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Journal articles on the topic 'Bio hydrogène'

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Author: Grafiati
Published: 5 October 2024

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1

Sathyaprakasan, Parvathy, and Geetha Kannan. "Economics of Bio-Hydrogen Production." International Journal of Environmental Science and Development 6, no. 4 (2015): 352–56. http://dx.doi.org/10.7763/ijesd.2015.v6.617.

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2

Jung, Yang-Sook, Sunhee Lee, Jaehyeung Park, and Eun-Joo Shin. "One-Shot Synthesis of Thermoplastic Polyurethane Based on Bio-Polyol (Polytrimethylene Ether Glycol) and Characterization of Micro-Phase Separation." Polymers 14, no. 20 (October 12, 2022): 4269. http://dx.doi.org/10.3390/polym14204269.

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In this study, a series of bio-based thermoplastic polyurethane (TPU) was synthesized via the solvent-free one-shot method using 100% bio-based polyether polyol, prepared from fermented corn, and 1,4-butanediol (BDO) as a chain extender. The average molecular weight, degree of phase separation, thermal and mechanical properties of the TPU-based aromatic (4,4-methylene diphenyl diisocyanate: MDI), and aliphatic (bis(4-isocyanatocyclohexyl) methane: H12MDI) isocyanates were investigated by gel permeation chromatography, Fourier transform infrared spectroscopy, atomic force microscopy, X-ray Diffraction, differential scanning calorimetry, dynamic mechanical thermal analysis, and thermogravimetric analysis. Four types of micro-phase separation forms of a hard segment (HS) and soft segment (SS) were suggested according to the [NCO]/[OH] molar ratio and isocyanate type. The results showed (a) phase-mixed disassociated structure between HS and SS, (b) hydrogen-bonded structure of phase-separated between HS and SS forming one-sided hard domains, (c) hydrogen-bonded structure of phase-mixed between HS, and SS and (d) hydrogen-bonded structure of phase-separated between HS and SS forming dispersed hard domains. These phase micro-structure models could be matched with each bio-based TPU sample. Accordingly, H-BDO-2.0, M-BDO-2.0, H-BDO-2.5, and M-BDO-3.0 could be related to the (a)—form, (b)—form, (c)—form, and (d)—form, respectively.
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3

Palaniswamy D, Palaniswamy D., Ramesh G. Ramesh G, Sri Pradeep M. Sri Pradeep M, and Ranjith Raja S. Ranjith Raja S. "Investigation of Bio-Wastes and Methods for the Production of Bio-Hydrogen – A Review." International Journal of Scientific Research 1, no. 5 (June 1, 2012): 60–62. http://dx.doi.org/10.15373/22778179/oct2012/20.

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4

Hendrawan and Kiyoshi Dowaki. "CO2 Emission Reduction Analysis of Bio-Hydrogen Network: An Initial Stage of Hydrogen Society." Journal of Clean Energy Technologies 3, no. 4 (2015): 296–301. http://dx.doi.org/10.7763/jocet.2015.v3.212.

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5

Ahmad, Syed A. R., Mritunjai Singh, and Archana Tiwari. "Review on Bio-hydrogen Production Methods." International Journal for Research in Applied Science and Engineering Technology 10, no. 3 (March 31, 2022): 610–14. http://dx.doi.org/10.22214/ijraset.2022.40679.

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Abstract: Hydrogen is a promising replacement for fossil fuels as a long-term energy source. It is a clean, recyclable, high efficient nature and environmentally friendly fuel. Hydrogen is now produced mostly using water electrolysis and natural gas steam reformation. However, biological hydrogen production has substantial advantages over thermochemical and electrochemical. Hydrogen can be produced biologically by bio-photolysis (direct and indirect), photo fermentation, dark fermentation. The methods for producing biological hydrogen were studied in this study. Keywords: Biological hydrogen, steam reformation, bio-photolysis, photo-fermentation, dark fermentation
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6

Abd-Elrahman, Nabil K., Nuha Al-Harbi, Yas Al-Hadeethi, Adel Bandar Alruqi, Hiba Mohammed, Ahmad Umar, and Sheikh Akbar. "Influence of Nanomaterials and Other Factors on Biohydrogen Production Rates in Microbial Electrolysis Cells—A Review." Molecules 27, no. 23 (December 6, 2022): 8594. http://dx.doi.org/10.3390/molecules27238594.

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Microbial Electrolysis Cells (MECs) are one of the bioreactors that have been used to produce bio-hydrogen by biological methods. The objective of this comprehensive review is to study the effects of MEC configuration (single-chamber and double-chamber), electrode materials (anode and cathode), substrates (sodium acetate, glucose, glycerol, domestic wastewater and industrial wastewater), pH, temperature, applied voltage and nanomaterials at maximum bio-hydrogen production rates (Bio-HPR). The obtained results were summarized based on the use of nanomaterials as electrodes, substrates, pH, temperature, applied voltage, Bio-HPR, columbic efficiency (CE) and cathode bio-hydrogen recovery (C Bio-HR). At the end of this review, future challenges for improving bio-hydrogen production in the MEC are also discussed.
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7

Fang, H. H. P., H. Liu, and T. Zhang. "Bio-hydrogen production from wastewater." Water Supply 4, no. 1 (February 1, 2004): 77–85. http://dx.doi.org/10.2166/ws.2004.0009.

