Top

The International Journal of Life Cycle Assessment

Published in:

15-10-2020 | CRITICAL REVIEW

Reviewing environmental life cycle impacts of biobased polymers: current trends and methodological challenges

Authors: Diana Ita-Nagy, Ian Vázquez-Rowe, Ramzy Kahhat, Gary Chinga-Carrasco, Isabel Quispe

Published in: The International Journal of Life Cycle Assessment | Issue 11/2020

Activate our intelligent search to find suitable subject content or patents.

search-config

AI-assisted search

Off

Abstract

Purpose

The aim of this review is to evaluate previous life cycle assessment (LCA) studies of first- and second-generation bioplastics, to understand the state of the art and the main problems addressed during the development of new bioplastics. Furthermore, it provides an overview on land use change (LUC) impacts accounted for, methodologies chosen, and the results obtained.

Methods

Studies related to the impact assessment of bioplastics and published between 2007 and 2018 were gathered. Five keyword strings were used to perform a wide search and select relevant LCA studies. The study aimed to analyze critical methodological aspects in LCA, in order to determine the most common choices made during biobased material analyses, as well as major limitations. Three filters were applied to select comparable studies, ending with a final number of 17 papers. Recommendations were obtained by comparing common practices performed by different authors with suggested best available practices mentioned in handbooks and guidelines. Interestingly, LUC metrics and impacts were, most of the time, neglected. Thus, a specific assessment and discussion was performed regarding the methods used to quantify LUC impacts, considering its importance during the production of biobased materials.

Results and discussion

The study discussed the main environmental problems linked to the development of new biomaterials. LCA of agricultural products or systems, when compared with fossil-based counterparts, is expected to show higher environmental impacts in categories directly affected by fertilizer use, occupied and transformed land, among others. Thus, studies that included additional impact categories besides global warming (e.g., eutrophication or acidification) concluded that biobased materials present higher impacts, recommending improvements in farming practices to improve their overall environmental profile. Moreover, this review gathered methodologies used to account for LUC impacts and the results obtained. The main constraint of including LUC impacts was the lack of a standardized methodology, as well as large uncertainties in existing methodologies.

Conclusions

Most studies concluded that improvements in farming practices might reduce the attributed environmental impacts with the reduction of the amount of land, fertilizer, pesticides, and water used. Studies computing LUC impacts agreed on the importance of including these impacts and concluded that greenhouse gas emissions of bioplastic production would increase, but in most cases would still be lower than the impact of their fossil-based counterparts. However, challenges remain when computing LUC impacts that need to be tackled when working with the available methodologies, including the collection of reliable inventory data (site-specific or regional data) and regionalized characterization factors.

previous article Ways to get work done: a review and systematisation of simplification practices in the LCA literature

next article A life cycle environmental sustainability analysis of microbial protein production via power-to-food approaches

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

inform now

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

inform now

Abdullah SA, Hezri AA (2008) From Forest Landscape to Agricultural Landscape in the Developing Tropical Country of Malaysia: Pattern, Process, and Their Significance on Policy. Environ Manage 42:907–917

Bare JC, Hofstetter P, Pennington D, Udo de Haes HA (2000) Midpoints versus endpoints: the sacrifices and benefits. Int J Life Cycle Assess 5(6):319–326

Beck T, Bos U, Wittstock B, Baitz M, Fischer M, Sedlbauer K (2010) LANCA—land use indicator value calculation in life cycle assessment. Fraunhofer-Stuttgart, Germany. http://publica.fraunhofer.de/eprints/urn_nbn_de_0011-n-1435418.pdf. Accessed 20 June 2018.

Bos U, Horn R (2018) Documentation of Land Use Inventory in GaBi. Version 1.0. http://www.gabi-software.com/fileadmin/Documents/Land_use__LANCA__in_GaBi_V1.0.pdf. Accessed 10 January 2019

Bos U, Horn R, Beck T, Lindner JP, Fischer M (2016a) LANCA®—Characterization Factors for Life Cycle Impact Assessment, Version 2.0. Fraunhofer Verlag, Stuttgart. ISBN 978-3-8396-0953-8.

