Hydrogen production, storage, utilisation and environmental impacts: a review

Environmental Chemistry Letters, Год журнала: 2021, Номер 20(1), С. 153 - 188

Опубликована: Окт. 6, 2021

Abstract Dihydrogen (H 2 ), commonly named ‘hydrogen’, is increasingly recognised as a clean and reliable energy vector for decarbonisation defossilisation by various sectors. The global hydrogen demand projected to increase from 70 million tonnes in 2019 120 2024. Hydrogen development should also meet the seventh goal of ‘affordable energy’ United Nations. Here we review production life cycle analysis, geological storage utilisation. produced water electrolysis, steam methane reforming, pyrolysis coal gasification. We compare environmental impact routes analysis. used power systems, transportation, hydrocarbon ammonia production, metallugical industries. Overall, combining electrolysis-generated with underground porous media such reservoirs salt caverns well suited shifting excess off-peak dispatchable on-peak demand.

Язык: Английский

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Agricultural waste management strategies for environmental sustainability

Environmental Research, Год журнала: 2021, Номер 206, С. 112285 - 112285

Опубликована: Окт. 25, 2021

Язык: Английский

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Recent advances in carbon capture storage and utilisation technologies: a review

Environmental Chemistry Letters, Год журнала: 2020, Номер 19(2), С. 797 - 849

Опубликована: Ноя. 22, 2020

Abstract Human activities have led to a massive increase in $$\hbox {CO}_{2}$$ CO 2 emissions as primary greenhouse gas that is contributing climate change with higher than $$1\,^{\circ }\hbox {C}$$ 1 ∘ C global warming of the pre-industrial level. We evaluate three major technologies are utilised for carbon capture: pre-combustion, post-combustion and oxyfuel combustion. review advances capture, storage utilisation. compare uptake techniques dioxide separation. Monoethanolamine most common sorbent; yet it requires high regeneration energy 3.5 GJ per tonne . Alternatively, recent sorbent technology reveal novel solvents such modulated amine blend lower 2.17 Graphene-type materials show adsorption capacity 0.07 mol/g, which 10 times specific types activated carbon, zeolites metal–organic frameworks. geosequestration provides an efficient long-term strategy storing captured geological formations factor at Gt-scale within operational timescales. Regarding utilisation route, currently, gross 200 million tonnes year, roughly negligible compared extent anthropogenic emissions, 32,000 year. Herein, we different methods direct routes, i.e. beverage carbonation, food packaging oil recovery, chemical industries fuels. Moreover, investigated additional base-load power generation, seasonal storage, district cooling cryogenic air capture using geothermal energy. Through bibliometric mapping, identified research gap literature this field future investigations, instance, designing new stable ionic liquids, pore size selectivity frameworks enhancing solvents. areas techno-economic evaluation solvents, process design dynamic simulation require further effort well development before pilot- commercial-scale trials.

Язык: Английский

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Conversion of biomass to biofuels and life cycle assessment: a review

Environmental Chemistry Letters, Год журнала: 2021, Номер 19(6), С. 4075 - 4118

Опубликована: Июль 23, 2021

Abstract The global energy demand is projected to rise by almost 28% 2040 compared current levels. Biomass a promising source for producing either solid or liquid fuels. Biofuels are alternatives fossil fuels reduce anthropogenic greenhouse gas emissions. Nonetheless, policy decisions biofuels should be based on evidence that produced in sustainable manner. To this end, life cycle assessment (LCA) provides information environmental impacts associated with biofuel production chains. Here, we review advances biomass conversion and their impact assessment. Processes gasification, combustion, pyrolysis, enzymatic hydrolysis routes fermentation. Thermochemical processes classified into low temperature, below 300 °C, high higher than i.e. combustion pyrolysis. Pyrolysis because it operates at relatively lower temperature of up 500 which 800–1300 °C. We focus 1) the drawbacks advantages thermochemical biochemical various possibility integrating these better process efficiency; 2) methodological approaches key findings from 40 LCA studies pathways published 2019 2021; 3) bibliometric trends knowledge gaps using routes. integration hydrothermal circular economy.