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The technically feasibility of converting organic pollutants in wastewater into hydrogen by a continuous two-step process was demonstrated. Two carbohydrates, i.e. glucose and sucrose, in wastewater were respectively acidified by dark fermentation at pH 5.5 with 6–6.6 hours of hydraulic retention in a 3-l fermentor, producing an effluent containing mostly acetate and butyrate, and a methane-free biogas comprising mostly hydrogen. The acidified effluent was then further treated by photo fermentation for hydrogen production. The overall yield based on the substrate consumed was 31–32%, i.e. 17–18% for dark fermentation and 14% for photo fermentation. It was found that under certain dark fermentation conditions, hydrogen-producing sludge was agglutinated into granules, resulting in a higher biomass density and increased volumetric hydrogen production efficiency. DNA-based analysis of microbial communities revealed that the respective predominant bacteria were Clostridium in dark fermentation and Rhodobacter in photo fermentation. Further investigations are warranted, particularly, in areas such as improving reactor design, treating protein and lipid rich wastewaters, and studying sludge granulation mechanisms and controlling factors.
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8

Wu, Sheng, Haotian Zhu, Enrui Bai, Chongyang Xu, Xiaoyin Xie, and Chuanyu Sun. "Composite Modified Graphite Felt Anode for Iron–Chromium Redox Flow Battery." Inventions 9, no. 5 (September 9, 2024): 98. http://dx.doi.org/10.3390/inventions9050098.

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The iron–chromium redox flow battery (ICRFB) has a wide range of applications in the field of new energy storage due to its low cost and environmental protection. Graphite felt (GF) is often used as the electrode. However, the hydrophilicity and electrochemical activity of GF are poor, and its reaction reversibility to Cr3+/Cr2+ is worse than Fe2+/Fe3+, which leads to the hydrogen evolution side reaction of the negative electrode and affects the efficiency of the battery. In this study, the optimal composite modified GF (Bi-Bio-GF-O) electrode was prepared by using the optimal pomelo peel powder modified GF (Bio-GF-O) as the matrix and further introducing Bi3+. The electrochemical performance and material characterization of the modified electrode were analyzed. In addition, using Bio-GF-O as the positive electrode and Bi-Bio-GF-O as the negative electrode, the high efficiency of ICRFB is realized, and the capacity attenuation is minimal. When the current density is 100 mA·cm−2, after 100 cycles, the coulomb efficiency (CE), voltage efficiency (VE), and energy efficiency (EE) were 97.83%, 85.21%, and 83.36%, respectively. In this paper, the use of pomelo peel powder and Bi3+ composite modified GF not only promotes the electrochemical performance and reaction reversibility of the negative electrode but also improves the performance of ICRFB. Moreover, the cost of the method is controllable, and the process is simple.
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9

Zuo, J., Y. Zuo, W. Zhang, and J. Chen. "Anaerobic bio-hydrogen production using pre-heated river sediments as seed sludge." Water Science and Technology 52, no. 10-11 (November 1, 2005): 31–39. http://dx.doi.org/10.2166/wst.2005.0676.

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Anaerobic bio-hydrogen production is the focus in the field of bio-energy resources. In this paper, a series of batch experiments were conducted to investigate the effects of several factors on anaerobic bio-hydrogen producing process carried out by pre-heated river sediments. The results showed that several factors such as substrate and its concentration, temperature and the initial pH value could affect the anaerobic bio-hydrogen production in different levels. At 35°C and the initial pH of 6.5, using glucose of 20,000mg COD/L as substrate, the highest hydrogen production of 323.8ml-H2/g TVS in a 100ml batch reactor was reached, the specific hydrogen production rate was 37.7ml-H2/g TVSh, and the hydrogen content was 51.2%. Thereafter using the same pre-heated river sediments as seed sludge, continuous anaerobic bio-hydrogen production was achieved successfully in a lab-scale CSTR with gas-separator. At the organic loading rate of 36kg COD/m3d, the highest hydrogen production was 6.3–6.7l-H2/l-reactord, the specific hydrogen production was 1.3–1.4mol-H2/mol-glucose, and the hydrogen content in the gas was 52.3%. The effluent of the bio-reactor contained some small molecular organics, mainly including ethanol, acetate, butyrate and their molar proportion is 1 : 1 : 0.6.
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10

Li, Yong Feng, Jing Wei Zhang, Wei Han, Jian Yu Yang, Yong Juan Zhang, and Zhan Qing Wang. "Review on Engineering of Fermentative Bio-Hydrogen Production." Advanced Materials Research 183-185 (January 2011): 193–96. http://dx.doi.org/10.4028/www.scientific.net/amr.183-185.193.

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The paper not only reviews the progress of engineering and application on bio-hydrogen production, but also discusses characteristics, advantages and disadvantages of biological hydrogen production systems. Meanwhile, it mainly analyzes anaerobic fermentative bio-hydrogen production systems’ technological schemes, design strategies, engineering control parameters, fermentation control, fuel cell, technical means to increase hydrogen evolution and its rate. Under the guidance of the theory of ethanol-type fermentation, the fermentative bio-hydrogen production systems have been established in practice.
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11

Wang, Jingliang, Shanshan Wang, Jianwen Lu, Mingde Yang, and Yulong Wu. "Improved Bio-Oil Quality from Pyrolysis of Pine Biomass in Pressurized Hydrogen." Applied Sciences 12, no. 1 (December 21, 2021): 46. http://dx.doi.org/10.3390/app12010046.

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The pyrolysis of pine sawdust was carried out in a fixed bed reactor heated from 30 °C to a maximum of 700 °C in atmospheric nitrogen and pressurized hydrogen (5 MPa). The yield, elemental composition, thermal stability, and composition of the two pyrolysis bio-oils were analyzed and compared. The result shows that the oxygen content of the bio-oil (17.16%) obtained under the hydrogen atmosphere was lower while the heating value (31.40 MJ/kg) was higher than those of bio-oil produced under nitrogen atmosphere. Compounds with a boiling point of less than 200 °C account for 63.21% in the bio-oil at pressurized hydrogen atmosphere, with a proportion 14.69% higher than that of bio-oil at nitrogen atmosphere. Furthermore, the hydrogenation promoted the formation of ethyl hexadecanoate (peak area percentage 19.1%) and ethyl octadecanoate (peak area percentage 15.42%) in the bio-oil. Overall, high pressure of hydrogen improved the bio-oil quality derived from the pyrolysis of pine biomass.
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12

Singh Yadav, Vinod, Vinoth R, and Dharmesh Yadav. "Bio-hydrogen production from waste materials: A review." MATEC Web of Conferences 192 (2018): 02020. http://dx.doi.org/10.1051/matecconf/201819202020.