Bos U, Horn R, Maier S, Beck T (2016b) LANCA®—Characterization Factors for Life Cycle Impact Assessment, Version 2.3. November 2016. http://ibpgabi.de/files/lanca_characterisation_factors_v2-3.pdf. Accessed 15 February 2019

Brandão M (2012) Food, feed, fuel, timber or carbon sink?: Towards sustainable land-use systems: A consequential life cycle approach (Doctoral dissertation, University of Surrey).

Brando P, Trumbore S, Silvério D, Macedo M, Beck P, Coe M (2016) Climate impacts of expanded soy agriculture in the arc of deforestation in Brazil. EGU General Assembly 2016, held 17-22 April, 2016 in Vienna Austria. http://meetingorganizer.copernicus.org/EGU2016/EGU2016-10631-1.pdf. Accessed 20 June 2018

Brodin M, Vallejos M, Opedal MT, Area MC, Chinga-Carrasco G (2017) Lignocellulosics as sustainable resources for production of bioplastics–A review. J Clean Prod 162:646–664

California Environmental Protection Agency (CalEPA) (2009) Proposed regulation to implement the low carbon fuel standard, volume I, Staff report: Initial statement of reasons. Sacramento: California EPA Air Resource Board. https://www.arb.ca.gov/fuels/lcfs/030409lcfs_isor_vol1.pdf. Accessed 25 June 2018

Chen L, Pelton REO, Smith TM (2016) Comparative life cycle assessment of fossil and bio-based polyethylene terephthalate (PET) bottles. J Clean Prod 137:667–676

Cherubini F, Fuglestvedt J, Gasser T, Reisinger A, Cavalett O, Huijbregts MAJ, Johansson DJA, Jørgensen SV, Raugei M, Schivley G, Strømman AH, Tanaka K, Levasseur A (2016) Bridging the gap between impact assessment methods and climate science. Environ Sci Pol 64:129–140

Ciroth A, Muller S, Weidema B, Lesage P (2016) Empirically based uncertainty factors for the pedigree matrix in ecoinvent. Int J Life Cycle Assess 21(9):1338–1348

Cole-Hunter T, Johnston FH, Marks GB, Morawska L, Morgan GG, Overs M, Porta-Cubas A, Cowie CT (2020) The health impacts of Waste-to-Energy emissions: A systematic review of the literature. Environmental Research Letters.

Cullen J (2017) Circular economy: theoretical benchmark or perpetual motion machine? J Ind Ecol 21(3):483–486

Curran M (2014) Strengths and limitations of life cycle assessment. In: Klöpffer W (ed) Background and future prospects in life cycle assessment, LCA compendium—The complete world of life cycle assessment. Springer, Dordrecht, pp. 189-206.

Curran M, Maia de Souza D, Antón A, Teixeira R, Michelsen O, Vidal-Legaz B, Sala S, Milà i Canals L (2016) How well does LCA model land use impacts on biodiversity? A comparison with approaches from ecology and conservation. Environ Sci Technol 50(6):2782–2795

De Laurentiis V, Secchi M, Bos U, Horn R, Laurent A, Sala S (2019) Soil quality index: Exploring options for a comprehensive assessment of land use impacts in LCA. J Clean Prod 215:63–74

de Léis CM, Nogueira AR, Kulay L, Tadini CC (2016) Environmental and energy analysis of biopolymer film based on cassava starch in Brazil. J Clean Prod 143:76–89

De Rosa M (2018) Land Use and Land-use Changes in Life Cycle Assessment: Green Modelling or Black Boxing? Ecological Economics 144(2018):73–81

De Rosa M, Knudsen MT, Hermansen JE (2016) A comparison of Land Use Change models: challenges and future developments. J Clean Prod 113(2016):183–193

