=de Vriesa,Bert J.M. Detlef P.
| author2= van Vuurenb, Detlef P.
| author3= Hoogwijk, Monique M.
| accessdate=2008-05-25}}</ref>
|-
|style = "background-color: Lavender"|Wind
|style = "background-color: Lavender" align="Center"|110&nbsp;ZJ <ref>Lorenze (1976), p. X</ref>
|style = "background-color: Lavender" align="Center"|2.25&nbsp;ZJ <ref>{{cite web
| author=Archer, Cristina
| coauthor=Jacobson, Mark
| title=Evaluation of Global Wind Power
| publisher=Stanford
| url=http://www.stanford.edu/group/efmh/winds/global_winds.html
| accessdate=2008-06-03}}</ref>
|-
|style = "background-color: Lavender"|Biomass
|style = "background-color: Lavender" align="Center"|3.0&nbsp;ZJ <ref>{{cite web
| publisher=Food and Agriculture Organization of the United Nations
| url=http://www.fao.org/docrep/w7241e/w7241e06.htm#TopOfPage
| title=Energy conversion by photosynthetic organisms
| accessdate=2008-05-25}}</ref>
|style = "background-color: Lavender" align="Center"|0.104&nbsp;ZJ <ref>{{cite book
| author=Kyritsis, Spyros
| year=2001
| title=1st World Conference on Biomass for Energy and Industry
| publisher=Earthscan
| isbn=1902916158, 9781902916156
}}</ref>
|-
|style = "background-color: Lavender"|Hydro
|style = "background-color: Lavender" align="Center"|0.367&nbsp;ZJ <ref>Smil (2006), p. 245</ref>
|style = "background-color: Lavender" align="Center"|0.052&nbsp;ZJ <ref>Smil (2006), p. 246</ref>
|-
|style = "background-color: Lavender"|Electricity (2005)
|style = "background-color: Lavender" align="Center"|---
|style = "background-color: Lavender" align="Center"|0.0567&nbsp;ZJ <ref>{{cite web
| publisher=[[Energy Information Administration]]
| url=http://www.eia.doe.gov/iea/elec.html
| title=World Total Net Electricity Consumption, 1980-2005
| accessdate=2008-05-25}}</ref>
|-
|style = "background-color: Lavender"|Primary energy use (2005)
|style = "background-color: Lavender" align="Center"|---
|style = "background-color: Lavender" align="Center"|0.487&nbsp;ZJ <ref>{{cite web
| publisher=[[Energy Information Administration]]
| url=http://www.eia.doe.gov/pub/international/iealf/table18.xls
| title=World Consumption of Primary Energy by Energy Type and Selected Country Groups, 1980-2004
| accessdate=2008-05-17}}</ref><!-- converted from 462 quadrillion BTUs -->
|-
|}
{{clear}}

===Proposal 3===
<div style="float:right;border:solid gray 0px;">
{| class="wikitable" style="float: right;" margin-left: 10px"
!style="background-color: LightGray" colspan="1;" width="160;"| Resources
!style="background-color: LightGray" colspan="1;" width="160;"| Total Physical Suppy
!style="background-color: LightGray" colspan="1;" width="160;"| Technical Potential
|-
|style = "background-color: Lavender" |Solar
|style = "background-color: Lavender" align="Center"|3850&nbsp;[[joule#SI multiples|ZJ]] <ref>Smil (2006), p. 12</ref><!-- Smil quotes an absorbed solar flux of 122 PW. Multiplying this number by the number of seconds in a year yields 3,850 ZJ. -->
|style = "background-color: Lavender" align="Center"|3.38&nbsp;ZJ <ref>{{cite web
| publisher=Energy Policy
| url=http://www.igitur-archive.library.uu.nl/chem/2007-0621-201307/NWS-E-2006-225.pdf
| title=Renewable energy sources: Their global potential for the first-half of the 21st century at a global level: An integrated approach
| author=de Vriesa,Bert J.M. Detlef P.
| author2= van Vuurenb, Detlef P.
| author3= Hoogwijk, Monique M.
| accessdate=2008-05-25}}</ref>
|-
|style = "background-color: Lavender"|Wind
|style = "background-color: Lavender" align="Center"|110&nbsp;ZJ <ref>Lorenze (1976), p. X</ref>
|style = "background-color: Lavender" align="Center"|2.25&nbsp;ZJ <ref>{{cite web
| author=Archer, Cristina
| coauthor=Jacobson, Mark
| title=Evaluation of Global Wind Power
| publisher=Stanford
| url=http://www.stanford.edu/group/efmh/winds/global_winds.html
| accessdate=2008-06-03}}</ref>
|-
|style = "background-color: Lavender"|Biomass
|style = "background-color: Lavender" align="Center"|3.0&nbsp;ZJ <ref>{{cite web
| publisher=Food and Agriculture Organization of the United Nations
| url=http://www.fao.org/docrep/w7241e/w7241e06.htm#TopOfPage
| title=Energy conversion by photosynthetic organisms
| accessdate=2008-05-25}}</ref>
|style = "background-color: Lavender" align="Center"|0.104&nbsp;ZJ <ref>{{cite book
| author=Kyritsis, Spyros
| year=2001
| title=1st World Conference on Biomass for Energy and Industry
| publisher=Earthscan
| isbn=1902916158, 9781902916156
}}</ref>
|-
|style = "background-color: Lavender"|Hydro
|style = "background-color: Lavender" align="Center"|0.367&nbsp;ZJ <ref>Smil (2006), p. 245</ref>
|style = "background-color: Lavender" align="Center"|0.052&nbsp;ZJ <ref>Smil (2006), p. 246</ref>
|-
|style = "background-color: Lavender"|Electricity (2005)
|style = "background-color: Lavender" align="Center"|---
|style = "background-color: Lavender" align="Center"|0.0567&nbsp;ZJ <ref>{{cite web
| publisher=[[Energy Information Administration]]
| url=http://www.eia.doe.gov/iea/elec.html
| title=World Total Net Electricity Consumption, 1980-2005
| accessdate=2008-05-25}}</ref>
|-
|style = "background-color: Lavender"|Primary energy use (2005)
|style = "background-color: Lavender" align="Center"|---
|style = "background-color: Lavender" align="Center"|0.487&nbsp;ZJ <ref>{{cite web
| publisher=[[Energy Information Administration]]
| url=http://www.eia.doe.gov/pub/international/iealf/table18.xls
| title=World Consumption of Primary Energy by Energy Type and Selected Country Groups, 1980-2004
| accessdate=2008-05-17}}</ref><!-- converted from 462 quadrillion BTUs -->
|-
|}
</div>
{{clear}}

