Cleaner production of cleaner fuels: wind-to-wheel – environmental assessment of CO2-based oxymethylene ether as a drop-in fuel

The combustion of fossil fuels within the transportation sector is a key driver of global warming (GW) and leads to harmful emissions of nitrogen oxides (NOx) and particulates (soot). To reduce these negative impacts of the transportation sector, synthetic fuels are currently being developed, which are produced from renewable energy stored via catalytic conversion of hydrogen (H2) and carbon dioxide (CO2). A promising class of synthetic fuels are oxymethylene ethers (OMEs). This study conducts a prospective environmental assessment of an OME-based fuel using Life Cycle Assessment (LCA). We investigate an OME1-diesel-blend (OME1-blend), where OME1 replaces 24 mass% of diesel fuel. Such an OME1-blend could be a first step towards an OME transition. For the production of OME1 from CO2-based methanol, we consider both the established route via condensation with formaldehyde and a novel direct pathway based on catalytic combination with CO2 and hydrogen. To close the carbon loop, CO2 supply via biogas and direct air capture is considered. In a best-case scenario, hydrogen is produced by water electrolysis using electricity from wind power in the European Union as an input. The direct pathway reduces the required process steps from three to two and is shown to allow for an improved utilization of the energy provided by hydrogen: the exergy efficiency is increased from 74% to 86%. For combustion, we conducted experiments in a single cylinder engine to determine the full spectrum of engine-related emissions. The engine data provide the input for simulations of the cumulative raw emissions over the Worldwide Harmonized Light Vehicles Test Procedures (WLTP) cycle for a mid-size passenger vehicle. Our well-to-wheel LCA shows that OME1 has the potential to serve as an almost carbon-neutral blending component: replacing 24 mass% of diesel by OME1 could reduce the GW impact by 22% and the emissions of NOx and soot even by 43% and 75%, respectively. The key to achieving these benefits is the integration of renewable energy in hydrogen production. The cumulative energy demand (CED) over the life cycle is doubled compared to fossil diesel. With sufficient renewable electricity available, OME1-blends may serve as a promising first step towards a more sustainable transportation sector.

[1]  Pushpam Kumar Agriculture (Chapter8) in IPCC, 2007: Climate change 2007: Mitigation of Climate Change. Contribution of Working Group III to the Fourth assessment Report of the Intergovernmental Panel on Climate Change , 2007 .

[2]  Jakob Burger,et al.  Development of an Integrated Reaction–Distillation Process for the Production of Methylal , 2017 .

[3]  Boštjan Drobnič,et al.  Life-cycle assessment of a hydrogen-based uninterruptible power supply system using renewable energy , 2014, The International Journal of Life Cycle Assessment.

[4]  Jörg Sauer,et al.  Physico-chemical properties and fuel characteristics of oxymethylene dialkyl ethers , 2016 .

[5]  Ludolf Plass,et al.  Methanol: The Basic Chemical and Energy Feedstock of the Future Asinger's Vision Today , 2014 .

[6]  André Bardow,et al.  Massive, Automated Solvent Screening for Minimum Energy Demand in Hybrid Extraction-Distillation using COSMO-RS , 2016 .

[7]  F. Graf,et al.  Renewable Power-to-Gas: A technological and economic review , 2016 .

[8]  P. Frederiksen,et al.  Integrated well-to-wheel assessment of biofuels combining energy and emission LCA and welfare economic Cost Benefit Analysis , 2014 .

[9]  René Kleijn,et al.  Energy and climate impacts of producing synthetic hydrocarbon fuels from CO(2). , 2014, Environmental science & technology.

[10]  Georg Wachtmeister,et al.  Oxygenate screening on a heavy-duty diesel engine and emission characteristics of highly oxygenated oxymethylene ether fuel OME1 , 2015 .

[11]  H. Sperber,et al.  Herstellung von Formaldehyd aus Methanol in der BASF , 1969 .

[12]  J L Sullivan,et al.  CO2 emission benefit of diesel (versus gasoline) powered vehicles. , 2004, Environmental science & technology.

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

[14]  Detlef Stolten,et al.  Power to Gas: Technological Overview, Systems Analysis and Economic Assessment , 2015 .

[15]  Daniel Himmel,et al.  Poly(oxymethylene) dimethyl ether synthesis – a combined chemical equilibrium investigation towards an increasingly efficient and potentially sustainable synthetic route , 2017 .

[16]  André Bardow,et al.  Life-cycle assessment of carbon dioxide capture and utilization: avoiding the pitfalls , 2013 .

[17]  Michael J Matzen,et al.  Methanol and dimethyl ether from renewable hydrogen and carbon dioxide: Alternative fuels production and life-cycle assessment , 2016 .