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When hydrogen burns in air, it produces nothing but water vapour. It is therefore the cleanest possible, totally non-polluting fuel. This fact has led some people to propose an energy economy based entirely on hydrogen, in which hydrogen would replace gasoline, oil, natural gas, coal, and nuclear power. Hydrogen is a clean energy source. Therefore, in recent years, demand on hydrogen production has increased considerably. Electrolysis of water, steam reforming of hydrocarbons and auto-thermal processes are well-known methods for hydrogen gas production, but not cost-effective due to high energy requirements. As compare to chemical methods, biological production of hydrogen gas has significant advantages such as bio-photolysis of water by algae, dark and photo-fermentation of organic materials, usually carbohydrates by bacteria. New approach for bio-hydrogen production is dark and photo-fermentation process but with some major problems like dark and photo-fermentative hydrogen production is the raw material cost. By using suitable bio-process technologies hydrogen can be produced through carbohydrate rich, nitrogen deficient solid wastes such as cellulose and starch containing agricultural and food industry wastes and some food industry wastewaters such as cheese whey, olive mill and baker's yeast industry wastewaters. Utilization of aforementioned wastes for hydrogen production provides inexpensive energy generation with simultaneous waste treatment. This review article summarizes bio-hydrogen production from some waste materials with recent developments and relative advantages.
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13

Wodołażski, Artur, and Adam Smoliński. "Bio-Hydrogen Production in Packed Bed Continuous Plug Flow Reactor—CFD-Multiphase Modelling." Processes 10, no. 10 (September 20, 2022): 1907. http://dx.doi.org/10.3390/pr10101907.

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This research study investigates the modelling and simulation of biomass anaerobic dark fermentation in bio-hydrogen production in a continuous plug flow reactor. A CFD multiphase full transient model in long-term horizons was adopted to model dark fermentation biohydrogen production in continuous mode. Both the continuous discharge of biomass, which prevents the accumulation of solid parts, and the recirculation of the liquid phase ensure constant access to the nutrient solution. The effect of the hydraulic retention time (HRT), pH and the feed rate on the bio-hydrogen yield and production rates were examined in the simulation stage. Metabolite proportions (VFA: acetic, propionic, butyric) constitute important parameters influencing the bio-hydrogen production efficiency. The model of substrate inhibition on bio-hydrogen production from glucose by attached cells of the microorganism T. neapolitana applied to the modelling of the kinetics of bio-hydrogen production was used. The modelling and simulation of a continuous plug flow (bio)reactor in biohydrogen production is an important part of the process design, modelling and optimization of the biological H2 production pathway.
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14

Saad Hussain Khudair, Amal Abdul Nabi Haloob, Iman Hindi Qatia, and Ameena Ghazi Abid. "Biological treatment of organic waste polluting the environment and bio-hydrogen production." Journal of Wasit for Science and Medicine 8, no. 3 (December 9, 2022): 26–30. http://dx.doi.org/10.31185/jwsm.261.

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Thirty four local isolates of bio-hydrogen producing anaerobic bacteria were isolated from samples of solid waste of sewage plants from different regions using liquid and solid mineral salt medium at initial pH of 7 and incubated at 37 ºC for 72 hr. .The ability of isolates was tested to produce bio-hydrogen, using liquid production medium. Results indicate that the bio-hydrogen production in 25 isolates cannot be detected, while 9 isolates showed the ability to produce bio-hydrogen and that theAn-18 isolate showed the highest level of bio-hydrogen production(34 ppm) after 72 hr. of incubation at 37 ºC. Anaerobic isolates producing bio-hydrogen were identified based on morphological characteristics and some biochemical tests, results showed that 7isolates belong to the genus Actinomycessp.and only two isolates belong to the genus Clostridium sp., Then prepared the mixed culture from 7 isolates and subsequently was used as inoculums for hydrogen production medium. Inoculated the bioreactor containing the residues of agricultural and household by mixed culture (1 ml/ 50 ml medium) at initial pH of 7 and incubated at 37 ºC by using water bath for 20 days ,and subsequently was estimated the amount of hydrogen produced in every day. The results showed that hydrogen production was started from the second day (12 ppm) andreached its maximum production for the period from 14-17 days after the start of the experiment.
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15

Hemmati, Sadaf, M. Mostafa Elnegihi, Chee Hoong Lee, Darren Yu Lun Chong, Dominic C. Y. Foo, Bing Shen How, and ChangKyoo Yoo. "Synthesis of Large-Scale Bio-Hydrogen Network Using Waste Gas from Landfill and Anaerobic Digestion: A P-Graph Approach." Processes 8, no. 5 (April 26, 2020): 505. http://dx.doi.org/10.3390/pr8050505.

