Nutrient recovery and pollutant removal during renewable fuel production: opportunities and challenges

Circumstances affecting the heat of the sun’s rays.

Am. J. Sci. Arts. 1856; 22: 382-383

Climate Change 2022: Mitigation of Climate Change.

in: Contribution of Working Group III to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, 2022

• Aykut S.C.
• Castro M.

The end of fossil fuels? Understanding the partial climatisation of global energy debates.

in: Aykut S. Globalising the Climate. Taylor & Francis, 2017: 173-193

• El Bilali H.
• et al.

Climate change and food security.

Agric. Forestry. 2020; 66: 197-210

• Sinay L.
• Carter R.W.

Climate change adaptation options for coastal communities and local governments.

Climate. 2020; 8: 7

Climate Change 2022: Impacts, Adaptation, and Vulnerability.

in: Contribution of Working Group II to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, 2022

• Gaulin N.
• Le Billon P.

Climate change and fossil fuel production cuts: assessing global supply-side constraints and policy implications.

Clim. Pol. 2020; 20: 888-901

• German Advisory Council On Global Change

World in Transition 3: Towards Sustainable Energy Systems.

Routledge, 2014

• United Nations/Framework Convention on Climate Change

Adoption of the Paris Agreement, 21st Conference of the Parties.

United Nations, 2015

World Energy Transitions Outlook 2022: 1.5°C Pathway.

International Renewable Energy Agency, 2022

• Woolf D.
• et al.

Biochar for climate change mitigation: navigating from science to evidence-based policy.

in: Lal R. Stewart B.A. Soil and Climate. CRC Press, 2018: 219-248

• Lehmann J.
• et al.

Biochar in climate change mitigation.

Nat. Geosci. 2021; 14: 883-892

• Mertens J.
• et al.

Why the carbon-neutral energy transition will imply the use of lots of carbon.

J. Carbon Res. 2020; 6: 39

• Staffell I.
• et al.

The role of hydrogen and fuel cells in the global energy system.

Energy Environ. Sci. 2019; 12: 463-491

• Allegue L.B.
• et al.

Biogas and Bio-Syngas Upgrading.

Danish Technological Institute, 2012

• Wisell T.
• et al.

Fuel and Technology Alternatives in Non-Road Engines.

IEA-AMF, 2018

Technology Roadmap – Biofuels for Transport.

IEA, 2011

Global Biofuel Demand in the Net Zero Scenario, 2015-2030.

IEA, 2022

• De Vrieze J.
• et al.

The hydrogen gas bio-based economy and the production of renewable building block chemicals, food and energy.

New Biotechnol. 2020; 55: 12-18

• Miandad R.
• et al.

Catalytic pyrolysis of plastic waste: moving toward pyrolysis based biorefineries.

Front. Energy Res. 2019; 7: 27

• Cherubini F.

The biorefinery concept: using biomass instead of oil for producing energy and chemicals.

Energy Convers. Manag. 2010; 51: 1412-1421

• Roddy D.J.

A syngas network for reducing industrial carbon footprint and energy use.

Appl. Therm. Eng. 2013; 53: 299-304

• Math M.C.
• et al.

Technologies for biodiesel production from used cooking oil — a review.

Energy Sustain. Dev. 2010; 14: 339-345

• Boerrigter H.
• et al.

Green diesel from biomass by Fischer-Tropsch synthesis: new insights in glass cleaning and process design.

in: A.V. Bridgewater, Pyrolysis and Gasification of Biomass and Waste. Proceedings of PGBW Expert Meeting, Strasbourg, France2002: 4-7

• Stoll I.K.
• et al.

Syngas fermentation to alcohols: reactor technology and application perspective.

Chem. Ing. Tech. 2020; 92: 125-136

• Xu D.
• et al.

The effects of syngas impurities on syngas fermentation to liquid fuels.

Biomass Bioenergy. 2011; 35: 2690-2696

• Shahriar M.F.
• Khanal A.

The current techno-economic, environmental, policy status and perspectives of sustainable aviation fuel (SAF).

Fuel. 2022; 325124905

• McCue A.J.
• Anderson J.A.

Sulfur as a catalyst promoter or selectivity modifier in heterogeneous catalysis.

Catal. Sci. Technol. 2014; 4: 272-294

• Sanford S.D.
• et al.

Feedstock and biodiesel characteristics report.

Renew. Energy Group. 2009; 416: 1-136

• Christensen J.M.
• et al.

Effects of H2S and process conditions in the synthesis of mixed alcohols from syngas over alkali promoted cobalt-molybdenum sulfide.

Appl. Catal. A Gen. 2009; 366: 29-43

Synthesis of renewable hydrocarbons from vegetable oil feedstock by hydrotreatment over selective sulfur-free SiO2-Al2O3 supported monometallic Pd, Pt, Ru, Ni, Mo and bimetallic NiMo catalysts.

Fuel. 2021; 285119129

• Abraham V.
• deMan J.M.

Effect of some isothiocyanates on the hydrogenation of canola oil.

J. Am. Oil Chem. Soc. 1987; 64: 855-858

• Hensley J.E.
• et al.

Compositional analysis and advanced distillation curve for mixed alcohols produced via syngas on a K-CoMoSx catalyst.

Energy Fuels. 2013; 27: 3246-3260

• Andersson R.
• et al.

Higher alcohols from syngas using a K/Ni/MoS2 catalyst: trace sulfur in the product and effect of H2S-containing feed.

