Bioenergy - GCAM - Revision history

Matthew Binsted at 20:23, 21 June 2022

2022-06-21T20:23:14Z

← Older revision		Revision as of 22:23, 21 June 2022
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	== Biomass ==		== Biomass ==
	While most of the effort in modeling biomass supply is in the agriculture and land use component, there is a renewable resource represented in the energy system, that generally refers to municipal and industrial wastes that can be used for energy purposes. The supply curves use the same functional form as printed in the [https://jgcri.github.io/gcam-doc/supply_energy.html#wind wind section], and the specific quantities are documented in ~~[https://jgcri~~.~~github~~.~~io/gcam-doc/energy~~.~~html#references Gregg~~ and Smith (~~2010~~)]. Unlike other resources, the waste biomass supply curve is assumed to grow with GDP, as prescribed by the exogenous supply elasticity of GDP, or “gdpSupplyElast”. See GCAM's [https://jgcri.github.io/gcam-doc/supply_energy.html#biomass biomass] and [https://jgcri.github.io/gcam-doc/details_energy.html#biomass-liquids biomass liquids] sections for more details.		While most of the effort in modeling biomass supply is in the agriculture and land use component, there is a renewable resource represented in the energy system, that generally refers to municipal and industrial wastes that can be used for energy purposes. The supply curves use the same functional form as printed in the [https://jgcri.github.io/gcam-doc/supply_energy.html#wind wind section], and the specific quantities are documented in Gregg and Smith (2010).<ref>Gregg, J.S., and Smith, S.J. Global and regional potential for bioenergy from agricultural and forestry residue biomass. Mitigation and Adaptation Strategies for Global Change 15(3), pp 241-262.</ref> Unlike other resources, the waste biomass supply curve is assumed to grow with GDP, as prescribed by the exogenous supply elasticity of GDP, or “gdpSupplyElast”. See GCAM's [https://jgcri.github.io/gcam-doc/supply_energy.html#biomass biomass] and [https://jgcri.github.io/gcam-doc/details_energy.html#biomass-liquids biomass liquids] sections for more details.

	== Traditional biomass ==		== Traditional biomass ==
	Traditional biomass in GCAM is defined as the IEA’s “primary solid biomass” product consumed by the residential sector, in selected regions where it is considered to be an important part of the energy system. The largest consumers of traditional biomass in 2010 were China, India, and Western Africa. The specific energy goods involved include firewood, agricultural residues, animal dung, and others; no effort is made to disaggregate the category into these constituent parts, or to link the production volumes with the agriculture and land use module. See GCAM's [https://jgcri.github.io/gcam-doc/supply_energy.html#traditional-biomass traditional biomass] section.		Traditional biomass in GCAM is defined as the IEA’s “primary solid biomass” product consumed by the residential sector, in selected regions where it is considered to be an important part of the energy system. The largest consumers of traditional biomass in 2010 were China, India, and Western Africa. The specific energy goods involved include firewood, agricultural residues, animal dung, and others; no effort is made to disaggregate the category into these constituent parts, or to link the production volumes with the agriculture and land use module. See GCAM's [https://jgcri.github.io/gcam-doc/supply_energy.html#traditional-biomass traditional biomass] section.

Matthew Binsted at 18:03, 15 June 2022

2022-06-15T18:03:17Z

← Older revision		Revision as of 20:03, 15 June 2022
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	== Traditional biomass ==		== Traditional biomass ==
	Traditional biomass in GCAM is defined as the IEA’s “primary solid biomass” product consumed by the residential sector, in selected regions where it is considered to be an important part of the energy system. The largest consumers of traditional biomass in 2010 were China, India, and Western Africa. The specific energy goods involved include firewood, agricultural residues, animal dung, and others; no effort is made to disaggregate the category into these constituent parts, or to link the production volumes with the agriculture and land use module. See GCAM's [https://jgcri.github.io/gcam-doc/supply_energy.html#~~wtraditional~~-biomass traditional biomass] section.		Traditional biomass in GCAM is defined as the IEA’s “primary solid biomass” product consumed by the residential sector, in selected regions where it is considered to be an important part of the energy system. The largest consumers of traditional biomass in 2010 were China, India, and Western Africa. The specific energy goods involved include firewood, agricultural residues, animal dung, and others; no effort is made to disaggregate the category into these constituent parts, or to link the production volumes with the agriculture and land use module. See GCAM's [https://jgcri.github.io/gcam-doc/supply_energy.html#traditional-biomass traditional biomass] section.

