Net-zero emissions chemical industry in a world of limited resources

[1]  G. Guillén‐Gosálbez,et al.  Towards circular plastics within planetary boundaries , 2023, Nature Sustainability.

[2]  Jonathan M. Cullen,et al.  Planet-compatible pathways for transitioning the chemical industry , 2023, Proceedings of the National Academy of Sciences of the United States of America.

[3]  G. Guillén‐Gosálbez,et al.  Environmental Sustainability Assessment of Hydrogen from Waste Polymers , 2023, ACS sustainable chemistry & engineering.

[4]  Sumayh S. Aljameel,et al.  Biohydrogen from food waste: Modeling and estimation by machine learning based super learner approach , 2023, International Journal of Hydrogen Energy.

[5]  André Cabrera Serrenho,et al.  Greenhouse gas emissions from nitrogen fertilizers could be reduced by up to one-fifth of current levels by 2050 with combined interventions , 2023, Nature Food.

[6]  S. Griffiths,et al.  Decarbonizing the chemical industry: A systematic review of sociotechnical systems, technological innovations, and policy options , 2023, Energy Research & Social Science.

[7]  Steven F. Davis,et al.  Future demand for electricity generation materials under different climate mitigation scenarios , 2023, Joule.

[8]  Elizabeth J. Biddinger,et al.  Decarbonization of the chemical industry through electrification: Barriers and opportunities , 2023, Joule.

[9]  S. Hellweg,et al.  Net-zero transition of the global chemical industry with CO2-feedstock by 2050: feasible yet challenging , 2022, Green chemistry : an international journal and green chemistry resource : GC.

[10]  G. Guillén‐Gosálbez,et al.  Trade-offs between Sustainable Development Goals in carbon capture and utilisation , 2022, Energy & Environmental Science.

[11]  L. Rosa,et al.  Energy and food security implications of transitioning synthetic nitrogen fertilizers to net-zero emissions , 2022, Environmental Research Letters.

[12]  M. Junginger,et al.  Plastic futures and their CO2 emissions , 2022, Nature.

[13]  M. Mazzotti,et al.  Optimization and assessment of carbon capture, transport and storage supply chains for industrial sectors: The cost of resilience , 2022, International Journal of Greenhouse Gas Control.

[14]  A. Bardow,et al.  Sugar-to-What? An Environmental Merit Order Curve for Biobased Chemicals and Plastics , 2022, ACS sustainable chemistry & engineering.

[15]  K. Syberg Beware the false hope of recycling , 2022, Nature.

[16]  S. J. Friedmann,et al.  Technology options and policy design to facilitate decarbonization of chemical manufacturing , 2022, Joule.

[17]  P. Fennell,et al.  Geospatial analysis of regional climate impacts to accelerate cost-efficient direct air capture deployment , 2022, One Earth.

[18]  D. Macfarlane,et al.  Electroreduction of nitrogen with almost 100% current-to-ammonia efficiency , 2022, Nature.

[19]  C. Topp,et al.  Long-term evidence for ecological intensification as a pathway to sustainable agriculture , 2022, Nature Sustainability.

[20]  A. Bardow,et al.  Environmental trade-offs of direct air capture technologies in climate change mitigation toward 2100 , 2022, Nature Communications.

[21]  M. Mazzotti,et al.  Carbon dioxide capture, transport and storage supply chains: Optimal economic and environmental performance of infrastructure rollout , 2022, International Journal of Greenhouse Gas Control.

[22]  X. Bai,et al.  A planetary boundary for green water , 2022, Nature Reviews Earth & Environment.

[23]  A. Bardow,et al.  A climate-optimal supply chain for CO2 capture, utilization, and storage by mineralization , 2022, Journal of Cleaner Production.

[24]  A. Bardow,et al.  Cost-optimal pathways towards net-zero chemicals and plastics based on a circular carbon economy , 2022, Comput. Chem. Eng..

[25]  M. Mazzotti,et al.  Potential for hydrogen production from sustainable biomass with carbon capture and storage , 2022, Renewable and Sustainable Energy Reviews.

[26]  Shaohui Zhang,et al.  Exploring pathways to deep de-carbonization and the associated environmental impact in China’s ammonia industry , 2022, Environmental Research Letters.

[27]  B. Chachuat,et al.  A Pathway Towards Net-Zero Emissions in Oil Refineries , 2022, Frontiers in Chemical Engineering.