===Proposal 4===
<div style="float:right;padding-left:1em;">
{| border="0" class="wikitable" style="background-color: Lavender;text-align:right;border:lavender 3px solid"
!style="background-color:LightGray;border-right:solid white 2px;width:13em;"|Source and Use
!style="background-color:LightGray;border-right:solid white 2px;width:13em;"|Total Physical Supply
!style="background-color:LightGray;border-right:solid white 0px;width:13em;"|Technical Potential
|-
|style="border:solid white 1px;text-align:left;"|Solar
|style="border:solid white 1px;padding-right:3em;"|3,850,000&nbsp;[[joule#SI multiples|EJ]] <ref>Smil (2006), p. 12</ref><!-- Smil quotes an absorbed solar flux of 122 PW. Multiplying this number by the number of seconds in a year yields 3,850,000 EJ. -->
|style="border:solid white 1px;padding-right:3em;"|3,380&nbsp;EJ <ref>{{cite web
| publisher=Energy Policy
| url=http://www.igitur-archive.library.uu.nl/chem/2007-0621-201307/NWS-E-2006-225.pdf
| title=Renewable energy sources: Their global potential for the first-half of the 21st century at a global level: An integrated approach
| author=de Vriesa,Bert J.M. Detlef P.
| author2= van Vuurenb, Detlef P.
| author3= Hoogwijk, Monique M.
| accessdate=2008-05-25}}</ref>
|-
|style="border:solid white 2px;text-align:left;"|Wind
|style="border:solid white 2px;padding-right:3em;"|110,000&nbsp;EJ <ref>Lorenze (1976), p. X</ref>
|style="border:solid white 2px;padding-right:3em;"|2,250&nbsp;EJ <ref>{{cite web
| author=Archer, Cristina
| coauthor=Jacobson, Mark
| title=Evaluation of Global Wind Power
| publisher=Stanford
| url=http://www.stanford.edu/group/efmh/winds/global_winds.html
| accessdate=2008-06-03}}</ref>
|-
|style="border:solid white 2px;text-align:left;"|Biomass
|style="border:solid white 2px;padding-right:3em;"|3,000&nbsp;EJ <ref>{{cite web
| publisher=Food and Agriculture Organization of the United Nations
| url=http://www.fao.org/docrep/w7241e/w7241e06.htm#TopOfPage
| title=Energy conversion by photosynthetic organisms
| accessdate=2008-05-25}}</ref>
|style="border:solid white 2px;padding-right:3em;"|104&nbsp;EJ <ref>{{cite book
| author=Kyritsis, Spyros
| year=2001
| title=1st World Conference on Biomass for Energy and Industry
| publisher=Earthscan
| isbn=1902916158, 9781902916156
}}</ref>
|-
|style="border:solid white 2px;text-align:left;"|Hydro
|style="border:solid white 2px;padding-right:3em;"|367&nbsp;EJ <ref>Smil (2006), p. 245</ref>
|style="border:solid white 2px;padding-right:3em;"|52&nbsp;EJ <ref>Smil (2006), p. 246</ref>
|-
|style="border:solid white 2px;text-align:left;"|Electricity (2005)
|style="border:solid white 2px;text-align:center;"|---
|style="border:solid white 2px;padding-right:3em;"|57<!--56.7-->&nbsp;EJ <ref>{{cite web
| publisher=[[Energy Information Administration]]
| url=http://www.eia.doe.gov/iea/elec.html
| title=World Total Net Electricity Consumption, 1980-2005
| accessdate=2008-05-25}}</ref>
|-
|style="border:solid white 2px;text-align:left;"|Primary energy use (2005)
|style="border:solid white 2px;text-align:center;"|---
|style="border:solid white 2px;padding-right:3em;"|487&nbsp;EJ <ref>{{cite web
| publisher=[[Energy Information Administration]]
| url=http://www.eia.doe.gov/pub/international/iealf/table18.xls
| title=World Consumption of Primary Energy by Energy Type and Selected Country Groups,
1980-2004
| accessdate=2008-05-17}}</ref><!-- converted from 462 quadrillion BTUs -->
|-
|style="border:solid white 2px;background-color:white;text-align:left;" colspan="3"|{{reflist|group="t"}}
* <small>if needed, explanatory notes (e.g. definitions) could go here here...</small>
|}
</div>
{{clear}}

