The effect of increasing lifespan and recycling rate on carbon storage in wood products from theoretical model to application for the European wood sector
The use of wood products is often promoted as a climate change mitigation option to reduce atmospheric carbon dioxide concentrations. In previous literature, we identified longevity and recycling rate as two determining factors that influence the carbon stock in wood products, but no studies have pr...
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| Vydáno v: | Mitigation and adaptation strategies for global change Ročník 22; číslo 8; s. 1193 - 1205 |
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| Médium: | Journal Article |
| Jazyk: | angličtina |
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Springer Netherlands
01.12.2017
Springer Nature B.V |
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| ISSN: | 1381-2386, 1573-1596, 1573-1596 |
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| Abstract | The use of wood products is often promoted as a climate change mitigation option to reduce atmospheric carbon dioxide concentrations. In previous literature, we identified longevity and recycling rate as two determining factors that influence the carbon stock in wood products, but no studies have predicted the effect of improved wood use on carbon storage over time. In this study, we aimed at evaluating changes in the lifespan and the recycling rate as two options for enhancing carbon stock in wood products for different time horizons. We first explored the behaviour over time of both factors in a theoretical simulation, and then calculated their effect for the European wood sector of the future. The theoretical simulation shows that the carbon stock in wood products increases linearly when increasing the average lifespan of wood products and exponentially when improving the recycling rate. The emissions savings under the current use of wood products in Europe in 2030 were estimated at 57.65 Mt carbon dioxide (CO
2
) per year. This amount could be increased 5 Mt CO
2
if average lifespan increased 19.54 % or if recycling rate increased 20.92 % in 2017. However, the combination of both strategies could increase the emissions saving almost 5 Mt CO
2
more by 2030. Incrementing recycling rate of paper and paperboard is the best short-term strategy (2030) to reduce emissions, but elongating average lifespan of wood-based panels is a better strategy for longer term periods (2046). |
|---|---|
| AbstractList | The use of wood products is often promoted as a climate change mitigation option to reduce atmospheric carbon dioxide concentrations. In previous literature, we identified longevity and recycling rate as two determining factors that influence the carbon stock in wood products, but no studies have predicted the effect of improved wood use on carbon storage over time. In this study, we aimed at evaluating changes in the lifespan and the recycling rate as two options for enhancing carbon stock in wood products for different time horizons. We first explored the behaviour over time of both factors in a theoretical simulation, and then calculated their effect for the European wood sector of the future. The theoretical simulation shows that the carbon stock in wood products increases linearly when increasing the average lifespan of wood products and exponentially when improving the recycling rate. The emissions savings under the current use of wood products in Europe in 2030 were estimated at 57.65 Mt carbon dioxide (CO2) per year. This amount could be increased 5 Mt CO2 if average lifespan increased 19.54 % or if recycling rate increased 20.92 % in 2017. However, the combination of both strategies could increase the emissions saving almost 5 Mt CO2 more by 2030. Incrementing recycling rate of paper and paperboard is the best short-term strategy (2030) to reduce emissions, but elongating average lifespan of wood-based panels is a better strategy for longer term periods (2046). The use of wood products is often promoted as a climate change mitigation option to reduce atmospheric carbon dioxide concentrations. In previous literature, we identified longevity and recycling rate as two determining factors that influence the carbon stock in wood products, but no studies have predicted the effect of improved wood use on carbon storage over time. In this study, we aimed at evaluating changes in the lifespan and the recycling rate as two options for enhancing carbon stock in wood products for different time horizons. We first explored the behaviour over time of both factors in a theoretical simulation, and then calculated their effect for the European wood sector of the future. The theoretical simulation shows that the carbon stock in wood products increases linearly when increasing the average lifespan of wood products and exponentially when improving the recycling rate. The emissions savings under the current use of wood products in Europe in 2030 were estimated at 57.65 Mt carbon dioxide (CO₂) per year. This amount could be increased 5 Mt CO₂ if average lifespan increased 19.54 % or if recycling rate increased 20.92 % in 2017. However, the combination of both strategies could increase the emissions saving almost 5 Mt CO₂ more by 2030. Incrementing recycling rate of paper and paperboard is the best short-term strategy (2030) to reduce emissions, but elongating average lifespan of wood-based panels is a better strategy for longer term periods (2046). The use of wood products is often promoted as a climate change mitigation option to reduce atmospheric carbon dioxide concentrations. In previous literature, we identified longevity and recycling rate as two determining factors that influence the carbon stock in wood products, but no studies have predicted the effect of improved wood use on carbon storage over time. In this study, we aimed at evaluating