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Due to the expanding concern on cleaner production and sustainable development aspects, a technology shift is needed for the hydrogen production, which is commonly derived from natural gas. This work aims to synthesise a large-scale bio-hydrogen network in which its feedstock, i.e., bio-methane, is originated from landfill gas and palm oil mill effluent (POME). Landfill gas goes through a biogas upgrader where high-purity bio-methane is produced, while POME is converted to bio-methane using anaerobic digestor (AD). The generated bio-methane is then distributed to the corresponding hydrogen sink (e.g., oil refinery) through pipelines, and subsequently converted into hydrogen via steam methane reforming (SMR) process. In this work, P-graph framework is used to determine a supply network with minimum cost, while ensuring the hydrogen demands are satisfied. Two case studies in the West and East Coasts of Peninsular Malaysia are used to illustrate the feasibility of the proposed model. In Case Study 1, four scenarios on the West Coast have been considered, showing total cost saving ranging between 25.9% and 49.5%. This showed that aside from the positive environmental impact, the incorporation of bio-hydrogen supply can also be economically feasible. Such benefits can also be seen in Case Study 2, where the uptake of biogas from landfill and POME sources on the East Coast can lead to a 31% reduction on total network cost. In addition, the effect of bio-hydrogen supply network on carbon footprint reduction was analysed in this work.
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16

Prestipino, Mauro, Antonio Piccolo, Maria Francesca Polito, and Antonio Galvagno. "Combined Bio-Hydrogen, Heat, and Power Production Based on Residual Biomass Gasification: Energy, Exergy, and Renewability Assessment of an Alternative Process Configuration." Energies 15, no. 15 (July 29, 2022): 5524. http://dx.doi.org/10.3390/en15155524.

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Bio-hydrogen from residual biomass may involve energy-intensive pre-treatments for drying and size management, as in the case of wet agro-industrial residues. This work assesses the performance of an alternative process layout for bio-hydrogen production from citrus peel gasification, with the aim of cogenerating heat and power along with hydrogen, using minimal external energy sources. The process consists of an air-steam fluidized bed reactor, a hydrogen separation unit, a hydrogen compression unit, and a combined heat and power unit fed by the off-gas of the separation unit. Process simulations were carried out to perform sensitivity analyses to understand the variation in bio-hydrogen production’s thermodynamic and environmental performance when the steam to biomass ratios (S/B) vary from 0 to 1.25 at 850 °C. In addition, energy and exergy efficiencies and the integrated renewability (IR) of bio-hydrogen production are evaluated. As main results, the analysis showed that the highest hydrogen yield is 40.1 kgH2 per mass of dry biomass at S/B = 1.25. Under these conditions, the exergy efficiency of the polygeneration system is 33%, the IR is 0.99, and the carbon footprint is −1.9 kgCO2-eq/kgH2. Negative carbon emissions and high values of the IR are observed due to the substitution of non-renewable resources operated by the cogenerated streams. The proposed system demonstrated for the first time the potential of bio-hydrogen production from citrus peel and the effects of steam flow variation on thermodynamic performance. Furthermore, the authors demonstrated how bio-hydrogen could be produced with minimal external energy input while cogenerating net heat and power by exploiting the off-gas in a cogeneration unit.
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17

Marks, Stanislaw, Jacek Dach, Jose Luis Garcia-Morales, and Francisco Jesus Fernandez-Morales. "Bio-Energy Generation from Synthetic Winery Wastewaters." Applied Sciences 10, no. 23 (November 25, 2020): 8360. http://dx.doi.org/10.3390/app10238360.

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In Spain, the winery industry exerts a great influence on the national economy. Proportional to the scale of production, a significant volume of waste is generated, estimated at 2 million tons per year. In this work, a laboratory-scale reactor was used to study the feasibility of the energetic valorization of winery effluents into hydrogen by means of dark fermentation and its subsequent conversion into electrical energy using fuel cells. First, winery wastewater was characterized, identifying and determining the concentration of the main organic substrates contained within it. To achieve this, a synthetic winery effluent was prepared according to the composition of the winery wastewater studied. This effluent was fermented anaerobically at 26 °C and pH = 5.0 to produce hydrogen. The acidogenic fermentation generated a gas effluent composed of CO2 and H2, with the percentage of hydrogen being about 55% and the hydrogen yield being about 1.5 L of hydrogen at standard conditions per liter of wastewater fermented. A gas effluent with the same composition was fed into a fuel cell and the electrical current generated was monitored, obtaining a power generation of 1 W·h L−1 of winery wastewater. These results indicate that it is feasible to transform winery wastewater into electricity by means of acidogenic fermentation and the subsequent oxidation of the bio-hydrogen generated in a fuel cell.
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18

Tandon, Mona, Shailesh Kumar Jadhav, and Kishan Lal Tiwari. "Optimization of pH and temperature for efficient bio-hydrogen production from lignocellulosic waste." NewBioWorld 1, no. 2 (December 31, 2019): 28–32. http://dx.doi.org/10.52228/nbw-jaab.2019-1-2-6.

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Biomass is the chief source of bio-hydrogen production which includes agricultural crops as well as their residues, various effluents generated in human habitat, aquatic plants and algae, and by-products released during food processing. Bio-hydrogen is selectively produced from biomass because of its cost-effectiveness, easy availability, high carbohydrate content and their ease of biodegradability. This research paper includes optimization of pH and temperature on bio-hydrogen producing capacity and their effect on bacterial growth.
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19

Tandon, Mona, Veena Thakur, Kunjlata Sao, and Shailesh Kumar Jadhav. "Water hyacinth producing bio-hydrogen by Klebsiella oxytoca ATCC 13182 and their optimization." NewBioWorld 1, no. 1 (July 31, 2019): 1–4. http://dx.doi.org/10.52228/nbw-jaab.2019-1-1-1.

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Our energy requirements are almost totally provided by carbon containing fossil sources such as oil, coal and nature gas, but they cause serious environmental problems during combustion such as CO2 emission and climate changes. Bio-hydrogen production from Klebsiella oxytoca ATCC 13182 and water hyacinth was taken as a substrate. Water hyacinth are good source of cellulose and hemicelluloses content used for bio-hydrogen production. This research paper includes the effect of age of inoculation, volume of inoculation and acid pre-treatment (concentrated sulfhuric acid) on bio-hydrogen production along with their specific hydrogen production rate (SHPR), carbon consuming efficiency (CCE) and pH.
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20

Ding, Zhijun, Yang Liu, Xin Yao, Yuekai Xue, Chenxiao Li, Zhihui Li, Shuhuan Wang, and Jianwei Wu. "Thermodynamic Analysis of Hydrogen Production from Bio-Oil Steam Reforming Utilizing Waste Heat of Steel Slag." Processes 11, no. 8 (August 3, 2023): 2342. http://dx.doi.org/10.3390/pr11082342.