Deng Y, Achten WM, Van Acker K, Duflou JR (2013) Life cycle assessment of wheat gluten powder and derived packaging film. Biofuels, Bioprod Bioref 7:429–458

Doka G, Hillier W, Kaila S, Köllner T, Kreißig J, Muys B, Quijano JG, Salpakivi-Salomaa P, Schweinle J, Swan G, Wessman H (2002) The assessment of environmental impacts caused by land-use in the life cycle assessment of forestry and forest products. Final Report of Working Group 2 “Land-use” of COST Action E9. http://www.doka.ch/COSTE9LandUseDoka.pdf. Accessed 23 October 2018

EC-JRC (2010) ILCD Handbook. Analysis of existing environmental impact assessment for use in life cycle assessment. http://eplca.jrc.ec.europa.eu/?page_id=86. Accessed 14 February 2018

EC-JRC (2011) ILCD Handbook. Recommendations for life cycle impact assessment in the European context—First Edition. http://eplca.jrc.ec.europa.eu/?page_id=86. Accessed 14 February 2018

Escobar N, Haddad S, Börner J, Britz W (2018) Land use mediated GHG emissions and spillovers from increased consumption of bioplastics. Environ Res Lett 13:125005

EU Commission (2015) Closing the loop – An EU action plan for the circular economy. https://ec.europa.eu/transparency/regdoc/rep/1/2015/EN/1-2015-614-EN-F1-1.PDF. Accessed 24 June 2018

Fargione J, Hill J, Tilman D, Polasky S, Hawthorne P (2008) Land Clearing and the Biofuel Carbon Debt. Science 319:1235–1238

Filgueira D, Holmen S, Melbø JK, Moldes D, Echtermeyer AT, Chinga-Carrasco G (2018) 3D Printable Filaments made of Biobased Polyethylene Biocomposites. Polymers 10:314

Guinée JB, Gorrée M, Heijungs R, Huppes G, Kleijn R, de Koning A, van Oers L, Wegener Sleeswijk A, Suh S, Udo de Haes HA, de Bruijn JA, van Duin R, Huijbregts MAJ (2002) Handbook on life cycle assessment: operational guide to the ISO standards. Eco-efficiency in Industry and Science. Kluwer Academic Publishers, Dordrecht, Series

Guo M, Murphy RJ (2012) LCA data quality: Sensitivity and uncertainty analysis. Sci Total Environ 435-436:230–243

Harding KG, Dennis JS, Blottnitz H, Harrison ST (2007) Environmental analysis of plastic production processes: Comparing petroleum-based polypropylene and polyethylene with biologically-based poly-beta-hydroxybutyric acid using life cycle analysis. J Biotechnol 130:57–66

Hauschild MZ, Goedkoop M, Guinée JB, Heijungs R, Huijbregts MAJ, Jolliet O, Margni M, De Schryver A, Humbert S, Laurent A, Sala S, Pant R (2013) Identifying best existing practice for characterization modeling in life cycle impact assessment. Int J Life Cycle Assess 18:683–697

Hermann BG, Blok K, Patel MK (2010) Twisting biomaterials around your little finger: environmental impacts of bio-based wrappings. Int J Life Cycle Assess 15(4):346–358

Hermansson F, Janssen M, Gellerstedt F (2015) Environmental evaluation of Durapulp bio-composite using LCA—Comparison of two different applications. Journal of Science and Technology for Forest Products and Processes 5(2):68–76

Hischier R, Weidema B, Althaus HJ, Bauer C, Doka G, Dones R, Frischknecht R, Hellweg S, Humbert S, Jungbluth N, Köllner T, Loerincik Y, Margni M, Nemecek T (2010) Implementation of life cycle impact assessment methods. Ecoinvent report No. 3, v2.2. Swiss Centre for Life Cycle Inventories, Dübendorf. http://esu-services.ch/fileadmin/download/publicLCI/03_LCIA-Implementation.pdf. Accessed 03 march 2018.

