Solar energy conserved in biomass: sustainable bioenergy use and reduction of land use change

Niclas Scott Bentsen; Ian Max Møller

doi:10.1016/j.rser.2016.12.124

Solar energy conserved in biomass: sustainable bioenergy use and reduction of land use change

Niclas Scott Bentsen, Ian Max Møller

Forest, Nature and Biomass

14 Citations (Scopus)

Abstract

Climate change mitigation requires a shift from fossil energy resources to renewables, and bioenergy crops are considered one of the major potential resources. At the same time future energy supplies are expected to be sustainable, but the sustainability of energy crop production is challenged by concerns over its potential competition for arable land and disruption of food and feed markets. Protein in plant biomass is a challenge for sustainability, but also an opportunity. The challenge with protein is a disproportionately large land use foot print associated with its biosynthesis. Bioenergy exploits solar energy temporarily stored in biomass compounds such as carbohydrate, lipid, lignin, protein and organic acids. Here we review energy cost estimates for photosynthesis and growth and maintenance respiration and show – by comparing energy costs with the amount of energy stored in different plant compounds – that protein conservation could improve the sustainability of energy crop production by reducing land use impacts. The opportunity with protein in plant biomass comes from the fact that favored energy crops like switch grass, reed grass and Miscanthus are excellent protein producers on par with soybean and other protein-rich crops. Due to the scale of potential future bioenergy deployment we find that energy strategies involving large amounts of herbaceous energy crops will not be sustainable unless the proteins are conserved in some way.

Original language	English
Journal	Renewable & Sustainable Energy Reviews
Volume	71
Pages (from-to)	954-958
Number of pages	5
ISSN	1364-0321
DOIs	https://doi.org/10.1016/j.rser.2016.12.124
Publication status	Published - May 2017

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10.1016/j.rser.2016.12.124

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title = "Solar energy conserved in biomass: sustainable bioenergy use and reduction of land use change",

abstract = "Climate change mitigation requires a shift from fossil energy resources to renewables, and bioenergy crops are considered one of the major potential resources. At the same time future energy supplies are expected to be sustainable, but the sustainability of energy crop production is challenged by concerns over its potential competition for arable land and disruption of food and feed markets. Protein in plant biomass is a challenge for sustainability, but also an opportunity. The challenge with protein is a disproportionately large land use foot print associated with its biosynthesis. Bioenergy exploits solar energy temporarily stored in biomass compounds such as carbohydrate, lipid, lignin, protein and organic acids. Here we review energy cost estimates for photosynthesis and growth and maintenance respiration and show – by comparing energy costs with the amount of energy stored in different plant compounds – that protein conservation could improve the sustainability of energy crop production by reducing land use impacts. The opportunity with protein in plant biomass comes from the fact that favored energy crops like switch grass, reed grass and Miscanthus are excellent protein producers on par with soybean and other protein-rich crops. Due to the scale of potential future bioenergy deployment we find that energy strategies involving large amounts of herbaceous energy crops will not be sustainable unless the proteins are conserved in some way.",

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T1 - Solar energy conserved in biomass

T2 - sustainable bioenergy use and reduction of land use change

AU - Bentsen, Niclas Scott

AU - Møller, Ian Max

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Y1 - 2017/5

N2 - Climate change mitigation requires a shift from fossil energy resources to renewables, and bioenergy crops are considered one of the major potential resources. At the same time future energy supplies are expected to be sustainable, but the sustainability of energy crop production is challenged by concerns over its potential competition for arable land and disruption of food and feed markets. Protein in plant biomass is a challenge for sustainability, but also an opportunity. The challenge with protein is a disproportionately large land use foot print associated with its biosynthesis. Bioenergy exploits solar energy temporarily stored in biomass compounds such as carbohydrate, lipid, lignin, protein and organic acids. Here we review energy cost estimates for photosynthesis and growth and maintenance respiration and show – by comparing energy costs with the amount of energy stored in different plant compounds – that protein conservation could improve the sustainability of energy crop production by reducing land use impacts. The opportunity with protein in plant biomass comes from the fact that favored energy crops like switch grass, reed grass and Miscanthus are excellent protein producers on par with soybean and other protein-rich crops. Due to the scale of potential future bioenergy deployment we find that energy strategies involving large amounts of herbaceous energy crops will not be sustainable unless the proteins are conserved in some way.

AB - Climate change mitigation requires a shift from fossil energy resources to renewables, and bioenergy crops are considered one of the major potential resources. At the same time future energy supplies are expected to be sustainable, but the sustainability of energy crop production is challenged by concerns over its potential competition for arable land and disruption of food and feed markets. Protein in plant biomass is a challenge for sustainability, but also an opportunity. The challenge with protein is a disproportionately large land use foot print associated with its biosynthesis. Bioenergy exploits solar energy temporarily stored in biomass compounds such as carbohydrate, lipid, lignin, protein and organic acids. Here we review energy cost estimates for photosynthesis and growth and maintenance respiration and show – by comparing energy costs with the amount of energy stored in different plant compounds – that protein conservation could improve the sustainability of energy crop production by reducing land use impacts. The opportunity with protein in plant biomass comes from the fact that favored energy crops like switch grass, reed grass and Miscanthus are excellent protein producers on par with soybean and other protein-rich crops. Due to the scale of potential future bioenergy deployment we find that energy strategies involving large amounts of herbaceous energy crops will not be sustainable unless the proteins are conserved in some way.

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DO - 10.1016/j.rser.2016.12.124

M3 - Journal article

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EP - 958

JO - Renewable & Sustainable Energy Reviews

JF - Renewable & Sustainable Energy Reviews

ER -

Solar energy conserved in biomass: sustainable bioenergy use and reduction of land use change

Abstract

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