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(1) Background: The discharged temperature of steel slag is up to 1450 °C, representing heat having a high calorific value. (2) Motivation: A novel technology, integrating bio-oil steam reforming with waste heat recovery from steel slag for hydrogen production, is proposed, and it is demonstrated to be an outstanding method via thermodynamic calculation. (3) Methods: The equilibrium productions of bio-oil steam reforming in steel slag under different temperatures and S/C ratios (the mole ratio of steam to carbon) are obtained by the method of minimizing the Gibbs free energy using HSC 6.0. (4) Conclusions: The hydrogen yield increases first and then decreases with the increasing temperature, but it increases with the increasing S/C. Considering equilibrium calculation and actual application, the optimal temperature and S/C are 706 °C and 6, respectively. The hydrogen yield and hydrogen component are 109.13 mol/kg and 70.21%, respectively, and the carbon yield is only 0.08 mol/kg under optimal conditions. Compared with CaO in steel slag, iron oxides have less effect on hydrogen production from bio-oil steam reforming in steel slag. The higher the basicity of steel slag, the higher the obtained hydrogen yield and hydrogen component of bio-oil steam reforming in steel slag. It is demonstrated that appropriately decreasing iron oxides and increasing basicity could promote the hydrogen yield and hydrogen component of bio-oil steam reforming that utilizes steel slag as a heat carrier during the industrial application.
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21

He, Chao, Baoyi Qi, Youzhou Jiao, Quanguo Zhang, Xiaoran Ma, Gang Li, Yanyan Jing, Danping Jiang, and Zhiping Zhang. "Potentials of bio-hydrogen and bio-methane production from diseased swines." International Journal of Hydrogen Energy 45, no. 59 (December 2020): 34473–82. http://dx.doi.org/10.1016/j.ijhydene.2019.08.215.

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22

Yung-Tse Hung, Sanad AlBurgan, Howard H Paul, and Christopher R Huhnke. "Combined bioprocess for fermentative hydrogen production from food waste: A review." Global Journal of Engineering and Technology Advances 20, no. 2 (August 30, 2024): 120–24. http://dx.doi.org/10.30574/gjeta.2024.20.2.0152.

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Bio hydrogen is a cheaper, sustainable and safer source to produce fuel comparable to energy obtained from fossil fuels. There are many experimental methods to produce bio hydrogen using food wastes as substrates that are acted upon by specific bacterial and fungal strains. Some of the methods include batch-dark fermentation, solid-state dark fermentation, dark-anaerobic hydrogen fermentation and integrated light-dark fermentation. Different food wastes are used in these fermentation processes such as kitchen food waste, potatoes peels, sugary waste water, fish, meats, grains, cassava residues, corn pulp and starchy solution etc. These food wastes are rich source of main raw materials that are required for bio hydrogen production such as cellulose, carbohydrates, fats, proteins, lipids, starch, phosphorus, volatile solids, Published experimental and research approaches revealed that the use of mixed dark-photo fermentative bacterial consortium in flat photo bioreactors and fermenters resulted in higher yield. Combined dark-photo fermentation is an advanced and promising strategy for increasing overall yield of bio hydrogen.
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23

Mayorga, "M A. "., "J G. ". Cadavid, "O Y. ". Suárez, "J C. ". Vargas, "C J. ". Castellanos, "L A. ". Suárez, and "P C. ". Narváez. "Bio-hydrogen production using metallic catalysts." Revista Mexicana de Ingeniería Química 19, no. 3 (March 1, 2020): 1103–15. http://dx.doi.org/10.24275/rmiq/cat652.

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24

Jayalakshmi, S., Kurian Joseph, and V. Sukumaran. "Bio hydrogen production from kitchen waste." International Journal of Environment and Waste Management 2, no. 1/2 (2008): 75. http://dx.doi.org/10.1504/ijewm.2008.016993.

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25

Xia, Ao, Amita Jacob, Christiane Herrmann, and Jerry D. Murphy. "Fermentative bio-hydrogen production from galactose." Energy 96 (February 2016): 346–54. http://dx.doi.org/10.1016/j.energy.2015.12.087.

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26

Schollhammer, Philippe, Jean Talarmin, Philippe Schollhammer, and Jean Talarmin. "Bio-inspired hydrogen production/uptake catalysis." Comptes Rendus Chimie 11, no. 8 (August 2008): 789. http://dx.doi.org/10.1016/j.crci.2008.04.007.

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27

Bo, Wang, Liu Yongye, Qiao Yahua, Yang Yang, Shi Qiang, Wan Wei, and Wang Jianlong. "Technology Research on Bio-Hydrogen Production." Procedia Engineering 43 (2012): 53–58. http://dx.doi.org/10.1016/j.proeng.2012.08.010.

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28

Lin, Chiu-Yue, Jun Miyake, and Alissara Reungsang. "Preface – 4th Asian Bio-Hydrogen Symposium." International Journal of Hydrogen Energy 36, no. 14 (July 2011): 8680. http://dx.doi.org/10.1016/j.ijhydene.2011.05.123.

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29

Kapdan, Ilgi Karapinar, and Fikret Kargi. "Bio-hydrogen production from waste materials." Enzyme and Microbial Technology 38, no. 5 (March 2006): 569–82. http://dx.doi.org/10.1016/j.enzmictec.2005.09.015.