Hoornweg D, Bhada-Tata P (2012) What a waste: A global review of solid waste management. World Bank 15. http://siteresources.worldbank.org/INTURBANDEVELOPMENT/Resources/336387-1334852610766/What_a_Waste2012_Final.pdf. Accessed 15 February 2018

Hopewell J, Dvorak R, Kosior E (2009) Plastics recycling: challenges and opportunities. Philos Trans R Soc Lond B Biol Sci. 364(1526):2115–2126

Horn R, Maier S (2018) LANCA®- characterization factors for life cycle impact assessment, Version 2.5. November 2018. http://publica.fraunhofer.de/documents/N-379310.html. Accessed 10 February 2019.

Hottle TA, Bilec MM, Landis AE (2013) Sustainability assessments of bio-based polymers. Polym Degrad Stab 98(9):1898–1907

Huijbregts MAJ, Steinmann ZJN, Elshout PMF, Stam G, Verones F, Vieira M, Zijp M, Hollander A, van Zelm R (2017) ReCiPe2016: a harmonised life cycle impact assessment method at midpoint and endpoint level. Int J Life Cycle Assess 22:138–147

IfBB (2016) Biopolymers—Facts and Statistics. https://www.ifbb-hannover.de/files/IfBB/downloads/faltblaetter&broschueren/Biopolymers-Facts-Statistics_2016.pdf. Accessed 15 February 2018.

IPCC (2006) Guidelines for national greenhouse gas inventories, in Agriculture, forestry and other land use volume 4. http://www.ipcc-nggip.iges.or.jp/public/2006gl/vol4.html. Accessed 22 February 2018

IPCC (2012) Special report on renewable energy sources and climate change mitigation. https://www.ipcc.ch/pdf/special-reports/srren/SRREN_FD_SPM_final.pdf. Accessed 22 February 2018.

ISO (International Organization for Standardization) (2013) ISO 14067. Greenhouse gases—Carbon footprint of products—Requirements and guidelines for quantification and communication.

Jolliet O, Antón A, Boulay AM, Cherubini F, Fantke P, Levasseur A, McKone TE, Michelsen O, Milà i Canals L, Motoshita M, Pfister S, Verones F, Vigon B, Frischknecht R (2018) Global guidance on environmental life cycle impact assessment indicators: impacts of climate change, fine particulate matter formation, water consumption and land use. Int J Life Cycle Assess 23:2189–2207

Khoo HH, Tan RBH (2010) Environmental impacts of conventional plastic and bio-based carrier bags: Part 2: End-of-life options. Int J Life Cycle Assess 15:338–345

Khoo HH, Tan RBH, Chng KWL (2010) Environmental impacts of conventional plastic and bio-based carrier bags - Part 1: Life Cycle Production. Int J Life Cycle Assess 15(3):284–293

Kikuchi Y, Hirao M, Narita K, Sugiyama E, Oliveira S, Chapman S, Arakaki MM, Cappra CM (2013) Environmental Performance of Biomass-Derived Chemical Production: A Case Study on Sugarcane-Derived Polyethylene. J Chem Eng Jpn 46(4):319–325

Kløverpris JH, Mueller S (2013) Baseline time accounting: considering global land use dynamics when estimating the climate impact of indirect land use change caused by biofuels. Int J Life Cycle Assess 18(2):319–330

Koellner T, Scholz RW (2007) Assessment of land use impacts on the natural environment. Part 1: an analytical framework for pure land occupation and land use change. Int J Life Cycle Assess 12:16–23

Koellner T, de Baan L, Beck T, Brandão M, Civit B, Margni M, Milà i Canals L, Saad R, Souza D, Muller-Wenk R (2013) UNEP-SETAC guideline on global land use impact assessment on biodiversity and ecosystem services in LCA. Int J Life Cycle Assess 18:1188–1202