Matthew Binsted at 18:02, 15 June 2022

2022-06-15T18:02:09Z

← Older revision		Revision as of 20:02, 15 June 2022
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	== Biomass ==		== Biomass ==
	While most of the effort in modeling biomass supply is in the agriculture and land use component, there is a renewable resource represented in the energy system, that generally refers to municipal and industrial wastes that can be used for energy purposes. The supply curves use the same functional form as printed in the [https://jgcri.github.io/gcam-doc/supply_energy.html#wind wind section], and the specific quantities are documented in [https://jgcri.github.io/gcam-doc/energy.html#references Gregg and Smith (2010)]. Unlike other resources, the waste biomass supply curve is assumed to grow with GDP, as prescribed by the exogenous supply elasticity of GDP, or “gdpSupplyElast”. See GCAM's https://jgcri.github.io/gcam-doc/supply_energy.html#biomass] and [https://jgcri.github.io/gcam-doc/details_energy.html#biomass-liquids biomass liquids] sections for more details.		While most of the effort in modeling biomass supply is in the agriculture and land use component, there is a renewable resource represented in the energy system, that generally refers to municipal and industrial wastes that can be used for energy purposes. The supply curves use the same functional form as printed in the [https://jgcri.github.io/gcam-doc/supply_energy.html#wind wind section], and the specific quantities are documented in [https://jgcri.github.io/gcam-doc/energy.html#references Gregg and Smith (2010)]. Unlike other resources, the waste biomass supply curve is assumed to grow with GDP, as prescribed by the exogenous supply elasticity of GDP, or “gdpSupplyElast”. See GCAM's [https://jgcri.github.io/gcam-doc/supply_energy.html#biomass biomass] and [https://jgcri.github.io/gcam-doc/details_energy.html#biomass-liquids biomass liquids] sections for more details.

	== Traditional biomass ==		== Traditional biomass ==
	Traditional biomass in GCAM is defined as the IEA’s “primary solid biomass” product consumed by the residential sector, in selected regions where it is considered to be an important part of the energy system. The largest consumers of traditional biomass in 2010 were China, India, and Western Africa. The specific energy goods involved include firewood, agricultural residues, animal dung, and others; no effort is made to disaggregate the category into these constituent parts, or to link the production volumes with the agriculture and land use module. See GCAM's [https://jgcri.github.io/gcam-doc/supply_energy.html#wtraditional-biomass traditional biomass] section.		Traditional biomass in GCAM is defined as the IEA’s “primary solid biomass” product consumed by the residential sector, in selected regions where it is considered to be an important part of the energy system. The largest consumers of traditional biomass in 2010 were China, India, and Western Africa. The specific energy goods involved include firewood, agricultural residues, animal dung, and others; no effort is made to disaggregate the category into these constituent parts, or to link the production volumes with the agriculture and land use module. See GCAM's [https://jgcri.github.io/gcam-doc/supply_energy.html#wtraditional-biomass traditional biomass] section.

Matthew Binsted at 18:01, 15 June 2022

2022-06-15T18:01:40Z

← Older revision		Revision as of 20:01, 15 June 2022
Line 5:		Line 5:

	== Biomass ==		== Biomass ==
	While most of the effort in modeling biomass supply is in the agriculture and land use component, there is a renewable resource represented in the energy system, that generally refers to municipal and industrial wastes that can be used for energy purposes. The supply curves use the same functional form as printed in the [~~http~~://jgcri.github.io/gcam-doc/~~energy~~.html#~~renewable-resources Wind~~ section], and the specific quantities are documented in [https://jgcri.github.io/gcam-doc/energy.html#references Gregg and Smith (2010)]. Unlike other resources, the waste biomass supply curve is assumed to grow with GDP, as prescribed by the exogenous supply elasticity of GDP, or “gdpSupplyElast”. See GCAM's [~~http~~://jgcri.github.io/gcam-doc/~~energy~~.html#biomass biomass] ~~section~~.		While most of the effort in modeling biomass supply is in the agriculture and land use component, there is a renewable resource represented in the energy system, that generally refers to municipal and industrial wastes that can be used for energy purposes. The supply curves use the same functional form as printed in the [https://jgcri.github.io/gcam-doc/supply_energy.html#wind wind section], and the specific quantities are documented in [https://jgcri.github.io/gcam-doc/energy.html#references Gregg and Smith (2010)]. Unlike other resources, the waste biomass supply curve is assumed to grow with GDP, as prescribed by the exogenous supply elasticity of GDP, or “gdpSupplyElast”. See GCAM's https://jgcri.github.io/gcam-doc/supply_energy.html#biomass] and [https://jgcri.github.io/gcam-doc/details_energy.html#biomass-liquids biomass liquids] sections for more details.