[28]  S. Krevor,et al.  An Estimate of the Amount of Geological CO2 Storage over the Period of 1996–2020 , 2021, Environmental science & technology letters.

[29]  A. Bardow,et al.  Environmental impact of pioneering carbon capture, transport and storage chains , 2022, Social Science Research Network.

[30]  S. T. Munkejord,et al.  Perspective on the hydrogen economy as a pathway to reach net-zero CO2 emissions in Europe , 2022, Energy & Environmental Science.

[31]  S. Pfister,et al.  Growing environmental footprint of plastics driven by coal combustion , 2021, Nature Sustainability.

[32]  J. Lilliestam,et al.  Drop-in fuels from sunlight and air , 2021, Nature.

[33]  L. Feyen,et al.  The number of people exposed to water stress in relation to how much water is reserved for the environment: a global modelling study. , 2021, The Lancet. Planetary health.

[34]  S. Shackley,et al.  How do people perceive carbon capture and storage for industrial processes? Examining factors underlying public opinion in the Netherlands and the United Kingdom , 2021 .

[35]  J. Lane,et al.  Uncertain storage prospects create a conundrum for carbon capture and storage ambitions , 2021, Nature Climate Change.

[36]  H. Herzog,et al.  Hard-to-Abate Sectors: The role of industrial carbon capture and storage (CCS) in emission mitigation , 2021 .

[37]  M. Mazzotti,et al.  Technological Demonstration and Life Cycle Assessment of a Negative Emission Value Chain in the Swiss Concrete Sector , 2021, Frontiers in Climate.

[38]  A. Bardow,et al.  Achieving net-zero greenhouse gas emission plastics by a circular carbon economy , 2021, Science.

[39]  J. Rogelj,et al.  Wave of net zero emission targets opens window to meeting the Paris Agreement , 2021, Nature Climate Change.

[40]  Antonio J. Martín,et al.  Planetary Boundaries Analysis of Low-Carbon Ammonia Production Routes , 2021, ACS Sustainable Chemistry & Engineering.

[41]  Zhong Xie,et al.  Measuring the similarity of building patterns using Graph Fourier transform , 2021, Earth Science Informatics.

[42]  Thomas H. Epps,et al.  Toward polymer upcycling—adding value and tackling circularity , 2021, Science.

[43]  G. Rosetto,et al.  Achieving a circular bioeconomy for plastics , 2021, Science.

[44]  Rebecca M Altman The myth of historical bio-based plastics , 2021, Science.

[45]  C. Dorich,et al.  Quantification of global and national nitrogen budgets for crop production , 2021, Nature Food.

[46]  Dolf Gielen,et al.  Zero-Emission Pathway for the Global Chemical and Petrochemical Sector , 2021, Energies.

[47]  J. Lange Towards circular carbo-chemicals – the metamorphosis of petrochemicals , 2021, Energy & Environmental Science.

[48]  Haotian Wang,et al.  Electrochemical ammonia synthesis via nitrate reduction on Fe single atom catalyst , 2021, Nature Communications.

[49]  N. Shah,et al.  A carbon neutral chemical industry powered by the sun , 2021, Discover Chemical Engineering.

[50]  V. Seufert,et al.  Global option space for organic agriculture is delimited by nitrogen availability , 2021, Nature Food.

[51]  G. Guillén‐Gosálbez,et al.  Sustainability footprints of a renewable carbon transition for the petrochemical sector within planetary boundaries , 2021 .

[52]  M. Mazzotti,et al.  Assessment of carbon dioxide removal potential via BECCS in a carbon-neutral Europe , 2021, Energy & Environmental Science.

[53]  I. Wilson,et al.  Sustainable Ammonia Production Processes , 2021, Frontiers in Energy Research.

[54]  Lidia S. Guerras,et al.  Sustainable Energy Transition Considering the Water–Energy Nexus: A Multiobjective Optimization Framework , 2021 .

[55]  M. Finkbeiner,et al.  Planetary boundaries for water – A review , 2021 .

[56]  M. Mazzotti,et al.  Role of Carbon Capture, Storage, and Utilization to Enable a Net-Zero-CO2-Emissions Aviation Sector , 2021 .

[57]  T. Ligthart,et al.  Plastic recycling in a circular economy; determining environmental performance through an LCA matrix model approach. , 2021, Waste management.

[58]  Yi-Ming Wei,et al.  A proposed global layout of carbon capture and storage in line with a 2 °C climate target , 2021, Nature Climate Change.