Larrea-Gallegos G, Vázquez-Rowe I, Wiener H, Kahhat R (2019) Applying the Technology Choice Model in Consequential Life Cycle Assessment: A Case Study in the Peruvian Agricultural Sector. J Ind Ecol 23(3):601–614

Lebreton LCM, Van der Zwet J, Damsteeg JW, Slat B, Andrady A, Reisser J (2017) River plastic emissions to the world’s oceans. Nature Comm 8:1561

Leejarkpai T, Mungcharoen T, Suwanmanee U (2016) Comparative assessment of global warming impact and eco-efficiency of PS (polystyrene), PET (polyethylene terephthalate) and PLA (polylactic acid) boxes. J Clean Prod 125:95–107

Liptow C, Tillman AM (2012) A Comparative Life Cycle Assessment Study of Polyethylene Based on Sugarcane and Crude Oil. J Ind Ecol 16(3):420–435

Macedo IC, Verde Leal MR, Ramos da Silva JE (2004) Assessment of greenhouse gas emissions in the production and use of fuel ethanol in Brazil. Sao Paulo, Brazil: Secretariat of the Environment, Government of the State of Sao Paulo. https://www.wilsoncenter.org/sites/default/files/brazil.unicamp.macedo.greenhousegas.pdf. Accessed 15 May 2018.

Madival S, Auras R, Singh SP, Narayan R (2009) Assessment of the environmental profile of PLA, PET and PS clamshell containers using LCA methodology. J Clean Prod 17(13):1183–1194

Margallo M, Ziegler-Rodriguez K, Vázquez-Rowe I, Aldaco R, Irabien Á, Kahhat R (2019) Enhancing waste management strategies in Latin America under a holistic environmental assessment perspective: A review for policy support. Sci Total Environ 689:1255–1275

Mattila T, Helin T, Antikainen R (2012) Land use indicators in life cycle assessment—a case study on beer production. Int J Life Cycle Assess 17:277–286

Milà i Canals L, Romanyà J, Cowell SJ (2006) Method for assessing impacts on life support functions (LSF) related to the use of “fertile land” in life cycle assessment (LCA). J Clean Prod 15:1426–1440

Milà i Canals L, Bauer C, Depestele J, Dubreuil A, Knuchel RF, Gaillard G, Michelsen O, Müller-Wenk R, Rydgren B (2007) Key elements in a framework for land use impact assessment within LCA. Int J Life Cycle Assess 12(1):2–4

MIT (2007) Units and conversion fact sheet, Derek supple, MIT Energy Club. https://web.mit.edu/mit_energy. Accessed 01 June 2018.

Muñoz I, Flury K, Jungbluth N, Rigarlsford G, Milà i Canals L, King H (2014) Life cycle assessment of bio-based ethanol produced from different agricultural feedstocks. Int J Life Cycle Assess 19(1):109–119

Nordborg M, Sasu-Boakye Y, Cederberg C, Berndes G (2017) Challenges in developing regionalized characterization factors in land use impact assessment: impacts on ecosystem services in case studies of animal protein production in Sweden. Int J Life Cycle Assess 22:328–345

Núñez M, Antón A, Muñoz P, Rieradevall J (2013) Inclusion of soil erosion impacts in life cycle assessment on a global scale: application to energy crops in Spain. Int J Life Cycle Assess 18:755–767

Ostle C, Thompson RC, Broughton D, Gregory L, Wootton M, Johns DG (2019) The rise in ocean plastics evidenced from a 60-year time series. Nature communications 10(1):1–6

PlasticsEurope (2019) Plastics - The Facts 2019: An Analysis of European Plastics Production, Demand and Waste Data. https://www.plasticseurope.org/application/files/9715/7129/9584/FINAL_web_version_Plastics_the_facts2019_14102019.pdf. Accessed 13 February 2020.