===Proposal 5===
{| border="0" class="wikitable" style="text-align:right" align=right
!style="background-color: #cfb;" colspan=4|Annual energy resources and consumption
|-
!Resource and use
!Total supply
!Technical potential
!Current use
|-
|style="text-align:left;"|Solar
|style="padding-right:3em;"|3,850,000&nbsp;[[joule#SI multiples|EJ]] <ref>Smil (2006), p. 12</ref><!-- Smil quotes an absorbed solar flux of 122 PW. Multiplying this number by the number of seconds in a year yields 3,850,000 EJ. -->
|style="padding-right:2em;"|3,380&nbsp;EJ <ref>{{cite web
| publisher=Energy Policy
| url=http://www.igitur-archive.library.uu.nl/chem/2007-0621-201307/NWS-E-2006-225.pdf
| title=Renewable energy sources: Their global potential for the first-half of the 21st century at a global level: An integrated approach
| author=de Vriesa,Bert J.M. Detlef P.
| author2= van Vuurenb, Detlef P.
| author3= Hoogwijk, Monique M.
| accessdate=2008-05-25}} Note: Forbidden<br>

You don't have permission to access /chem/2007-0621-201307/NWS-E-2006-225.pdf on this server.</ref> †
| xx (2007)
|-
|style="text-align:left;"|Wind
|style="padding-right:3em;"|110,000&nbsp;EJ <ref>Lorenze (1976), p. X</ref>
|style="padding-right:2em;"|795&nbsp;EJ <ref>{{cite web
| author=Archer, Cristina
| coauthor=Jacobson, Mark
| title=Evaluation of Global Wind Power
| publisher=Stanford
| url=http://www.stanford.edu/group/efmh/winds/global_winds.html
| accessdate=2008-06-03}}</ref> †
| xx (2007)
|-
|style="text-align:left;"|Biomass
|style="padding-right:3em;"|3,000&nbsp;EJ <ref>{{cite web
| publisher=Food and Agriculture Organization of the United Nations
| url=http://www.fao.org/docrep/w7241e/w7241e06.htm#TopOfPage
| title=Energy conversion by photosynthetic organisms
| accessdate=2008-05-25}}</ref>
|style="padding-right:3em;"|104&nbsp;EJ <ref>{{cite book
| author=Kyritsis, Spyros
| year=2001
| title=1st World Conference on Biomass for Energy and Industry
| publisher=Earthscan
| isbn=1902916158, 9781902916156
}}</ref>
| xx (2007)
|-
|style="text-align:left;"|Geothermal
|style="padding-right:3em;"|xx
|style="padding-right:3em;"|xx
| xx (2005)
|-
|style="text-align:left;"|Hydro
|style="padding-right:3em;"|367&nbsp;EJ <ref>Smil (2006), p. 245</ref>
|style="padding-right:3em;"|52&nbsp;EJ <ref>Smil (2006), p. 246</ref>
| xx (2005)
|-
|style="text-align:left;"|Electricity
|
|
|57<!--56.7-->&nbsp;EJ (2005)<ref>{{cite web
| publisher=[[Energy Information Administration]]
| url=http://www.eia.doe.gov/iea/elec.html
| title=World Total Net Electricity Consumption, 1980-2005
| accessdate=2008-05-25}}</ref>
|-
|style="text-align:left;"|Primary energy use
|
|
|487&nbsp;EJ (2005)<ref>{{cite web
| publisher=[[Energy Information Administration]]
| url=http://www.eia.doe.gov/pub/international/iealf/table18.xls
| title=World Consumption of Primary Energy by Energy Type and Selected Country Groups,
1980-2004
| accessdate=2008-05-17}}</ref><!-- converted from 462 quadrillion BTUs -->
|-
|style="background-color:white;text-align:left;" colspan="4"|{{reflist|group="t"}}
* † <small>The [[capacity factor]] for wind is assumed to be 0.35, and solar 0.20 using xx% efficiency.</small>
|}
{{clear}}

====Proposal 5.1====
Same as proposal 5 while ...
* sticking with the color scheme defined by "wikitable"; if used it ought to be used consistently
* not using attributes deprecated since 1999/HTML 4.01<br />(and also not supported in the XHTML 1.0 DTD, which WP pages ought to adhere to);
* not muddle css (presentation) and html (content)
ALSO: a) Citations are complete in this version. b) The caption ref placeholder is '&amp;#160;'