	== Traditional biomass ==		== Traditional biomass ==
	Traditional biomass in GCAM is defined as the IEA’s “primary solid biomass” product consumed by the residential sector, in selected regions where it is considered to be an important part of the energy system. The largest consumers of traditional biomass in 2010 were China, India, and Western Africa. The specific energy goods involved include firewood, agricultural residues, animal dung, and others; no effort is made to disaggregate the category into these constituent parts, or to link the production volumes with the agriculture and land use module. See GCAM's [~~http~~://jgcri.github.io/gcam-doc/~~energy~~.html#~~traditional~~-biomass traditional biomass] section.		Traditional biomass in GCAM is defined as the IEA’s “primary solid biomass” product consumed by the residential sector, in selected regions where it is considered to be an important part of the energy system. The largest consumers of traditional biomass in 2010 were China, India, and Western Africa. The specific energy goods involved include firewood, agricultural residues, animal dung, and others; no effort is made to disaggregate the category into these constituent parts, or to link the production volumes with the agriculture and land use module. See GCAM's [https://jgcri.github.io/gcam-doc/supply_energy.html#wtraditional-biomass traditional biomass] section.

Matthew Binsted at 13:34, 2 September 2020

2020-09-02T13:34:44Z

← Older revision		Revision as of 15:34, 2 September 2020
Line 5:		Line 5:

	== Biomass ==		== Biomass ==
	While most of the effort in modeling biomass supply is in the agriculture and land use component, there is a renewable resource represented in the energy system, that generally refers to municipal and industrial wastes that can be used for energy purposes. The supply curves use the same functional form as printed in the [http://jgcri.github.io/gcam-doc/energy.html#renewable-resources Wind section], and the specific quantities are documented in [https://jgcri.github.io/gcam-doc/energy.html#references Gregg and Smith (2010)]. Unlike other resources, the waste biomass supply curve is assumed to grow with GDP, as prescribed by the exogenous supply elasticity of GDP, or “gdpSupplyElast”. See GCAM's [http://jgcri.github.io/gcam-doc/energy.html#biomass biomass section].		While most of the effort in modeling biomass supply is in the agriculture and land use component, there is a renewable resource represented in the energy system, that generally refers to municipal and industrial wastes that can be used for energy purposes. The supply curves use the same functional form as printed in the [http://jgcri.github.io/gcam-doc/energy.html#renewable-resources Wind section], and the specific quantities are documented in [https://jgcri.github.io/gcam-doc/energy.html#references Gregg and Smith (2010)]. Unlike other resources, the waste biomass supply curve is assumed to grow with GDP, as prescribed by the exogenous supply elasticity of GDP, or “gdpSupplyElast”. See GCAM's [http://jgcri.github.io/gcam-doc/energy.html#biomass biomass] section.

	== Traditional biomass ==		== Traditional biomass ==
	Traditional biomass in GCAM is defined as the IEA’s “primary solid biomass” product consumed by the residential sector, in selected regions where it is considered to be an important part of the energy system. The largest consumers of traditional biomass in 2010 were China, India, and Western Africa. The specific energy goods involved include firewood, agricultural residues, animal dung, and others; no effort is made to disaggregate the category into these constituent parts, or to link the production volumes with the agriculture and land use module. See GCAM's [http://jgcri.github.io/gcam-doc/energy.html#traditional-biomass traditional biomass section].		Traditional biomass in GCAM is defined as the IEA’s “primary solid biomass” product consumed by the residential sector, in selected regions where it is considered to be an important part of the energy system. The largest consumers of traditional biomass in 2010 were China, India, and Western Africa. The specific energy goods involved include firewood, agricultural residues, animal dung, and others; no effort is made to disaggregate the category into these constituent parts, or to link the production volumes with the agriculture and land use module. See GCAM's [http://jgcri.github.io/gcam-doc/energy.html#traditional-biomass traditional biomass] section.

