Reaction engineering during biomass gasification and conversion to energy

Verma, Shivpal; Dregulo, Andrei Mikhailovich; Kumar, Vinay; Bhargava, Preeti Chaturvedi; Khan, Nabeel; Singh, Anuradha; Sun, Xinwei; Sindhu, Raveendran; Binod, Parameswaran; Zhang, Zengqiang; Pandey, Ashok; Awasthi, Mukesh Kumar

doi:10.1016/j.energy.2022.126458

Cited by 29 publications

(5 citation statements)

References 181 publications

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“…The smart approaches may provide relevant insights [ 33 ], including on biohydrogen production with algal [ 34 ]. They are used too to promote a more circular economy [ 35 ], to predict and simulate alternative scenarios [ 36 ], as well as to analyse data [ 37 ] with useful outputs for agricultural and bioenergy productions [ 38 ]. Considering the vulnerability of the sources of biomass to the soil, weather conditions [ 39 ] and farming management [ 40 ], the prediction models play a crucial role in these frameworks.…”

Section: Systematic Literature Review On the Specific Contributions O...mentioning

confidence: 99%

Bioenergy relations with agriculture, forestry and other land uses: Highlighting the specific contributions of artificial intelligence and co-citation networks

Martinho,

Rodrigues

2024

Heliyon

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Section: Systematic Literature Review On the Specific Contributions O...mentioning

confidence: 99%

Bioenergy relations with agriculture, forestry and other land uses: Highlighting the specific contributions of artificial intelligence and co-citation networks

Martinho,

Rodrigues

2024

Heliyon

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“…The rate of the gasification process can be regulated by manipulating the flow rate of the gas (Luo et al, 2022). By employing this particular approach, it is possible to achieve a breakdown rate of up to 60% for forest biomass into hydrogen (Vuppaladadiyam et al, 2022;Gnanasekaran et al, 2023;Verma et al, 2023). The cost associated with the production of hydrogen from forest biomass via gasification is approximately 1.2-2.4 USD per kilogram of H2, which is over 50% lower compared to alternative methods (Lepage et al, 2021).…”

Section: Forest Biomass To Gaseous Biofuelsmentioning

confidence: 99%

A concise review of technologies for converting forest biomass to bioenergy

Raihan

2023

JTIE

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The use of biomass is vital in reducing the negative effects of rising fossil fuel consumption. Given its quantity and diversity, forest biomass has garnered a lot of interest among the many kinds of biomass. This study evaluates the various strategies for transforming woody waste into usable biofuels. Carbon dioxide emissions from traditional energy generation systems could be mitigated through the direct utilization of forest biomass. Low energy conversion rates, as well as soot emissions and residues, are some of the problems that come up when directly using forest biomass. The sustainability of direct energy generation from forest biomass is also seriously threatened by the lack of constant access to biomass. Co-combustion with coal and pelletizing biomass is two solutions proposed for this issue. Co-combustion of forest biomass with coal has the potential to lower the process's emissions of carbon monoxide, nitrogen oxides, and sulfides. This article reviews and discusses the biochemical and thermochemical mechanisms that can transform forest biomass into a variety of liquid and gaseous biofuels. Future research using cutting-edge sustainability assessment tools like life cycle assessment, exergy, etc. should investigate the sustainability of forest biomass conversion processes to bioenergy further.

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“…For brownfields contaminated with heavy metals, it is advisable to combine methods of phytoremediation (using higher plants to remove heavy mobile metals by the root system of plants) and bioenergy (after restoration of lands, use biomass as a renewable energy source) [92], for example, poplars [93], which, after phytoremediation, can be used to produce biodiesel for jet engines [94], including thermochemical methods of processing biomass into electricity [95,96]. The energy efficiency of the brownfield phytoremediation also has a multiplicative effect, which consists of reducing urban (anthropogenic) heat and sequestration of CO 2 [97].…”

Section: Integration Of Brownfields or Aed Into Ees And Ebs Stabilitymentioning

confidence: 99%

Brownfields, Environmental Stability and Renewable Energy: Pathways to Overcome the Imperfection of Cumulative Effect Assessment

Dregulo

2023

Energies

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Brownfields or objects of accumulated environmental damage are a complex object characterized by both the absorption and release of uncontrolled energy (for example, biogas or hydrothermal energy). The brownfield redevelopment process provides unique opportunities to ensure efficient energy transfer and maintain environmental stability. However, the implementation of these solutions depends on the quality of the assessment of the cumulative impact of unspent deposits, namely, the assessment of the damage caused to the environment, which, in turn, gives an understanding of how to ensure the elimination of damage to energy efficiency and environmental safety from uncontrolled carbon dioxide emissions. In this article, we consider the problems of assessing the cumulative effect of waste management activities, as a result of which abandoned deposits or objects of accumulated environmental damage appear. A cycle of measures to achieve socio-economic efficiency through the re-development of brownfields and their integration within energy-efficient systems and environmentally balanced systems is proposed, and a new concept of identifying the negative occurrence of brownfields under the influence of climate change is substantiated. Particularly, we assess the possibilities of integrating brownfields or objects of accumulated environmental damage into energy-efficient and environmentally balanced systems for goals of sustainable development.

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Reaction engineering during biomass gasification and conversion to energy

Cited by 29 publications

References 181 publications

Bioenergy relations with agriculture, forestry and other land uses: Highlighting the specific contributions of artificial intelligence and co-citation networks

Bioenergy relations with agriculture, forestry and other land uses: Highlighting the specific contributions of artificial intelligence and co-citation networks

A concise review of technologies for converting forest biomass to bioenergy

Brownfields, Environmental Stability and Renewable Energy: Pathways to Overcome the Imperfection of Cumulative Effect Assessment

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