<div style="float:right;margin:1em 0 1em 1em;">
{| class="wikitable" style="border-spacing:1em;text-align:right;"<!-- most content is right-aligned -->
!colspan="4"|Annual energy resources and consumption
|-
!Resource and use
!style="width:11em;"|Total supply
!style="width:11em;"|Technical potential
!style="width:11em;"|Current use
|-
|style="text-align:left;"|Solar
|style="padding-right:1em;"|3,850,000 [[joule#SI multiples|EJ]] <ref>Smil (2006), p. 12</ref><!-- Smil quotes an absorbed solar flux of 122 PW. Multiplying this number by the number of seconds in a year yields 3,850,000 EJ. -->
|style="padding-right:1em;"|3,380 EJ <ref>{{citation
| title=Renewable energy sources: Their global potential for the first-half of the 21st century at a global level: An integrated approach
| last=de Vriesa|first=Bert J.M.|last2=van Vuuren|first2=Detlef P.|last3=Hoogwijk, Monique M.
| journal=Energy Policy
| year=2007|volume=35|issue=4|pages=2590-2610
| doi=10.1016/j.enpol.2006.09.002}}</ref> †
|style="padding-right:1em;"|xx (2007)
|-
|style="text-align:left;"|Wind
|style="padding-right:1em;"|110,000 EJ <ref>Lorenze (1976), p. X</ref>
|style="padding-right:1em;"|795 EJ <ref>{{citation
| last=Archer|first=Cristina|last2=Jacobson|first2=Mark Z.
| title=Evaluation of Global Wind Power
| url=http://www.stanford.edu/group/efmh/winds/global_winds.html
| journal=Journal of Geophysical Research - Atmospheres
| year=2005|volume=110|issue=D12110
| doi=10.1029/2004JD005462
}}</ref> †
|style="padding-right:1em;"|xx (2007)
|-
|style="text-align:left;"|Biomass
|style="padding-right:1em;"|3,000 EJ <ref>{{citation
| chapter=Energy conversion by photosynthetic organisms
| title=Renewable biological systems for alternative sustainable energy production
| series=FAO Agricultural Services Bulletin
| volume=128
| chapter-url=http://www.fao.org/docrep/w7241e/w7241e06.htm
| editor-last=Miyamoto|editor-first=Kazuhisa
| isbn=92-5-104059-1
| year=1997
| location=Rome
| publisher=Food and Agriculture Organization of the United Nations
}}</ref>
|style="padding-right:1em;"|104 EJ <ref>{{citation
<!-- PAGE NUMBER, VOL. NUMBER, CHAPTER TITLE, CHAPTER AUTHOR ARE MISSING. -->
| chapter=NOT SPECIFIED
| last=SPECIFIED
| first=NOT
| pages=NOT SPECIFIED
| volume=NOT SPECIFIED
| title=Proceedings of the First World Conference on Biomass for Energy and Industry
| editor-last=Kyritsis|editor-first=Spyros
| editor2-last=Beenackers|editor2-first=A.A.C.M.
| editor3-last=Helm|editor3-first=P.
| editor4-last=Grassi|editor4-first=A.
| editor5-last=Ciaramonti|editor5-first=D.
| year=2001
| publisher=Earthscan
| location=London
| isbn=1-902916-15-8
}}</ref> &#160;
|style="padding-right:1em;"|xx (2007)
|-
|style="text-align:left;"|Geothermal
|style="padding-right:1em;"|xx
|style="padding-right:1em;"|xx &#160;
|style="padding-right:1em;"|xx (2005)
|-
|style="text-align:left;"|Hydro
|style="padding-right:1em;"|367 EJ <ref>Smil (2006), p. 245</ref>
|style="padding-right:1em;"|52 EJ <ref>Smil (2006), p. 246</ref> &#160;
|style="padding-right:1em;"|xx (2005)
|-
|style="text-align:left;"|Electricity
|style="padding-right:1em;"|&nbsp;
|style="padding-right:1em;"|&nbsp; &#160;
|style="padding-right:1em;"|57<!--56.7--> EJ (2005)<ref>{{citation
| chapter=World Total Net Electricity Consumption, 1980-2005
| year=2007
| title=International Energy Annual 2005
| editor-last=<!--Smith|editor-first=Patricia-->
| author=US DOE/Energy Information Administration
| publisher=eia.doe.gov
| location=Washington
| url=http://www.eia.doe.gov/iea/elec.html <!-- this is url of title, not of chapter -->
| accessdate=2008-05-25}}</ref>
|-
|style="text-align:left;"|Primary energy use
|style="padding-right:1em;"|&nbsp;
|style="padding-right:1em;"|&nbsp; &#160;
|style="padding-right:1em;"|487 EJ (2005)<ref>{{citation
| chapter=Primary Energy Consumption by Source [Energy or Fuel Type], 1980-2005
| title=International Total Primary Energy Consumption and Energy Intensity: Selected Country Groups ... and World Total, 1980-2005
| year=2007<!-- "October 2, 2007" -->
| author=US DOE/Energy Information Administration
| <!--editor-last=Friedman|editor-first=Gregory-->
| publisher=eia.doe.gov
| location=Washington
| chapter-url=http://www.eia.doe.gov/pub/international/iealf/table18.xls
| accessdate=2008-05-17}}</ref><!-- converted from 462 quadrillion BTUs -->
|-
|style="background-color:white;text-align:left;" colspan="4"|{{reflist|group="t"}}
* † <small>The [[capacity factor]] for wind is assumed to be 0.35, and solar 0.20 using xx% efficiency.</small>
|}
</div>

==References==
{{reflist}}

== A Proposal To Review The Approach ==

I do not see why we are getting bogged down endlessly in trivial semantics and in specific and incomplete end product or end use listings. Every page is a bid to inform and educate as also an attempt for mind-share.