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30

Patel, Ronak, and Sanjay Patel. "Process Development for Bio-butanol Steam Reforming for PEMFC Application." International Journal of Engineering & Technology 7, no. 4.5 (September 22, 2018): 110. http://dx.doi.org/10.14419/ijet.v7i4.5.20023.

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In current study, process has been developed for hydrogen production from bio-butanol via steam reforming (SR) for proton exchange membrane fuel cell (PEMFC) application. Heat integration with pinch analysis method was carried out to reduce overall heating and cooling utility requirement of energy intensive SR process. Despite of highly endothermic nature of bio-butanol SR, process found to be self-sustained in terms of requirement of heating utility. Heat integrated process for hydrogen production from bio-butanol SR was found to be green process, which can be explored for its hydrogen production capacity.
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31

Reza, Md Sumon, Ashfaq Ahmed, Wahyu Caesarendra, Muhammad S. Abu Bakar, Shahriar Shams, R. Saidur, Navid Aslfattahi, and Abul K. Azad. "Acacia Holosericea: An Invasive Species for Bio-char, Bio-oil, and Biogas Production." Bioengineering 6, no. 2 (April 16, 2019): 33. http://dx.doi.org/10.3390/bioengineering6020033.

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To evaluate the possibilities for biofuel and bioenergy production Acacia Holosericea, which is an invasive plant available in Brunei Darussalam, was investigated. Proximate analysis of Acacia Holosericea shows that the moisture content, volatile matters, fixed carbon, and ash contents were 9.56%, 65.12%, 21.21%, and 3.91%, respectively. Ultimate analysis shows carbon, hydrogen, and nitrogen as 44.03%, 5.67%, and 0.25%, respectively. The thermogravimetric analysis (TGA) results have shown that maximum weight loss occurred for this biomass at 357 °C for pyrolysis and 287 °C for combustion conditions. Low moisture content (<10%), high hydrogen content, and higher heating value (about 18.13 MJ/kg) makes this species a potential biomass. The production of bio-char, bio-oil, and biogas from Acacia Holosericea was found 34.45%, 32.56%, 33.09% for 500 °C with a heating rate 5 °C/min and 25.81%, 37.61%, 36.58% with a heating rate 10 °C/min, respectively, in this research. From Fourier transform infrared (FTIR) spectroscopy it was shown that a strong C–H, C–O, and C=C bond exists in the bio-char of the sample.
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32

Rena, K. Mohammed Bin Zacharia, Shraddha Yadav, Nitesh Premchand Machhirake, Sang-Hyoun Kim, Byung-Don Lee, Heondo Jeong, Lal Singh, Sunil Kumar, and Rakesh Kumar. "Bio-hydrogen and bio-methane potential analysis for production of bio-hythane using various agricultural residues." Bioresource Technology 309 (August 2020): 123297. http://dx.doi.org/10.1016/j.biortech.2020.123297.

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33

Tymchyshyn, Matthew, Zhongshun Yuan, and Chunbao (Charles) Xu. "Reforming of Glycerol into Bio-Crude: A Parametric Study." International Journal of Chemical Reactor Engineering 11, no. 1 (June 18, 2013): 69–81. http://dx.doi.org/10.1515/ijcre-2012-0033.

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Abstract The reforming of glycerol was investigated using a micro-reactor in the presence of MoCoP/zeolite catalyst. The parameters which were investigated include initial hydrogen pressure, reaction temperature, residence time, and feedstock concentration. The liquid products were separated into water-soluble components and bio-oil by liquid-liquid extraction with water and ethyl acetate. The bio-oil, gaseous products, char, and unreacted glycerol were quantified relative to the initial mass of glycerol feed. The composition of the bio-oil was determined by GC/MS. The optimum conditions for the reforming of glycerol into bio-crude in the presence of MoCoP/zeolite catalyst were found to be: 300°C reaction temperature, 5 MPa initial hydrogen pressure, 60 min reaction time, and 100% glycerol feed. While dilution of the glycerol feedstock with water had a negative effect on bio-oil yield, reforming of pure glycerol produced the highest bio-oil yield (40 wt.% at 300°C, 1 h, and 5 MPa H2). The amount of char deposited on the catalyst decreased with extended reaction time, increased reaction temperature, and elevated initial hydrogen pressure.
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KINOUCHI, KOUJI, MASAHIRO KATOH, TOSHIHIDE HORIKAWA, TAKUSHI YOSHIKAWA, and MAMORU WADA. "HYDROGEN PERMEABILITY OF PALLADIUM MEMBRANE FOR STEAM-REFORMING OF BIO-ETHANOL USING THE MEMBRANE REACTOR." International Journal of Modern Physics: Conference Series 06 (January 2012): 7–12. http://dx.doi.org/10.1142/s2010194512002851.

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A Palladium membrane was prepared by electro-less plating method on porous stainless steel. The catalytic hydrogen production by steam-reforming of biomass-derived ethanol (bio-ethanol) using a Pd membrane was analyzed by comparing it with those for the reaction using reagent ethanol (the reference sample). And the hydrogen permeability of the palladium membrane was investigated using the same palladium membrane ( H 2/ He selectivity = 249, at ΔP = 0.10 MPa, 873 K). As a result, for bio-ethanol, deposited carbon had a negative influence on the hydrogen-permeability of the palladium membrane and hydrogen purity. The sulfur content in the bio-ethanol may have promoted carbon deposition. By using a palladium membrane, it was confirmed that H 2 yield (%) was increased. It can be attributed that methane was converted from ethanol and produced more hydrogen by steam reforming, due to the in situ removal of hydrogen from the reaction location.
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35

Wang, Bing, Rui Xiao, and Huiyan Zhang. "An Overview of Bio-oil Upgrading with High Hydrogen-containing Feedstocks to Produce Transportation Fuels: Chemistry, Catalysts, and Engineering." Current Organic Chemistry 23, no. 7 (July 16, 2019): 746–67. http://dx.doi.org/10.2174/1385272823666190405145007.