Posen ID, Griffin WM, Matthews HS, Azevedo IL (2015) Changing the renewable fuel standard to a renewable material standard: bioethylene case study. Environ Sci Technol 49:93–102

Posen ID, Jaramillo P, Landis AE, Griffin WM (2017) Greenhouse gas mitigation for U.S. plastics production: energy first, feedstocks later. Environ Res Lett 12:034024

Rochman CM, Cook AM, Koelmans AA (2016) Plastic debris and policy: using current scientific understanding to invoke positive change. Environ Toxicol Chem 35:1617–1626

Ryberg MW, Hauschild MZ, Wang F, Averous-Monnery S, Laurent A (2019) Global environmental losses of plastics across their value chains. Resour Conserv Recy 151:104459

Saez de Bikuña K, Hamelin L, Hauschild MZ, Pilegaard K (2018) A comparison of land use change accounting methods: seeking common grounds for key modeling choices in biofuel assessments. J Clean Prod 177:52–61

Saibuatrong W, Cheroennet N, Suwanmanee U (2017) Life cycle assessment focusing on the waste management of conventional and bio-based garbage bags. J Clean Prod 158:319–334

Schmidt JH, Weidema BP, Brandão M (2015) A framework for modelling indirect land use changes in life cycle assessment. J Clean Prod 99:230–238

Scopus Elsevier (2018). Scopus Web site. https://www.scopus.com. Accessed 15 June 2018

Seabra JEA, Macedo IC, Chum HL, Faroni CE, Sarto CA (2011) Life cycle assessment of Brazilian sugarcane products: GHG emissions and energy use. Biofuels Bioprod Biorefin 5:519–532

Searchinger T, Heimlich R, Houghton RA, Dong F, Elobeid A, Fabiosa J, Tokgoz S, Hayes D, Yu TH (2008) Use of US croplands for biofuels increases greenhouse gases through emissions from land-use change. Science 319:1238–1240

Sevigné-Itoiz E, Gasol CM, Rieradevall J, Gabarrell X (2015) Contribution of plastic waste recovery to greenhouse gas (GHG) savings in Spain. Waste Management 46:557–567

SPI (2016) SPI: The Plastics Industry Trade Association. Plastics Market Watch: Bioplastics. Issue VI. http://plasticsindustry.org/sites/plastics.dev/files/2016PMWBioplasticsIA.pdf. Accessed 26 January 2018.

Statista (2020) Production of plastics worldwide from 1950 to 2018 (in million metric tons). https://www.statista.com/statistics/282732/global-production-of-plastics-since-1950/.

Tarrés Q, Melbø JK, Delgado-Aguilar M, Espinach FX, Mutjé P, Chinga-Carrasco G (2018) Bio-polyethylene reinforced with thermomechanical pulp fibers: Mechanical and micromechanical characterization and its application in 3D-printing by fused deposition modelling. Composites Part B: Engineering 153:70–77

Thomson Reuters (2018). ISI Web of Knowledge. https://www.webofknowledge.com/. Accessed 15 June 2018

Tsiropoulos I, Faaij APC, Lundquist L, Schenker U, Briois JF, Patel MK (2015) Life Cycle Impact Assessment of Bio-Based Plastics from Sugarcane. J Clean Prod 90:114–127

United States Environmental Protection Agency (U.S. EPA) (2010) Renewable Fuel Standard Program (RFS2) Regulatory Impact Analysis: EPA-420-R-10-006. Office of Transportation and Air Quality: Washington, DC. https://nepis.epa.gov/Exe/ZyPURL.cgi?Dockey=P1006DXP.TXT. Accessed 20 June 2018.

van den Oever M, Molenveld K, van der Zee M, Bos H (2017) Bio-based and biodegradable plastics - Facts and Figures. Focus on food packaging in the Netherlands. Wageningen Food & Biobased Research. Report 1722. https://library.wur.nl/WebQuery/wurpubs/519929. Accessed 23 May 2018