''Solar energy IS radiant light and heat.''
Then there are the following basics:
1. Use the heat OR light to generate electricity. A detailed listing of what electricity can be used for belongs elsewhere.
2. Use the heat to directly heat ANYTHING (i.e. without conversion to electricity). The Sahara desert is the biggest recipient and store! What heat can accomplish belongs elsewhere.
3. Use light to illuminate structures of all sorts internally and externally. Use heat to stimulate ventilation in buildings. Discussions and descriptions of smart building design for these purposes belongs elsewhere.

Based on this there needs to be a partial listing of important applications and corresponding technologies in some order of utility and viability. This list and the order can be debated.

There can be a separate section for emerging technologies.

Once this list is agreed a brief section on each will complete the picture. This needs to contain
1. a description.
2. state of the art report.
3. current viability assessment.
The last is important to ensure that readers do not view the whole thing as just ''hot air''.


Finally, there really isn't much point in using up valuable mind-share on concepts which made sense at one time, have been attempted at pilot or commercial scale and abandoned.
I agree with the last comment by itsmejudith (restructuring the Solar Power sentence using a semi-colon). --[[User:Skyemoor|Skyemoor]] ([[User talk:Skyemoor|talk]]) 16:04, 14 October 2008 (UTC)
A M Spock 03:05, 25 January 2009 (UTC)

Latest revision as of 11:11, 2 August 2022

Lead section

[edit]

Original

[edit]

(September 2008)

Solar energy refers to the utilization of the radiant energy from the Sun. Solar power is used interchangeably with solar energy, but refers more specifically to the conversion of sunlight into electricity by photovoltaics, concentrating solar thermal devices, or by an experimental technology such as a solar chimney or solar pond.

Solar energy and shading are important considerations in building design. Thermal mass is used to conserve the heat that sunshine delivers to all buildings. Daylighting techniques optimize the use of light in buildings. Solar water heaters heat swimming pools and provide domestic hot water. In agriculture, greenhouses expand growing seasons and pumps powered by solar cells (known as photovoltaics) provide water for grazing animals. Evaporation ponds are used to harvest salt and clean waste streams of contaminants.

Solar distillation and disinfection techniques produce potable water for millions of people worldwide. Simple applications include clotheslines and solar cookers which concentrate sunlight for cooking, drying and pasteurization. More sophisticated technologies concentrate sunlight for high-temperature material testing, metal smelting and industrial chemical production. A range of experimental solar vehicles provide ground, air and sea transportation.

Proposal

[edit]

(22:04, 7 October 2008)

Solar energy is heat and light from the sun. This energy resource powers the climate and weather and sustains life on Earth. Solar radiation along with secondary solar resources such as wind and wave power, hydroelectricity and biomass account for over 99.97% of the available flow of renewable energy on Earth.

Solar energy technologies can provide daylighting and thermal comfort in passive buildings; potable water via distillation and disinfection; water and space heating; space cooling by absorption or vapor-compression refrigeration; high temperature process heat for industrial purposes; and electrical generation by thermal or photovoltaic means.

Interim

[edit]

(formerly identified as "current version")

Solar energy uses the light and radiant heat from the Sun which powers Earth's climate and weather and sustains life. Since ancient times it has been harnessed for human use through a range of technologies. Solar radiation along with secondary solar resources such as wind and wave power, hydroelectricity and biomass account for most of the available renewable energy on Earth.

The term solar power is used interchangeably with solar energy, but refers more specifically to the conversion of sunlight into electricity by photovoltaics, concentrating solar thermal devices, or by an experimental technology such as a solar chimney or solar pond.

Solar energy technologies can provide daylighting and thermal comfort in passive buildings, potable water via distillation and disinfection, hot water and space heating, space cooling by absorption or vapor-compression refrigeration, thermal energy for cooking, high temperature process heat for industrial purposes, and transportation.

Revised Proposal

[edit]

Solar energy uses the light and radiant heat from the Sun, that powers Earth's climate and weather and sustains life. Since ancient times it has been harnessed for human use with a variety of technologies. Solar radiation along with secondary solar resources such as wind and wave power, hydroelectricity and biomass account for most of the available renewable energy on Earth.

Solar power is used synonymously with solar energy, but refers more specifically to the conversion of sunlight into electricity by photovoltaics, concentrating solar thermal devices, or by an experimental technology such as a solar chimney or solar pond.

Solar energy technologies can provide daylighting and thermal comfort in passive buildings, potable water via distillation and disinfection, hot water and space heating, space cooling by absorption or vapor-compression refrigeration, thermal energy for cooking, high temperature process heat for industrial purposes, and transportation. < add missing items, make into sentences where possible >

< add a third or third and fourth paragraph >

Consensus version

[edit]

17:44, 14 October 2008 (UTC)

Solar energy is the light and radiant heat from the Sun that influences Earth's climate and weather and sustains life. Solar power is the rate of solar energy at a point in time; it is sometimes used as a synonym for solar energy or more specifically to refer to electricity generated from solar radiation. Since ancient times solar energy has been harnessed for human use through a range of technologies. Solar radiation along with secondary solar resources such as wind and wave power, hydroelectricity and biomass account for most of the available flow of renewable energy on Earth.