Язык: Английский

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Industrial decarbonization via hydrogen: A critical and systematic review of developments, socio-technical systems and policy options

Energy Research & Social Science, Год журнала: 2021, Номер 80, С. 102208 - 102208

Опубликована: Авг. 3, 2021

Язык: Английский

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A technical review of bioenergy and resource recovery from municipal solid waste

Journal of Hazardous Materials, Год журнала: 2020, Номер 403, С. 123970 - 123970

Опубликована: Сен. 17, 2020

Язык: Английский

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Current status of carbon capture, utilization, and storage technologies in the global economy: A survey of technical assessment

Fuel, Год журнала: 2023, Номер 342, С. 127776 - 127776

Опубликована: Фев. 27, 2023

The latest tremendously rapid expansion of the energy and industrial sector has led to a sharp increase in stationary sources CO2. Consequently, lot concerns have been raised about prevention global warming achievement climate mitigation strategies by 2050 with low-carbon sustainable future. In view this, current state various aspects carbon capture, utilization, storage (CCUS) technologies general technical assessment were concisely reviewed discussed. We concentrated on precisely identifying technology readiness level (TRL), which is beneficial specifically defining maturity for each key element CCUS system commercialization direction paths. addition, we especially presented emphasized importance CO2 capture types from flue gases separation methods. Then, determined valuable data largest R&D projects at scales. This paper provides critical review literature related challenges that must be overcome raise many low TRL facilitate their implementation commercial scale. Finally, our work aims guide further scaling up establishment worldwide emission reduction projects.

Язык: Английский

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Algal biomass valorization for biofuel production and carbon sequestration: a review

Environmental Chemistry Letters, Год журнала: 2022, Номер 20(5), С. 2797 - 2851

Опубликована: Июнь 15, 2022

Abstract The world is experiencing an energy crisis and environmental issues due to the depletion of fossil fuels continuous increase in carbon dioxide concentrations. Microalgal biofuels are produced using sunlight, water, simple salt minerals. Their high growth rate, photosynthesis, sequestration capacity make them one most important biorefinery platforms. Furthermore, microalgae's ability alter their metabolism response stresses produce relatively levels high-value compounds makes a promising alternative fuels. As result, microalgae can significantly contribute long-term solutions critical global such as climate change. benefits algal biofuel have been demonstrated by significant reductions dioxide, nitrogen oxide, sulfur oxide emissions. Microalgae-derived biomass has potential generate wide range commercially compounds, novel materials, feedstock for variety industries, including cosmetics, food, feed. This review evaluates microalgal bioenergy carriers, biodiesel from stored lipids, alcohols reserved carbohydrate fermentation, hydrogen, syngas, methane, biochar bio-oils via anaerobic digestion, pyrolysis, gasification. use routes atmospheric removal approach being evaluated. cost production primarily determined culturing (77%), harvesting (12%), lipid extraction (7.9%). choice species cultivation mode (autotrophic, heterotrophic, mixotrophic) factors controlling production, well fuel properties. simultaneous agricultural, municipal, or industrial wastewater low-cost option that could reduce economic costs while also providing valuable remediation service. Microalgae proposed viable candidate capture atmosphere point source. sequester 1.3 kg 1 biomass. Using potent strains efficient design bioreactors thus challenge. theoretically up 9% light convert 513 tons into 280 dry per hectare year open closed cultures. integrated bio-refinery recover high-value-added products waste create processing bioenergy. To system, should be coupled with thermochemical technologies, pyrolysis.

Язык: Английский

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Biohydrogen Production From Biomass Sources: Metabolic Pathways and Economic Analysis

Frontiers in Energy Research, Год журнала: 2021, Номер 9

Опубликована: Сен. 10, 2021

The commercialization of hydrogen as a fuel faces severe technological, economic, and environmental challenges. As method to overcome these challenges, microalgal biohydrogen production has become the subject growing research interest. Microalgal can be produced through different metabolic routes, economic considerations which are largely missing from recent reviews. Thus, this review briefly explains techniques economics associated with enhancing microalgae-based production. cost producing been estimated between $10 GJ-1 $20 GJ-1, is not competitive gasoline ($0.33 GJ-1). Even though direct biophotolysis sunlight conversion efficiency over 80%, its productivity sensitive oxygen availability. While electrochemical processes produce highest (>90%), fermentation photobiological more environmentally sustainable. Studies have revealed that quite high, ranging $2.13 kg-1 7.24 via biophotolysis, $1.42kg-1 indirect $7.54 7.61 fermentation. Therefore, low-cost technologies need developed ensure long-term sustainability requires optimization critical experimental parameters, engineering, genetic modification.

Язык: Английский

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Biohydrogen production from microalgae for environmental sustainability

Chemosphere, Год журнала: 2021, Номер 291, С. 132717 - 132717

Опубликована: Окт. 29, 2021

Язык: Английский

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