Vázquez-Rowe I, Marvuglia A, Flammang K, Braun C, Leopold U, Benetto E (2014) The use of temporal dynamics for the automatic calculation of land use impacts in LCA using R programming environment: A case study for increased bioenergy production in Luxembourg. Int J Life Cycle Assess 19:500–516

Vázquez-Rowe I, Caceres AL, Torres-García JR, Quispe I, Kahhat R (2017a) Life Cycle Assessment of the production of pisco in Peru. J Clean Prod 142:4369–4383

Vázquez-Rowe I, Kahhat R, Santillan-Saldívar J, Quispe I, Bentín M (2017b) Carbon footprint of pomegranate (Punica granatum) cultivation in a hyper-arid region in coastal Peru. Int J Life Cycle Assess 22:601–617

Villanueva A, Wenzel H (2007) Paper waste - Recycling, incineration or landfilling? A review of existing life cycle assessments. Waste Management 27(8):29–46

Vink ETH, Davies S, Kolstad JJ (2010) The eco-profile for current Ingeo® polylactide production. Ind Biotechnol 6(4):212–224

Wang Y, Gao YX, Song J, Bonin M, Guo MA, Murphy R (2010) Assessment of technical and environmental performances of wheat-based foams in thermal packaging applications. Packag Technol Sci 23:363–382

Weiss M, Haufe J, Carus M, Brandão M, Bringezu S, Hermann B, Patel MK (2012) A review of the environmental impacts of biobased materials. J Ind Ecol 16:169–181

Wicke B, Verweij P, Van Meijl H, Van Vuuren DP, Faaij APC (2012) Indirect land use change: review of existing models and strategies for mitigation. Biofuels 1:87–100

Zamagni A, Masoni P, Buttol P, Raggi A, Buonamici R (2012) Finding Life Cycle Assessment Research Direction with the Aid of Meta-Analysis. J Ind Ecol 16(1):39–52

Ziegler-Rodriguez K, Margallo M, Vázquez-Rowe I, Kahhat R (2019) Transitioning from open dumpsters to landfilling in Peru: environmental benefits and challenges from a life-cycle perspective. J. Clean. Prod. (under review). 229:989–1003

Zumsteg JM, Cooper JS, Noon MS (2012) Systematic Review Checklist: A Standardized Technique for Assessing and Reporting Reviews of Life Cycle Assessment Data. J Ind Ecol 16(1):12–21

Zuurbier P, van de Vooren J (2008) Sugarcane ethanol: Contributions to climate change mitigation and the environment. Wageningen, the Netherlands: Wageningen Academic Publishers. http://edepot.wur.nl/141865. Accessed 04 October 2018

Title: Reviewing environmental life cycle impacts of biobased polymers: current trends and methodological challenges
Authors: Diana Ita-Nagy
Ian Vázquez-Rowe
Ramzy Kahhat
Gary Chinga-Carrasco
Isabel Quispe
Publication date: 15-10-2020
Publisher: Springer Berlin Heidelberg
Published in: The International Journal of Life Cycle Assessment / Issue 11/2020
Print ISSN: 0948-3349
Electronic ISSN: 1614-7502
DOI: https://doi.org/10.1007/s11367-020-01829-2

Springer Professional

Abstract

Purpose

Methods

Results and discussion

Conclusions

Please log in to get access to your license.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Other articles of this Issue 11/2020

A framework for environmental decision support in cities incorporating organizational LCA

Designing hybrid life cycle assessment models based on uncertainty and complexity

Why statistical testing and confidence intervals should not be used in comparative life cycle assessments based on Monte Carlo simulations

Applying multi-criteria decision-making on alternatives for earth-retaining walls: LCA, LCC, and S-LCA

SETAC Europe Young Scientist LCA Award 2020 for N. Mirabella

Comparing the incomparable? A review of methodical aspects in the sustainability assessment of wood in vehicles