[18]  Andreas Jørgensen,et al.  Enabling optimization in LCA: from “ad hoc” to “structural” LCA approach—based on a biodiesel well-to-wheel case study , 2013, The International Journal of Life Cycle Assessment.

[19]  K. Andreassen Hydrogen Production by Electrolysis , 1998 .

[20]  T. Johnson Review of Vehicular Emissions Trends , 2015 .

[21]  Hans-Jürgen Dr. Klüppel,et al.  The Revision of ISO Standards 14040-3 - ISO 14040: Environmental management – Life cycle assessment – Principles and framework - ISO 14044: Environmental management – Life cycle assessment – Requirements and guidelines , 2005 .

[22]  Jürgen Klankermayer,et al.  Harnessing renewable energy with CO2 for the chemical value chain: challenges and opportunities for catalysis , 2016, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[23]  Jürgen Klankermayer,et al.  Selective Catalytic Synthesis Using the Combination of Carbon Dioxide and Hydrogen: Catalytic Chess at the Interface of Energy and Chemistry. , 2016, Angewandte Chemie.

[24]  Heinz Pitsch,et al.  Experimental and numerical study of a novel biofuel: 2-Butyltetrahydrofuran , 2017 .

[25]  Stefan Pischinger,et al.  Potential of oxymethylenether-diesel blends for ultra-low emission engines , 2017 .

[26]  Niklas von der Assen,et al.  Life cycle assessment of CO2 capture and utilization: a tutorial review. , 2014, Chemical Society reviews.

[27]  Johannes Lindorfer,et al.  Global warming potential of hydrogen and methane production from renewable electricity via power-to-gas technology , 2015, The International Journal of Life Cycle Assessment.

[28]  Jakob Burger,et al.  Chemical Equilibrium of the Synthesis of Poly(oxymethylene) Dimethyl Ethers from Formaldehyde and Methanol in Aqueous Solutions , 2015 .

[29]  Wilhelm Kuckshinrichs,et al.  Worldwide innovations in the development of carbon capture technologies and the utilization of CO2 , 2012 .

[30]  W. Leitner,et al.  Advanced Biofuels and Beyond: Chemistry Solutions for Propulsion and Production. , 2017, Angewandte Chemie.

[31]  A. Godula-Jopek Hydrogen Production: by Electrolysis , 2015 .

[32]  Anders Hammer Strømman,et al.  Life cycle environmental assessment of lithium-ion and nickel metal hydride batteries for plug-in hybrid and battery electric vehicles. , 2011, Environmental science & technology.

[33]  Reinout Heijungs,et al.  Einstein’ssons for energy accounting in LCA , 1998 .

[34]  S. Godtfredsen,et al.  Ullmann ' s Encyclopedia of Industrial Chemistry , 2017 .

[35]  Jürgen Klankermayer,et al.  Tailor-made Molecular Cobalt Catalyst System for the Selective Transformation of Carbon Dioxide to Dialkoxymethane Ethers. , 2017, Angewandte Chemie.

[36]  Robert Schlögl,et al.  The revolution continues: energiewende 2.0. , 2015, Angewandte Chemie.

[37]  G. Centi,et al.  Catalysis for CO2 conversion: a key technology for rapid introduction of renewable energy in the value chain of chemical industries , 2013 .

[38]  Jürgen Klankermayer,et al.  Ruthenium-Catalyzed Synthesis of Dialkoxymethane Ethers Utilizing Carbon Dioxide and Molecular Hydrogen. , 2016, Angewandte Chemie.

[39]  O. Edenhofer Climate change 2014 : mitigation of climate change : Working Group III contribution to the fifth assessment report of the Intergovernmental Panel on Climate Change , 2015 .

[40]  A. Bardow,et al.  Life Cycle Assessment of Power-to-Gas: Syngas vs Methane , 2016 .

[41]  A. Mitsos,et al.  Optimal design and operation of a natural gas tri-reforming reactor for DME synthesis , 2009 .

[42]  Brian Vad Mathiesen,et al.  A comparison between renewable transport fuels that can supplement or replace biofuels in a 100% renewable energy system , 2014 .

[43]  C. Frear,et al.  Purification Technologies for Biogas Generated by Anaerobic Digestion , 2010 .

[44]  Adisa Azapagic,et al.  Carbon dioxide utilisation for production of transport fuels: process and economic analysis , 2015 .

[45]  G. Olah Beyond oil and gas: the methanol economy. , 2006, Angewandte Chemie.

[46]  Niklas von der Assen,et al.  Selecting CO2 Sources for CO2 Utilization by Environmental-Merit-Order Curves. , 2016, Environmental science & technology.

[47]  Friedrich Asinger Methanol — Chemie und Energierohstoff , 1986 .