Fuel. 2014; 115: 544-550

• Popovic M.
• Minceva M.

Standard thermodynamic properties, biosynthesis rates, and the driving force of growth of five agricultural plants.

Front. Plant Sci. 2021; 12: 871

• Eriksson J.E.

Effects of nitrogen-containing fertilizers on solubility and plant uptake of cadmium.

Water Air Soil Pollut. 1990; 49: 355-368

• Dimkpa C.O.
• et al.

Development of fertilizers for enhanced nitrogen use efficiency – trends and perspectives.

Sci. Total Environ. 2020; 731139113

• Miller S.A.
• et al.

Environmental trade-offs of biobased production.

Environ. Sci. Technol. 2007; 41: 5176-5182

• Guthrie S.
• et al.

The Impact of Ammonia Emissions from Agriculture on Biodiversity.

RAND Corporation and The Royal Society, 2018

• Ma W.
• et al.

Fischer-Tropsch synthesis: effect of ammonia in syngas on the Fischer-Tropsch synthesis performance of a precipitated iron catalyst.

J. Catal. 2015; 326: 149-160

• Tawalbeh M.
• et al.

Ammonia: a versatile candidate for the use in energy storage systems.

Renew. Energy. 2022; 194: 955-977

• Metcalf L.
• et al.

Wastewater Energy: Treatment and Reuse.

McGraw-Hill, 2004

• Erisman J.W.
• et al.

How a century of ammonia synthesis changed the world.

Nat. Geosci. 2008; 1: 636-639

• Beckinghausen A.
• et al.

From removal to recovery: an evaluation of nitrogen recovery techniques from wastewater.

Appl. Energy. 2020; 263114616

• Morlanés N.
• et al.

A technological roadmap to the ammonia energy economy: current state and missing technologies.

Chem. Eng. J. 2021; 408127310

• National Research Council

Acute Exposure Guideline Levels for Selected Airborne Chemicals.

The National Academies Press, 2013

Odor thresholds and irritation levels of several chemical substances: a review.

Am. Ind. Hyg. Assoc. J. 1986; 47: A142-A151

• Rokni E.
• et al.

Reduction of sulfur dioxide emissions by burning coal blends.

J. Energy Resour. Technol. 2015; 138032204

• Salih Y.M.
• et al.

A comparative study of the emission of volatile organic compounds (VOCs) from different sulfur content crude oils.

Pet. Sci. Technol. 2018; 36: 1037-1043

• Maslin M.
• et al.

Sulfur: a potential resource crisis that could stifle green technology and threaten food security as the world decarbonises.

Geogr. J. 2022; 188: 498-505

• Kelly T.D.
• et al.

Historical statistics for mineral and material commodities in the United States.

US Geological Survey Data Series. 140. 2010: 01-006

• Wang W.
• et al.

Catalytic fast pyrolysis of cellulose for increasing contents of furans and aromatics in biofuel production.

J. Anal. Appl. Pyrolysis. 2018; 131: 93-100

• Mo W.
• et al.

Processes simulation and environmental evaluation of biofuel production via Co-pyrolysis of tropical agricultural waste.

Energy. 2022; 242123016

• El-Naas M.H.
• et al.

Aerobic biodegradation of BTEX: progresses and prospects.

J. Environ. Chem. Eng. 2014; 2: 1104-1122

• Lueders T.

The ecology of anaerobic degraders of BTEX hydrocarbons in aquifers.

FEMS Microbiol. Ecol. 2017; 93: 1-13

• Oh Y-.S.
• et al.

Interactions between benzene, toluene, and p‐xylene (BTX) during their biodegradation.

Biotechnol. Bioeng. 1994; 44: 533-538

• European Council

Directive (EU) 2020/2184 of the European Parliament and of the Council of 16 December 2020 on the Quality of Water Intended For Human Consumption.

European Council, 2020

• US Environmental Protection Agency

2006 Edition of the Drinking Water Standards and Health Advisories.

US Environmental Protection Agency, 2006

• Farhadian M.
• et al.

In situ bioremediation of monoaromatic pollutants in groundwater: a review.

Bioresour. Technol. 2008; 99: 5296-5308

• Varjani S.J.

Microbial degradation of petroleum hydrocarbons.

Bioresour. Technol. 2017; 223: 277-286

• Logeshwaran P.
• et al.

Petroleum hydrocarbons (PH) in groundwater aquifers: an overview of environmental fate, toxicity, microbial degradation and risk-based remediation approaches.

Environ. Technol. Innov. 2018; 10: 175-193

• Hatipoğlu-Bağci Z.
• Motz L.H.

Methods for investigation of natural attenuation and modeling of petroleum hydrocarbon contamination in coastal aquifers.

Jeoloji Muhendisligi Dergisi. 2019; 43: 131-154

• Calbry-Muzyka A.
• et al.

Biogas composition from agricultural sources and organic fraction of municipal solid waste.

Renew. Energy. 2022; 181: 1000-1007

• Li Y.
• et al.

Composition and toxicity of biogas produced from different feedstocks in California.

Environ. Sci. Technol. 2019; 53: 11569-11579

• Higman C.
• van der Burgt M.

Gasification.

Elsevier, 2003

How to Produce Methanol from Coal.

Springer, 1990

• Liakakou E.T.
• et al.

Connecting gasification with syngas fermentation: comparison of the performance of lignin and beech wood.

Fuel. 2021; 290120054