changes in the lifespan and the recycling rate as two options for enhancing carbon stock in wood products for different time horizons. We first explored the behaviour over time of both factors in a theoretical simulation, and then calculated their effect for the European wood sector of the future. The theoretical simulation shows that the carbon stock in wood products increases linearly when increasing the average lifespan of wood products and exponentially when improving the recycling rate. The emissions savings under the current use of wood products in Europe in 2030 were estimated at 57.65 Mt carbon dioxide (CO ) per year. This amount could be increased 5 Mt CO if average lifespan increased 19.54 % or if recycling rate increased 20.92 % in 2017. However, the combination of both strategies could increase the emissions saving almost 5 Mt CO more by 2030. Incrementing recycling rate of paper and paperboard is the best short-term strategy (2030) to reduce emissions, but elongating average lifespan of wood-based panels is a better strategy for longer term periods (2046). The use of wood products is often promoted as a climate change mitigation option to reduce atmospheric carbon dioxide concentrations. In previous literature, we identified longevity and recycling rate as two determining factors that influence the carbon stock in wood products, but no studies have predicted the effect of improved wood use on carbon storage over time. In this study, we aimed at evaluating changes in the lifespan and the recycling rate as two options for enhancing carbon stock in wood products for different time horizons. We first explored the behaviour over time of both factors in a theoretical simulation, and then calculated their effect for the European wood sector of the future. The theoretical simulation shows that the carbon stock in wood products increases linearly when increasing the average lifespan of wood products and exponentially when improving the recycling rate. The emissions savings under the current use of wood products in Europe in 2030 were estimated at 57.65 Mt carbon dioxide (CO 2 ) per year. This amount could be increased 5 Mt CO 2 if average lifespan increased 19.54 % or if recycling rate increased 20.92 % in 2017. However, the combination of both strategies could increase the emissions saving almost 5 Mt CO 2 more by 2030. Incrementing recycling rate of paper and paperboard is the best short-term strategy (2030) to reduce emissions, but elongating average lifespan of wood-based panels is a better strategy for longer term periods (2046). The use of wood products is often promoted as a climate change mitigation option to reduce atmospheric carbon dioxide concentrations. In previous literature, we identified longevity and recycling rate as two determining factors that influence the carbon stock in wood products, but no studies have predicted the effect of improved wood use on carbon storage over time. In this study, we aimed at evaluating changes in the lifespan and the recycling rate as two options for enhancing carbon stock in wood products for different time horizons. We first explored the behaviour over time of both factors in a theoretical simulation, and then calculated their effect for the European wood sector of the future. The theoretical simulation shows that the carbon stock in wood products increases linearly when increasing the average lifespan of wood products and exponentially when improving the recycling rate. The emissions savings under the current use of wood products in Europe in 2030 were estimated at 57.65 Mt carbon dioxide (CO2) per year. This amount could be increased 5 Mt CO2 if average lifespan increased 19.54 % or if recycling rate increased 20.92 % in 2017. However, the combination of both strategies could increase the emissions saving almost 5 Mt CO2 more by 2030. Incrementing recycling rate of paper and paperboard is the best short-term strategy (2030) to reduce emissions, but elongating average lifespan of wood-based panels is a better strategy for longer term periods (2046).The use of wood products is often promoted as a climate change mitigation option to reduce atmospheric carbon dioxide concentrations. In previous literature, we identified longevity and recycling rate as two determining factors that influence the carbon stock in wood products, but no studies have predicted the effect of improved wood use on carbon storage over time. In this study, we aimed at evaluating changes in the lifespan and the recycling rate as two options for enhancing carbon stock in wood products for different time horizons. We first explored the behaviour over time of both factors in a theoretical simulation, and then calculated their effect for the European wood sector of the future. The theoretical simulation shows that the carbon stock in wood products increases linearly when increasing the average lifespan of wood products and exponentially when improving the recycling rate. The emissions savings under the current use of wood products in Europe in 2030 were estimated at 57.65 Mt carbon dioxide (CO2) per year. This amount could be increased 5 Mt CO2 if average lifespan increased 19.54 % or if recycling rate increased 20.92 % in 2017. However, the combination of both strategies could increase the emissions saving almost 5 Mt CO2 more by 2030. Incrementing recycling rate of paper and paperboard is the best short-term strategy (2030) to reduce emissions, but elongating average lifespan of wood-based panels is a better strategy for longer term periods (2046). The use of wood products is often promoted as a climate change mitigation option to reduce atmospheric carbon dioxide concentrations. In previous literature, we identified longevity and recycling rate as two determining factors that influence the carbon stock in wood products, but no studies have predicted the effect of improved wood use on carbon