Solar energy technologies can provide electrical generation by heat engine or photovoltaic means, daylighting and space heating in passive solar and active solar buildings, potable water via distillation and disinfection, hot water, space cooling by absorption or vapor-compression refrigeration, thermal energy for cooking, and high temperature process heat for industrial purposes.

Further changes (proposal)

[edit]

Solar energy uses the light and radiant heat from the Sun, which is the energy source for Earth's climate and weather and sustains life. Solar power, often used interchangeably with solar energy, refers to electricity generated from solar radiation. Since ancient times solar energy has been harnessed for human use through a range of technologies. Solar radiation along with secondary solar resources such as wind and wave power, hydroelectricity and biomass account for most of the available renewable energy on Earth.

Solar energy technologies can provide electrical generation by heat engine or photovoltaic means, daylighting and space heating in passive solar and active solar buildings, potable water via distillation and disinfection, hot water, space cooling by absorption or vapor-compression refrigeration, thermal energy for cooking, and high temperature process heat for industrial purposes.

Table proposals

[edit]

From RfM

[edit]
Yearly Energy Sources & Annual Energy Consumption
Solar [1] 3850.00 ZJ
Wind [2] 2.25 ZJ
Biomass [3] 3.00 ZJ
Electricity (2005) [4] -0.06 ZJ
Primary energy use (2005) [5] -0.49 ZJ

Correction to wind/solar data

[edit]
Yearly energy resources & annual energy consumption
Solar [6] 2710.00 ZJ
Wind [6] 27.45 ZJ
Biomass [7] 3.00 ZJ
Electricity (2005) [8] -0.06 ZJ
Primary energy use (2005) [9] -0.49 ZJ

Proposal 1

[edit]
Energy resources and consumption
Solar [6] 86,000.00 TW
Wind [6] 870.00 TW
Biomass [10] 90.00 TW
Electricity (2005) [11] -1.80 TW
Primary energy use (2005) [12] -15.47 TW

Proposal 2

[edit]
Source and Use Total Physical Suppy Technical Potential
Solar 3,850 ZJ [13] 3.38 ZJ [14]
Wind 110 ZJ [15] 2.25 ZJ [16]
Biomass 3.0 ZJ [17] 0.104 ZJ [18]
Hydro 0.367 ZJ [19] 0.052 ZJ [20]
Electricity (2005) --- 0.0567 ZJ [21]
Primary energy use (2005) --- 0.487 ZJ [22]

Proposal 3

[edit]
Resources Total Physical Suppy Technical Potential
Solar 3850 ZJ [23] 3.38 ZJ [24]
Wind 110 ZJ [25] 2.25 ZJ [26]
Biomass 3.0 ZJ [27] 0.104 ZJ [28]
Hydro 0.367 ZJ [29] 0.052 ZJ [30]
Electricity (2005) --- 0.0567 ZJ [31]
Primary energy use (2005) --- 0.487 ZJ [32]

Proposal 4

[edit]
Source and Use Total Physical Supply Technical Potential
Solar 3,850,000 EJ [33] 3,380 EJ [34]
Wind 110,000 EJ [35] 2,250 EJ [36]
Biomass 3,000 EJ [37] 104 EJ [38]
Hydro 367 EJ [39] 52 EJ [40]
Electricity (2005) --- 57 EJ [41]
Primary energy use (2005) --- 487 EJ [42]
  • if needed, explanatory notes (e.g. definitions) could go here here...

Proposal 5

[edit]
Annual energy resources and consumption
Resource and use Total supply Technical potential Current use
Solar 3,850,000 EJ [43] 3,380 EJ [44] xx (2007)
Wind 110,000 EJ [45] 795 EJ [46] xx (2007)
Biomass 3,000 EJ [47] 104 EJ [48] xx (2007)
Geothermal xx xx xx (2005)
Hydro 367 EJ [49] 52 EJ [50] xx (2005)
Electricity 57 EJ (2005)[51]
Primary energy use 487 EJ (2005)[52]
  • The capacity factor for wind is assumed to be 0.35, and solar 0.20 using xx% efficiency.

Proposal 5.1

[edit]

Same as proposal 5 while ...

  • sticking with the color scheme defined by "wikitable"; if used it ought to be used consistently
  • not using attributes deprecated since 1999/HTML 4.01
    (and also not supported in the XHTML 1.0 DTD, which WP pages ought to adhere to);
  • not muddle css (presentation) and html (content)

ALSO: a) Citations are complete in this version. b) The caption ref placeholder is '&#160;'

Annual energy resources and consumption
Resource and use Total supply Technical potential Current use
Solar 3,850,000 EJ [53] 3,380 EJ [54] xx (2007)
Wind 110,000 EJ [55] 795 EJ [56] xx (2007)
Biomass 3,000 EJ [57] 104 EJ [58]   xx (2007)
Geothermal xx xx   xx (2005)
Hydro 367 EJ [59] 52 EJ [60]   xx (2005)
Electricity       57 EJ (2005)[61]
Primary energy use       487 EJ (2005)[62]
  • The capacity factor for wind is assumed to be 0.35, and solar 0.20 using xx% efficiency.