[59]  Gonzalo Guillén-Gosálbez,et al.  Process design within planetary boundaries: Application to CO2 based methanol production , 2021 .

[60]  Catherine Azzaro-Pantel,et al.  Centralised vs. decentralised production and storage: optimal design of a decarbonised hydrogen supply chain with multiple end uses , 2021, 31st European Symposium on Computer Aided Process Engineering.

[61]  D. Victor,et al.  Explaining successful and failed investments in U.S. carbon capture and storage using empirical and expert assessments , 2020, Environmental Research Letters.

[62]  Chunshan Song,et al.  Carbon Capture From Flue Gas and the Atmosphere: A Perspective , 2020, Frontiers in Energy Research.

[63]  Jingguang G. Chen,et al.  N2 Fixation by Plasma-Activated Processes , 2020 .

[64]  M. Mazzotti,et al.  Optimization of low-carbon multi-energy systems with seasonal geothermal energy storage: The Anergy Grid of ETH Zurich , 2020, Energy Conversion and Management: X.

[65]  M. Mazzotti,et al.  Hydrogen from wood gasification with CCS – a techno-environmental analysis of production and use as transport fuel , 2020, Sustainable Energy & Fuels.

[66]  A. Bardow,et al.  Towards a circular economy for plastic packaging wastes – the environmental potential of chemical recycling , 2020 .

[67]  M. Mazzotti,et al.  Enabling low-carbon hydrogen supply chains through use of biomass and carbon capture and storage: A Swiss case study , 2020 .

[68]  A. Bardow,et al.  Rock ‘n’ use of CO2: carbon footprint of carbon capture and utilization by mineralization , 2020, Sustainable Energy & Fuels.

[69]  Toby D. Pilditch,et al.  Evaluating scenarios toward zero plastic pollution , 2020, Science.

[70]  M. Mazzotti,et al.  Hydrogen production from natural gas and biomethane with carbon capture and storage – A techno-environmental analysis , 2020, Sustainable Energy & Fuels.

[71]  D. Macfarlane,et al.  A Roadmap to the Ammonia Economy , 2020, Joule.

[72]  P. D’Odorico,et al.  Hydrological limits to carbon capture and storage , 2020, Nature Sustainability.

[73]  P. D’Odorico,et al.  Global agricultural economic water scarcity , 2020, Science Advances.

[74]  M. Mazzotti,et al.  The Role of Carbon Capture and Utilization, Carbon Capture and Storage, and Biomass to Enable a Net-Zero-CO2 Emissions Chemical Industry , 2020, Industrial & Engineering Chemistry Research.

[75]  L. Torrente‐Murciano,et al.  Current and future role of Haber–Bosch ammonia in a carbon-free energy landscape , 2020, Energy & Environmental Science.

[76]  G. Centi,et al.  Chemistry and energy beyond fossil fuels. A perspective view on the role of syngas from waste sources , 2020 .

[77]  P. Anastas,et al.  Designing for a green chemistry future , 2020, Science.

[78]  Sandra Ó. Snæbjörnsdóttir,et al.  Carbon dioxide storage through mineral carbonation , 2020, Nature Reviews Earth & Environment.

[79]  A. Vourros,et al.  An Electrochemical Haber-Bosch Process , 2020 .

[80]  G. Sampson,et al.  The On-Farm and Near-Farm Effects of Wind Turbines on Agricultural Land Values , 2020 .

[81]  G. Guillén‐Gosálbez,et al.  Plant-to-planet analysis of CO2-based methanol processes , 2019, Energy & Environmental Science.

[82]  G. Centi,et al.  Chemical engineering role in the use of renewable energy and alternative carbon sources in chemical production , 2019, BMC Chemical Engineering.

[83]  Charlotte K. Williams,et al.  The technological and economic prospects for CO2 utilization and removal , 2019, Nature.

[84]  G. Kabir,et al.  Green supply chain management in the chemical industry: structural framework of drivers , 2019, International Journal of Sustainable Development & World Ecology.

[85]  Fabrizio Bezzo,et al.  European supply chains for carbon capture, transport and sequestration, with uncertainties in geological storage capacity: Insights from economic optimisation , 2019, Comput. Chem. Eng..

[86]  M. Mazzotti,et al.  110th Anniversary: Evaluation of CO2-Based and CO2-Free Synthetic Fuel Systems Using a Net-Zero-CO2-Emission Framework , 2019, Industrial & Engineering Chemistry Research.