storage over time. In this study, we aimed at evaluating changes in the lifespan and the recycling rate as two options for enhancing carbon stock in wood products for different time horizons. We first explored the behaviour over time of both factors in a theoretical simulation, and then calculated their effect for the European wood sector of the future. The theoretical simulation shows that the carbon stock in wood products increases linearly when increasing the average lifespan of wood products and exponentially when improving the recycling rate. The emissions savings under the current use of wood products in Europe in 2030 were estimated at 57.65 Mt carbon dioxide (CO2) per year. This amount could be increased 5 Mt CO2 if average lifespan increased 19.54 % or if recycling rate increased 20.92 % in 2017. However, the combination of both strategies could increase the emissions saving almost 5 Mt CO2 more by 2030. Incrementing recycling rate of paper and paperboard is the best short-term strategy (2030) to reduce emissions, but elongating average lifespan of wood-based panels is a better strategy for longer term periods (2046). |
| Author | Jochheim, Hubert Brunet-Navarro, Pau Muys, Bart |
| Author_xml | – sequence: 1 givenname: Pau orcidid: 0000-0001-9615-4810 surname: Brunet-Navarro fullname: Brunet-Navarro, Pau email: Pau.Brunet@zalf.de organization: Leibniz Centre for Agricultural Landscape Research (ZALF), Institute of Landscape Systems Analysis, Division Forest, Nature and Landscape, University of Leuven – sequence: 2 givenname: Hubert surname: Jochheim fullname: Jochheim, Hubert organization: Leibniz Centre for Agricultural Landscape Research (ZALF), Institute of Landscape Systems Analysis – sequence: 3 givenname: Bart surname: Muys fullname: Muys, Bart organization: Division Forest, Nature and Landscape, University of Leuven |
| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/30093824$$D View this record in MEDLINE/PubMed |
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HarmonMEHarmonJMFerrellWKModeling carbon stores in Oregon and Washington forest products: 1900-1992Clim Chang199633452155010.1007/BF00141703 KarjalainenTKellomakiSPussinenARole of wood-based products in absorbing atmospheric carbonSilva Fenn1994282678010.14214/sf.a9163 SkogKESequestration of carbon in harvested wood products for the United StatesFor Prod J20085865672 Brunet-NavarroPJochheimHMuysBModelling carbon stocks and fluxes in the wood product sector: a comparative reviewGlob Chang Biol20162272555256910.1111/gcb.13235 Barredo JI, San Miguel J, Caudullo G et al (2012) A European map of living forest biomass and carbon stock. Ispra, Italy, p. 16. 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WernerFTavernaRHoferPNational and global greenhouse gas dynamics of different forest management and wood use scenarios: a model-based assessmentEnviron Sci Pol2010131728510.1016/j.envsci.2009.10.004 MarlandEMarlandGThe treatment of long-lived, carbon-containing products in inventories of carbon dioxide emissions to the atmosphereEnviron Sci Pol20036213915210.1016/S1462-9011(03)00003-0 Höglmeier K, Steubing B, Weber-Blaschke G et al (2015) LCA-based optimization of wood utilization under special consideration of a cascading use of wood. J Environ Manag 152(0):158-170. KleinDHöllerlSBlaschkeMThe contribution of managed and unmanaged forests to climate change mitigation—a model approach at stand level for the main tree species in BavariaForests201341436910.3390/f4010043 Mantau U, Saal U (2010) Material use. p. 19–34. Hamburg, Germany. MullerDBBaderH-PBacciniPLong-term coordination of timber production and consumption using a dynamic material and energy flow analysisJ Ind Ecol200483658710.1162/1088198042442342 M Garcia (9722_CR8) 2010; 114 D Klein (9722_CR16) 2013; 4 T Karjalainen (9722_CR15) 2003; 5 JK Winjum (9722_CR35) 1998; 44 K Höglmeier (9722_CR10) 2014; 19 KE Skog (9722_CR29) 2008; 58 G Kohlmaier (9722_CR18) 2007; 126 9722_CR30 DB Muller (9722_CR25) 2004; 8 9722_CR12 9722_CR11 9722_CR13 9722_CR17 ES Marland (9722_CR23) 2010; 15 9722_CR1 T Karjalainen (9722_CR14) 1994; 28 9722_CR19 9722_CR4 RM Waterworth (9722_CR31) 2008; 255 ME Harmon (9722_CR9) 1996; 33 M Wiesmeier (9722_CR34) 2012; 18 9722_CR6 RC Dewar (9722_CR3) 1992; 11 E Marland (9722_CR22) 2003; 6 J Mason Earles (9722_CR24) 2012; 2 P Brunet-Navarro (9722_CR2) 2016; 22 9722_CR21 F Werner (9722_CR32) 2006; 74 9722_CR20 F Werner (9722_CR33) 2010; 13 9722_CR27 9722_CR26 9722_CR28 M Fortin (9722_CR7) 2012; 279 E Eriksson (9722_CR5) 2007; 37 26097501 - Carbon Balance Manag. 2015 Jun 12;10:13 26824792 - Glob Chang Biol. 2016 Jul;22(7):2555-69 25660355 - J Environ Manage. 2015 Apr 1;152:158-70 26457115 - Carbon Balance Manag. 2015 Feb 25;10(1):6 14969967 - Tree Physiol. 1992 Jul;11(1):49-71 |
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Cambridge University Press, Cambridge and New York, pp. 1–29 – reference: Schelhaas MJ, van Esch PW, Groen TA et al (2004) CO2FIX V 3.1—a modelling framework for quantifying carbon sequestration in forest ecosystems. p. 122. 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| SubjectTerms | Atmospheric Sciences Carbon capture and storage Carbon dioxide Carbon sequestration carbon sinks Climate change Climate Change Management and Policy Climate change mitigation Computer simulation Earth and Environmental Science Earth Sciences Elongation Emissions Emissions control Environmental Management Europe Life span Longevity Mitigation Original Original Article Paper board paperboard Product life cycle Products Recycling Simulation Wood Wood products wood-based panels |
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| Title | The effect of increasing lifespan and recycling rate on carbon storage in wood products from theoretical model to application for the European wood sector |
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