Matthew Binsted at 19:03, 1 September 2020

2020-09-01T19:03:05Z

← Older revision		Revision as of 21:03, 1 September 2020
Line 5:		Line 5:

	== Biomass ==		== Biomass ==
	While most of the effort in modeling biomass supply is in the agriculture and land use component, there is a renewable resource represented in the energy system, that generally refers to municipal and industrial wastes that can be used for energy purposes. The supply curves use the same functional form as printed in the [http://jgcri.github.io/gcam-doc/energy.html#renewable-resources Wind section], and the specific quantities are documented in Gregg and Smith (2010). Unlike other resources, the waste biomass supply curve is assumed to grow with GDP, as prescribed by the exogenous supply elasticity of GDP, or “gdpSupplyElast” [http://jgcri.github.io/gcam-doc/energy.html#biomass ~~<nowiki>[1]</nowiki>~~].		While most of the effort in modeling biomass supply is in the agriculture and land use component, there is a renewable resource represented in the energy system, that generally refers to municipal and industrial wastes that can be used for energy purposes. The supply curves use the same functional form as printed in the [http://jgcri.github.io/gcam-doc/energy.html#renewable-resources Wind section], and the specific quantities are documented in [https://jgcri.github.io/gcam-doc/energy.html#references Gregg and Smith (2010)]. Unlike other resources, the waste biomass supply curve is assumed to grow with GDP, as prescribed by the exogenous supply elasticity of GDP, or “gdpSupplyElast”. See GCAM's [http://jgcri.github.io/gcam-doc/energy.html#biomass biomass section].

	== Traditional biomass ==		== Traditional biomass ==
	Traditional biomass in GCAM is defined as the IEA’s “primary solid biomass” product consumed by the residential sector, in selected regions where it is considered to be an important part of the energy system. The largest consumers of traditional biomass in 2010 were China, India, and Western Africa. The specific energy goods involved include firewood, agricultural residues, animal dung, and others; no effort is made to disaggregate the category into these constituent parts, or to link the production volumes with the agriculture and land use module [http://jgcri.github.io/gcam-doc/energy.html#traditional-biomass ~~<nowiki>[2]</nowiki>].~~		Traditional biomass in GCAM is defined as the IEA’s “primary solid biomass” product consumed by the residential sector, in selected regions where it is considered to be an important part of the energy system. The largest consumers of traditional biomass in 2010 were China, India, and Western Africa. The specific energy goods involved include firewood, agricultural residues, animal dung, and others; no effort is made to disaggregate the category into these constituent parts, or to link the production volumes with the agriculture and land use module. See GCAM's [http://jgcri.github.io/gcam-doc/energy.html#traditional-biomass traditional biomass section].

	~~== References ==~~
	~~[Gregg and Smith 2010~~] ~~Gregg, J~~.S., and Smith, S.J. Global and regional potential for bioenergy from agricultural and forestry residue biomass. ''Mitigation and Adaptation Strategies for Global Change'' 15(3), pp 241-262. [https://link.springer.com/article/10.1007/s11027-010-9215-4 Link]

Matthew Binsted at 14:48, 25 August 2020

2020-08-25T14:48:29Z

← Older revision		Revision as of 16:48, 25 August 2020
Line 5:		Line 5:

	== Biomass ==		== Biomass ==
	While most of the effort in modeling biomass supply is in the agriculture and land use component, there is a renewable resource represented in the energy system, that generally refers to municipal and industrial wastes that can be used for energy purposes. The supply curves use the same functional form as printed in the [http://jgcri.github.io/gcam-doc/energy.html#renewable-resources Wind section], and the specific quantities are documented in Gregg and Smith (2010). Unlike other resources, the waste biomass supply curve is assumed to grow with GDP, as prescribed by the exogenous supply elasticity of GDP, or “gdpSupplyElast” [http://jgcri.github.io/gcam-doc/energy.html#~~renewable-resources~~ <nowiki>[1]</nowiki>].		While most of the effort in modeling biomass supply is in the agriculture and land use component, there is a renewable resource represented in the energy system, that generally refers to municipal and industrial wastes that can be used for energy purposes. The supply curves use the same functional form as printed in the [http://jgcri.github.io/gcam-doc/energy.html#renewable-resources Wind section], and the specific quantities are documented in Gregg and Smith (2010). Unlike other resources, the waste biomass supply curve is assumed to grow with GDP, as prescribed by the exogenous supply elasticity of GDP, or “gdpSupplyElast” [http://jgcri.github.io/gcam-doc/energy.html#biomass <nowiki>[1]</nowiki>].