[87]  Andrea K. Gerlak,et al.  Agrivoltaics provide mutual benefits across the food–energy–water nexus in drylands , 2019, Nature Sustainability.

[88]  M. Aresta Carbon dioxide utilization: The way to the circular economy , 2019, Greenhouse Gases: Science and Technology.

[89]  E. Davidson,et al.  A World of Cobenefits: Solving the Global Nitrogen Challenge , 2019, Earth's future.

[90]  Christian Breyer,et al.  Techno-economic assessment of CO2 direct air capture plants , 2019, Journal of Cleaner Production.

[91]  S. Suh,et al.  Climate change mitigation potential of carbon capture and utilization in the chemical industry , 2019, Proceedings of the National Academy of Sciences.

[92]  G. Soloveichik Electrochemical synthesis of ammonia as a potential alternative to the Haber–Bosch process , 2019, Nature Catalysis.

[93]  S. Suh,et al.  Strategies to reduce the global carbon footprint of plastics , 2019, Nature Climate Change.

[94]  A. Ramírez,et al.  When are negative emissions negative emissions? , 2019, Energy & Environmental Science.

[95]  M. J. Booij,et al.  Limits to the world’s green water resources for food, feed, fiber, timber, and bioenergy , 2019, Proceedings of the National Academy of Sciences.

[96]  V. Moreau,et al.  Enough Metals? Resource Constraints to Supply a Fully Renewable Energy System , 2019, Resources.

[97]  M. Aresta,et al.  Large Scale Utilization of Carbon Dioxide: From Its Reaction with Energy Rich Chemicals to (Co)-processing with Water to Afford Energy Rich Products. Opportunities and Barriers , 2019, An Economy Based on Carbon Dioxide and Water.

[98]  Seong-Rin Lim,et al.  Comparative assessment of solar photovoltaic panels based on metal-derived hazardous waste, resource depletion, and toxicity potentials , 2018, International Journal of Green Energy.

[99]  David William Keith,et al.  A Process for Capturing CO2 from the Atmosphere , 2018, Joule.

[100]  Jessica A. Gephart,et al.  The Global Food‐Energy‐Water Nexus , 2018, Reviews of Geophysics.

[101]  P. Ringrose The CCS hub in Norway: some insights from 22 years of saline aquifer storage , 2018, Energy Procedia.

[102]  Marco Mazzotti,et al.  Electrochemical conversion technologies for optimal design of decentralized multi-energy systems: Modeling framework and technology assessment , 2018, Applied Energy.

[103]  Matthew R. Shaner,et al.  Net-zero emissions energy systems , 2018, Science.

[104]  C. Maravelias,et al.  Greening Ammonia toward the Solar Ammonia Refinery , 2018, Joule.

[105]  Patrick L. Holland,et al.  Beyond fossil fuel–driven nitrogen transformations , 2018, Science.

[106]  Solomon F. Brown,et al.  Carbon capture and storage (CCS): the way forward , 2018 .

[107]  Tomoko Hasegawa,et al.  Scenarios towards limiting global mean temperature increase below 1.5 °C , 2018, Nature Climate Change.

[108]  Peter G. Levi,et al.  Mapping Global Flows of Chemicals: From Fossil Fuel Feedstocks to Chemical Products. , 2018, Environmental science & technology.

[109]  William F. Lamb,et al.  Negative emissions—Part 3: Innovation and upscaling , 2018 .

[110]  R. C. Samsun,et al.  The separation of CO2 from ambient air – A techno-economic assessment , 2018 .

[111]  Sukhwinder K. Bali,et al.  A Review of Methods to Improve Nitrogen Use Efficiency in Agriculture , 2017 .

[112]  Edward S. Rubin,et al.  On the climate change mitigation potential of CO2 conversion to fuels , 2017 .

[113]  Fabrizio Bezzo,et al.  Economic optimisation of European supply chains for CO2 capture, transport and sequestration , 2017 .

[114]  Zachary J. Schiffer,et al.  Electrification and Decarbonization of the Chemical Industry , 2017 .

[115]  E. Furusjö,et al.  Techno-economic assessment of catalytic gasification of biomass powders for methanol production. , 2017, Bioresource technology.

[116]  Steve Whittaker,et al.  Building Confidence in CO2 Storage Using Reference Datasets from Demonstration Projects , 2017 .

[117]  Sergey Paltsev,et al.  Developing a Consistent Database for Regional Geologic CO2 Storage Capacity Worldwide , 2017 .