References

[edit]
  1. ^ Smil (2006), p. 12
  2. ^ Archer, Cristina. "Evaluation of Global Wind Power". Stanford. Retrieved 2008-06-03. {{cite web}}: Unknown parameter |coauthor= ignored (|author= suggested) (help)
  3. ^ "Energy conversion by photosynthetic organisms". Food and Agriculture Organization of the United Nations. Retrieved 2008-05-25.
  4. ^ "World Total Net Electricity Consumption, 1980-2005". Energy Information Administration. Retrieved 2008-05-25.
  5. ^ "World Consumption of Primary Energy by Energy Type and Selected Country Groups, 1980-2004". Energy Information Administration. Retrieved 2008-05-17.
  6. ^ a b c d GCEP
  7. ^ "Energy conversion by photosynthetic organisms". Food and Agriculture Organization of the United Nations. Retrieved 2008-05-25.
  8. ^ "World Total Net Electricity Consumption, 1980-2005". Energy Information Administration. Retrieved 2008-05-25.
  9. ^ "World Consumption of Primary Energy by Energy Type and Selected Country Groups, 1980-2005". Energy Information Administration. Retrieved 2008-10-20.
  10. ^ "Energy conversion by photosynthetic organisms". Food and Agriculture Organization of the United Nations. Retrieved 2008-05-25.
  11. ^ "World Total Net Electricity Consumption (Billion Kilowatthours), 1980-2005". Energy Information Administration. Retrieved 2008-10-20.
  12. ^ "World Consumption of Primary Energy by Energy Type and Selected Country Groups, 1980-2005". Energy Information Administration. Retrieved 2008-10-20.
  13. ^ Smil (2006), p. 12
  14. ^ de Vriesa,Bert J.M. Detlef P.; van Vuurenb, Detlef P.; Hoogwijk, Monique M. "Renewable energy sources: Their global potential for the first-half of the 21st century at a global level: An integrated approach" (PDF). Energy Policy. Retrieved 2008-05-25.
  15. ^ Lorenze (1976), p. X
  16. ^ Archer, Cristina. "Evaluation of Global Wind Power". Stanford. Retrieved 2008-06-03. {{cite web}}: Unknown parameter |coauthor= ignored (|author= suggested) (help)
  17. ^ "Energy conversion by photosynthetic organisms". Food and Agriculture Organization of the United Nations. Retrieved 2008-05-25.
  18. ^ Kyritsis, Spyros (2001). 1st World Conference on Biomass for Energy and Industry. Earthscan. ISBN 1902916158, 9781902916156. {{cite book}}: Check |isbn= value: invalid character (help)
  19. ^ Smil (2006), p. 245
  20. ^ Smil (2006), p. 246
  21. ^ "World Total Net Electricity Consumption, 1980-2005". Energy Information Administration. Retrieved 2008-05-25.
  22. ^ "World Consumption of Primary Energy by Energy Type and Selected Country Groups, 1980-2004". Energy Information Administration. Retrieved 2008-05-17.
  23. ^ Smil (2006), p. 12
  24. ^ de Vriesa,Bert J.M. Detlef P.; van Vuurenb, Detlef P.; Hoogwijk, Monique M. "Renewable energy sources: Their global potential for the first-half of the 21st century at a global level: An integrated approach" (PDF). Energy Policy. Retrieved 2008-05-25.
  25. ^ Lorenze (1976), p. X
  26. ^ Archer, Cristina. "Evaluation of Global Wind Power". Stanford. Retrieved 2008-06-03. {{cite web}}: Unknown parameter |coauthor= ignored (|author= suggested) (help)
  27. ^ "Energy conversion by photosynthetic organisms". Food and Agriculture Organization of the United Nations. Retrieved 2008-05-25.
  28. ^ Kyritsis, Spyros (2001). 1st World Conference on Biomass for Energy and Industry. Earthscan. ISBN 1902916158, 9781902916156. {{cite book}}: Check |isbn= value: invalid character (help)
  29. ^ Smil (2006), p. 245
  30. ^ Smil (2006), p. 246
  31. ^ "World Total Net Electricity Consumption, 1980-2005". Energy Information Administration. Retrieved 2008-05-25.
  32. ^ "World Consumption of Primary Energy by Energy Type and Selected Country Groups, 1980-2004". Energy Information Administration. Retrieved 2008-05-17.
  33. ^ Smil (2006), p. 12
  34. ^ de Vriesa,Bert J.M. Detlef P.; van Vuurenb, Detlef P.; Hoogwijk, Monique M. "Renewable energy sources: Their global potential for the first-half of the 21st century at a global level: An integrated approach" (PDF). Energy Policy. Retrieved 2008-05-25.
  35. ^ Lorenze (1976), p. X
  36. ^ Archer, Cristina. "Evaluation of Global Wind Power". Stanford. Retrieved 2008-06-03. {{cite web}}: Unknown parameter |coauthor= ignored (|author= suggested) (help)
  37. ^ "Energy conversion by photosynthetic organisms". Food and Agriculture Organization of the United Nations. Retrieved 2008-05-25.
  38. ^ Kyritsis, Spyros (2001). 1st World Conference on Biomass for Energy and Industry. Earthscan. ISBN 1902916158, 9781902916156. {{cite book}}: Check |isbn= value: invalid character (help)
  39. ^ Smil (2006), p. 245
  40. ^ Smil (2006), p. 246
  41. ^ "World Total Net Electricity Consumption, 1980-2005". Energy Information Administration. Retrieved 2008-05-25.