	== Traditional biomass ==		== Traditional biomass ==
	Traditional biomass in GCAM is defined as the IEA’s “primary solid biomass” product consumed by the residential sector, in selected regions where it is considered to be an important part of the energy system. The largest consumers of traditional biomass in 2010 were China, India, and Western Africa. The specific energy goods involved include firewood, agricultural residues, animal dung, and others; no effort is made to disaggregate the category into these constituent parts, or to link the production volumes with the agriculture and land use module.		Traditional biomass in GCAM is defined as the IEA’s “primary solid biomass” product consumed by the residential sector, in selected regions where it is considered to be an important part of the energy system. The largest consumers of traditional biomass in 2010 were China, India, and Western Africa. The specific energy goods involved include firewood, agricultural residues, animal dung, and others; no effort is made to disaggregate the category into these constituent parts, or to link the production volumes with the agriculture and land use module [http://jgcri.github.io/gcam-doc/energy.html#traditional-biomass <nowiki>[2]</nowiki>].

	== References ==		== References ==
	[Gregg and Smith 2010] Gregg, J.S., and Smith, S.J. Global and regional potential for bioenergy from agricultural and forestry residue biomass. ''Mitigation and Adaptation Strategies for Global Change'' 15(3), pp 241-262. [https://link.springer.com/article/10.1007/s11027-010-9215-4 Link]		[Gregg and Smith 2010] Gregg, J.S., and Smith, S.J. Global and regional potential for bioenergy from agricultural and forestry residue biomass. ''Mitigation and Adaptation Strategies for Global Change'' 15(3), pp 241-262. [https://link.springer.com/article/10.1007/s11027-010-9215-4 Link]

Matthew Binsted at 15:53, 19 August 2020

2020-08-19T15:53:29Z

← Older revision		Revision as of 17:53, 19 August 2020
Line 3:		Line 3:
	\|DocumentationCategory=Bioenergy		\|DocumentationCategory=Bioenergy
	}}		}}

			== Biomass ==
			While most of the effort in modeling biomass supply is in the agriculture and land use component, there is a renewable resource represented in the energy system, that generally refers to municipal and industrial wastes that can be used for energy purposes. The supply curves use the same functional form as printed in the [http://jgcri.github.io/gcam-doc/energy.html#renewable-resources Wind section], and the specific quantities are documented in Gregg and Smith (2010). Unlike other resources, the waste biomass supply curve is assumed to grow with GDP, as prescribed by the exogenous supply elasticity of GDP, or “gdpSupplyElast” [http://jgcri.github.io/gcam-doc/energy.html#renewable-resources <nowiki>[1]</nowiki>].

			== Traditional biomass ==
			Traditional biomass in GCAM is defined as the IEA’s “primary solid biomass” product consumed by the residential sector, in selected regions where it is considered to be an important part of the energy system. The largest consumers of traditional biomass in 2010 were China, India, and Western Africa. The specific energy goods involved include firewood, agricultural residues, animal dung, and others; no effort is made to disaggregate the category into these constituent parts, or to link the production volumes with the agriculture and land use module.

			== References ==
			[Gregg and Smith 2010] Gregg, J.S., and Smith, S.J. Global and regional potential for bioenergy from agricultural and forestry residue biomass. ''Mitigation and Adaptation Strategies for Global Change'' 15(3), pp 241-262. [https://link.springer.com/article/10.1007/s11027-010-9215-4 Link]

Rineke Oostenrijk: Rineke Oostenrijk moved page Bioenergy - GAMS to Bioenergy - GCAM without leaving a redirect: Text replacement - "GAMS" to "GCAM"

2019-12-17T15:37:58Z

Rineke Oostenrijk moved page Bioenergy - GAMS to Bioenergy - GCAM without leaving a redirect: Text replacement - "GAMS" to "GCAM"

← Older revision

Revision as of 17:37, 17 December 2019

Rineke Oostenrijk: Text replacement - "GAMS" to "GCAM"

2019-12-17T15:37:44Z

Text replacement - "GAMS" to "GCAM"

← Older revision		Revision as of 17:37, 17 December 2019
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	{{ModelDocumentationTemplate		{{ModelDocumentationTemplate
	\|IsDocumentationOf=~~GAMS~~		\|IsDocumentationOf=GCAM
	\|DocumentationCategory=Bioenergy		\|DocumentationCategory=Bioenergy
	}}		}}