[118]  R. Geyer,et al.  Production, use, and fate of all plastics ever made , 2017, Science Advances.

[119]  Peter H. Pfromm,et al.  Towards sustainable agriculture: Fossil-free ammonia , 2017 .

[120]  J. Finnigan,et al.  Losses, inefficiencies and waste in the global food system , 2017, Agricultural systems.

[121]  Licheng Sun,et al.  Chemistry Future: Priorities and Opportunities from the Sustainability Perspective. , 2017, ChemSusChem.

[122]  W. M. Griffin,et al.  Greenhouse gas mitigation for U.S. plastics production: energy first, feedstocks later , 2017 .

[123]  I. Dincer,et al.  Comparative life cycle assessment of various ammonia production methods , 2016 .

[124]  Pratham Arora,et al.  Small-Scale Ammonia Production from Biomass: A Techno-Enviro-Economic Perspective , 2016 .

[125]  Alexander M. Niziolek,et al.  Biomass-Based Production of Benzene, Toluene, and Xylenes via Methanol: Process Synthesis and Deterministic Global Optimization , 2016 .

[126]  Fabrizio Passarini,et al.  Butadiene from biomass, a life cycle perspective to address sustainability in the chemical industry , 2016 .

[127]  A. Hoekstra,et al.  Four billion people facing severe water scarcity , 2016, Science Advances.

[128]  Aristide F. Massardo,et al.  Feasibility study of methanol production from different renewable sources and thermo-economic analysis , 2016 .

[129]  Emmanuel Kakaras,et al.  Investigation of technical and economic aspects for methanol production through CO2 hydrogenation , 2016 .

[130]  E. Tzimas,et al.  Methanol synthesis using captured CO2 as raw material: Techno-economic and environmental assessment , 2016 .

[131]  N. Nakicenovic,et al.  Biophysical and economic limits to negative CO2 emissions , 2016 .

[132]  Jim Philp,et al.  Policy: Define biomass sustainability , 2015, Nature.

[133]  C. Wilcox,et al.  Plastic waste inputs from land into the ocean , 2015, Science.

[134]  S. Carpenter,et al.  Planetary boundaries: Guiding human development on a changing planet , 2015, Science.

[135]  André Sternberg,et al.  Power-to-What? : Environmental assessment of energy storage systems , 2015 .

[136]  J. Garnier,et al.  50 year trends in nitrogen use efficiency of world cropping systems: the relationship between yield and nitrogen input to cropland , 2014 .

[137]  Christoph Schmitz,et al.  Reactive nitrogen requirements to feed the world in 2050 and potential to mitigate nitrogen pollution , 2014, Nature Communications.

[138]  Thore Berntsson,et al.  Gasification-based methanol production from biomass in industrial clusters: Characterisation of energy balances and greenhouse gas emissions , 2014 .

[139]  Robert Gross,et al.  Global bioenergy resources , 2014 .

[140]  P. Gilbert,et al.  Assessing economically viable carbon reductions for the production of ammonia from biomass gasification , 2014 .

[141]  C. Bouallou,et al.  Design and simulation of a methanol production plant from CO2 hydrogenation , 2013 .

[142]  Garvin A. Heath,et al.  Life cycle water use for electricity generation: a review and harmonization of literature estimates , 2013 .

[143]  Thore Berntsson,et al.  System aspects of biomass gasification with methanol synthesis – Process concepts and energy analysis , 2012 .

[144]  Waldemar Liebner,et al.  CO2-based methanol and DME – Efficient technologies for industrial scale production , 2011 .

[145]  E. Lambin,et al.  INAUGURAL ARTICLE by a Recently Elected Academy Member:Global land use change, economic globalization, and the looming land scarcity , 2011 .

[146]  W. Winiwarter,et al.  How a century of ammonia synthesis changed the world , 2008 .

[147]  Lukas H. Meyer,et al.  Summary for Policymakers , 2022, The Ocean and Cryosphere in a Changing Climate.

[148]  K. Blok,et al.  Producing bio-based bulk chemicals using industrial biotechnology saves energy and combats climate change. , 2007, Environmental science & technology.

[149]  H. Whittington,et al.  Methanol synthesis from flue-gas CO2 and renewable electricity: A feasibility study , 2003 .

[150]  V. Smil Nitrogen and Food Production: Proteins for Human Diets , 2002, Ambio.

[151]  R. Von Burg,et al.  Methanol , 1925, Journal of applied toxicology : JAT.