  42. ^ "World Consumption of Primary Energy by Energy Type and Selected Country Groups, 1980-2004". Energy Information Administration. Retrieved 2008-05-17. {{cite web}}: line feed character in |title= at position 80 (help)
  43. ^ Smil (2006), p. 12
  44. ^ de Vriesa,Bert J.M. Detlef P.; van Vuurenb, Detlef P.; Hoogwijk, Monique M. "Renewable energy sources: Their global potential for the first-half of the 21st century at a global level: An integrated approach" (PDF). Energy Policy. Retrieved 2008-05-25. Note: Forbidden
    You don't have permission to access /chem/2007-0621-201307/NWS-E-2006-225.pdf on this server.
  45. ^ Lorenze (1976), p. X
  46. ^ Archer, Cristina. "Evaluation of Global Wind Power". Stanford. Retrieved 2008-06-03. {{cite web}}: Unknown parameter |coauthor= ignored (|author= suggested) (help)
  47. ^ "Energy conversion by photosynthetic organisms". Food and Agriculture Organization of the United Nations. Retrieved 2008-05-25.
  48. ^ Kyritsis, Spyros (2001). 1st World Conference on Biomass for Energy and Industry. Earthscan. ISBN 1902916158, 9781902916156. {{cite book}}: Check |isbn= value: invalid character (help)
  49. ^ Smil (2006), p. 245
  50. ^ Smil (2006), p. 246
  51. ^ "World Total Net Electricity Consumption, 1980-2005". Energy Information Administration. Retrieved 2008-05-25.
  52. ^ "World Consumption of Primary Energy by Energy Type and Selected Country Groups, 1980-2004". Energy Information Administration. Retrieved 2008-05-17. {{cite web}}: line feed character in |title= at position 80 (help)
  53. ^ Smil (2006), p. 12
  54. ^ de Vriesa, Bert J.M.; van Vuuren, Detlef P.; Hoogwijk, Monique M. (2007), "Renewable energy sources: Their global potential for the first-half of the 21st century at a global level: An integrated approach", Energy Policy, 35 (4): 2590–2610, doi:10.1016/j.enpol.2006.09.002
  55. ^ Lorenze (1976), p. X
  56. ^ Archer, Cristina; Jacobson, Mark Z. (2005), "Evaluation of Global Wind Power", Journal of Geophysical Research - Atmospheres, 110 (D12110), doi:10.1029/2004JD005462
  57. ^ Miyamoto, Kazuhisa, ed. (1997), "Energy conversion by photosynthetic organisms", Renewable biological systems for alternative sustainable energy production, FAO Agricultural Services Bulletin, vol. 128, Rome: Food and Agriculture Organization of the United Nations, ISBN 92-5-104059-1
  58. ^ SPECIFIED, NOT (2001), "NOT SPECIFIED", in Kyritsis, Spyros; Beenackers, A.A.C.M.; Helm, P.; Grassi, A.; Ciaramonti, D. (eds.), Proceedings of the First World Conference on Biomass for Energy and Industry, vol. NOT SPECIFIED, London: Earthscan, pp. NOT SPECIFIED, ISBN 1-902916-15-8
  59. ^ Smil (2006), p. 245
  60. ^ Smil (2006), p. 246
  61. ^ US DOE/Energy Information Administration (2007), "World Total Net Electricity Consumption, 1980-2005", International Energy Annual 2005, Washington: eia.doe.gov, retrieved 2008-05-25
  62. ^ US DOE/Energy Information Administration (2007), "Primary Energy Consumption by Source [Energy or Fuel Type], 1980-2005", International Total Primary Energy Consumption and Energy Intensity: Selected Country Groups ... and World Total, 1980-2005, Washington: eia.doe.gov, retrieved 2008-05-17 {{citation}}: Cite has empty unknown parameter: |1= (help)

A Proposal To Review The Approach

[edit]

I do not see why we are getting bogged down endlessly in trivial semantics and in specific and incomplete end product or end use listings. Every page is a bid to inform and educate as also an attempt for mind-share.

Solar energy IS radiant light and heat. Then there are the following basics: 1. Use the heat OR light to generate electricity. A detailed listing of what electricity can be used for belongs elsewhere. 2. Use the heat to directly heat ANYTHING (i.e. without conversion to electricity). The Sahara desert is the biggest recipient and store! What heat can accomplish belongs elsewhere. 3. Use light to illuminate structures of all sorts internally and externally. Use heat to stimulate ventilation in buildings. Discussions and descriptions of smart building design for these purposes belongs elsewhere.

Based on this there needs to be a partial listing of important applications and corresponding technologies in some order of utility and viability. This list and the order can be debated.

There can be a separate section for emerging technologies.

Once this list is agreed a brief section on each will complete the picture. This needs to contain 1. a description. 2. state of the art report. 3. current viability assessment. The last is important to ensure that readers do not view the whole thing as just hot air.

Finally, there really isn't much point in using up valuable mind-share on concepts which made sense at one time, have been attempted at pilot or commercial scale and abandoned. A M Spock 03:05, 25 January 2009 (UTC)