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As an alternative to increasingly depleted traditional petroleum fuel, bio-oil has many advantages: high energy density, flexibility, easy storage and transportation. Nevertheless, bio-oil also presents some unwanted characteristics such as high viscosity, acidity, oxygen content and chemical instability. The process of bio-oil upgrading is necessary before utilization as transportation fuels. In addition, the bio-oil has low effective hydrogen/ carbon molar ratio (H/Ceff) which may lead to coke formation and hence deactivation of the catalyst during the upgrading process. Therefore, it seemed that co-refining of biooil with other higher hydrogen-containing feedstocks is necessary. This paper provides a broad review of the bio-oil upgrading with high hydrogen-containing feedstocks to produce transportation fuels: chemistry, catalyst, and engineering research aspects were discussed. The different thermochemical conversion routes to produce bio-oil and its physical-chemical properties are discussed firstly. Then the bio-oil upgrading research using traditional technologies and common catalysts that emerged in recent years are briefly reviewed. Furthermore, the applications of high H/Ceff feedstock to produce high-quality of bio-oil are also discussed. Moreover, the emphasis is placed on co-refining technologies to produce transportation fuels. The processes of co-refining bio-oil and vacuum gas oil in fluid catalytic cracking (FCC) unit for transportation fuels from laboratory scale to pilot scale are also covered in this review. Co-refining technology makes it possible for commercial applications of bio-oil. Finally, some suggestions and prospects are put forward.
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36

Ding, Zhijun, Yang Liu, Xin Yao, Yuekai Xue, Chenxiao Li, Zhihui Li, Shuhuan Wang, and Jianwei Wu. "The Thermodynamic Characterizations of Hydrogen Production from Catalyst-Enhanced Steam Reforming of Bio-Oil over Granulated Blast Furnace Slag as Heat Carrier." Processes 11, no. 8 (August 3, 2023): 2341. http://dx.doi.org/10.3390/pr11082341.

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To promote the efficiency of waste heat recovery from granulated blast furnace (BF) slag, a novel method of catalyst-enhanced steam reforming of bio-oil to recover heat from slag is proposed. CaO is utilized as a superior catalyst for the process of catalyst-enhanced steam reforming. The thermodynamic production of the catalyst-enhanced steam reforming of bio-oil in granulated BF slag is obtained using HSC 6.0 software. The optimal conditions are mainly assessed according to the hydrogen yield, hydrogen concentration and carbon production. Through the thermodynamic production and industrial application, the temperature of 608 °C, S/C of eight and pressure of 1 bar are found as the optimal conditions. At the optimal conditions, the hydrogen yield, hydrogen concentration and carbon production are 95.25%, 76.89% and 0.28 mol/kg, respectively. Taking the temperature of 625 °C, S/C of eight and pressure of 1 bar as an example, the catalyst could improve the hydrogen yield and hydrogen concentration from 93.99% and 70.31% to 95.15% and 76.49%, respectively. It is implied that utilizing the catalyst could promote the hydrogen yield and hydrogen concentration of steam reforming of bio-oil to recover waste heat from granulated BF slag. The mechanism of catalyst-enhanced steam reforming of bio-oil to recover waste heat from granulated BF slag is obtained to guide the subsequent industry application.
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37

Nusaibah, Nusaibah, Khaswar Syamsu, and Dwi Susilaningsih. "Bio-hydrogen Production From Vinasse By Using Agent Fermentation Of Photosynthetic Bacteria Rhodobium marinum." Indonesian Journal of Environmental Management and Sustainability 4, no. 1 (March 29, 2020): 23–27. http://dx.doi.org/10.26554/ijems.2020.4.1.23-27.

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The aim of this research was to find out the effect of substrate concentrations (COD) of vinasse and the length of fermentation time to bio-hydrogen gas production using agent fermentation of photosynthetic bacteria, Rhodobium marinum. The production of bio-hydrogen was examined by varying COD of vinasse (10,000; 20,000; 30,000; 40,000; 50,000 mg COD/L) at certain fermentation time in the third, sixth and ninth day. The highest Hydrogen gas was obtained at ninth day of fermentation (82.66±18.6 mL). The highest Hydrogen Production Rate (HPR) and COD removal rate were obtained at concentration 50,000 mg COD/L, namely 109.98 mL H2/L/d and 1437.66 mg COD/L/d, respectively. Thus it can be concluded, the concentration of substrates (COD) from vinasse and the length of fermentation time have an effect on production of bio-hydrogen gas using Rhodobium marinum
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38

Yue, Xiao Fang, Hong Yuan Sun, Xu Xin Zhao, and Li Qing Zhao. "Research Progress of Food Waste Fermentation for Bio-Hydrogen Production." Advanced Materials Research 550-553 (July 2012): 569–73. http://dx.doi.org/10.4028/www.scientific.net/amr.550-553.569.

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Hydrogen is a valuable gas as a clean energy source and as feedstock for some industries. Therefore, demand on hydrogen production has increased considerably in recent years. Food waste is an important part of urban living garbage,which is full of organic matter and easy to be degraded. So, biological production of hydrogen gas from food waste fermentation has significant advantages for providing inexpensive and clean energy generation to help meet the needs of carbon emission reduction with simultaneous waste treatment. This article reviews the following aspects: mechanism of fermentative hydrogen production by bacteria, and factors influencing fermentative bio-hydrogen production. In addition,the challenges and prospects of bio- hydrogen production are also reviewed.
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39

Kritzinger, Niel, Ravi Ravikumar, Sunil Singhal, Katie Johnson, and Kakul Singh. "Blue hydrogen production: a case study to quantify the reduction in CO2 emission in a steam methane reformer based hydrogen plant." APPEA Journal 59, no. 2 (2019): 619. http://dx.doi.org/10.1071/aj18164.

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In Australia, and globally, hydrogen is primarily produced from natural gas via steam methane reforming. This process also produces CO2, which is typically vented to the atmosphere. Under this configuration, the hydrogen produced is known as grey hydrogen (carbon producing). However, if the CO2 from this process is captured and stored after it is produced, the hydrogen product is CO2-neutral, or ‘blue hydrogen’. To enable production of blue hydrogen from existing natural gas steam methane reformers (SMRs) in Australia, gasification of biomass/bio waste can be utilised to produce fuel gas for use in a SMR-based hydrogen plant, and the CO2 in the shifted syngas can be removed as pure CO2 either for sequestration, enhanced oil recovery, or enhanced coal bed methane recovery. Australian liquefied natural gas that is exported and utilised as feedstock to existing SMRs in other countries can incorporate carbon emission reduction techniques for blue hydrogen production. The use of bio-derived syngas as fuel will generate hydrogen with only bio-derived CO2 emissions. Additional carbon credit can be obtained by replacing petrol or diesel consuming automobiles with fuel cell vehicles powered by hydrogen derived from gasification of biomass.
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40

Jiang, Pei-wen, Xiao-ping Wu, Jun-xu Liu, and Quan-xin Li. "Preparation of Bio-hydrogen and Bio-fuels from Lignocellulosic Biomass Pyrolysis-Oil." Chinese Journal of Chemical Physics 29, no. 5 (October 27, 2016): 635–43. http://dx.doi.org/10.1063/1674-0068/29/cjcp1603056.

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41

SHINTANI, HIDEHARU. "Application of Vapor Phase Hydrogen Peroxide Sterilization to Endoscope." Biocontrol Science 14, no. 1 (2009): 39–45. http://dx.doi.org/10.4265/bio.14.39.

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42

Alpeeva, Inna S., and Ivan Yu. Sakharov. "Luminol–hydrogen peroxide chemiluminescence produced by sweet potato peroxidase." Luminescence 22, no. 2 (2007): 92–96. http://dx.doi.org/10.1002/bio.931.

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43

Satha, Pardhasaradhi, Giriteja Illa, Arindam Ghosh, and Chandra Shekhar Purohit. "Bio-inspired self-assembled molecular capsules." RSC Advances 5, no. 91 (2015): 74457–62. http://dx.doi.org/10.1039/c5ra16421d.

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Bowl shaped molecules are useful for making molecular capsules with suitable non-covalent bonds. We appended cyclotriguaiacylene with biologically important adenine and thymine to make capsule in solution by hydrogen bonding.
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44

Zhang, Shuo. "Diverse sustainable methods for future jet engine." Applied and Computational Engineering 11, no. 1 (September 25, 2023): 143–48. http://dx.doi.org/10.54254/2755-2721/11/20230223.

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With global concerns over CO2 emissions and climate change, the aviation industry is investing in renewable fuels and sustainable engines. Bio-Synthetic Paraffinic Kerosene (Bio-SPK) and hydrogen are two significant biofuels that can replace fossil fuels in jet engines. Biofuel is considered a sustainable fuel; it is possible to replace fossil fuel in jet engines. Bio-SPK is an aviation fuel made from plant-derived lipids and processed to have similar properties to traditional jet fuel. It offers significant emissions savings compared to Jet-A1 but is not widely available due to high production costs and limited feedstock availability. While it can improve fuel efficiency and reduce emissions, it has lower energy density than conventional aviation fuels, potentially reducing aircraft range or payload capacity. Hydrogen produces only water but requires careful extraction or manufacturing. Green hydrogen is carbon-neutral, grey hydrogen generates carbon, and blue hydrogen captures and stores carbon. However, most hydrogen is currently generated as grey hydrogen, which offers less environmental benefit than directly burning fossil fuels. This work provides an overview of current and future sustainable jet engine technologies.
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45

Simasatitkul, Lida, Apiwat Lakkhanasombut, Worawit Morin, Supachai Jedsadajerm, Suksun Amornraksa, and Karittha Im-orb. "Performance Analysis of Integral Process of Bio-Oil Production, Bio-Oil Upgrading, and Hydrogen Production from Sewage Sludge." E3S Web of Conferences 428 (2023): 01004. http://dx.doi.org/10.1051/e3sconf/202342801004.

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This research investigated the production of bio-oil through the hydrothermal liquefaction (HTL) process using sewage sludge from wastewater, along with the hydrotreating of the bio-oil. The simulation process began with a wastewater flow rate of 460 tonnes/day, where the feedstock was divided into two streams. The first stream underwent the HTL process, while the other was directed towards hydrogen production. The resulting products included gaseous products, crude bio-oil, and heavy liquid. The crude bio-oil was further upgraded by introducing hydrogen, which was obtained through gasification and purified by gas separation using a palladium membrane. The primary product mainly comprised alkane, with a carbon content of 85.89% and hydrogen content of 14.11%. For the purification of gasoline, kerosene, diesel, and fuel oil, a fractionation distillation tower arrangement was designed. In addition, Additionally, the gaseous products underwent fractionation distillation to obtain 98% nitrogen and 99.9% liquid carbon dioxide. Considering the carbon footprint, it was observed that the bio-oil production process resulted in the highest greenhouse gas (GHG) emissions.
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46

Liu, Kun, An Ying Jiao, Li Ran Yue, and Yong Feng Li. "Study on Bio-Hydrogen Production of Different Fermentation Types." Advanced Materials Research 152-153 (October 2010): 377–82. http://dx.doi.org/10.4028/www.scientific.net/amr.152-153.377.

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By the researches and analyses of the fermentation type in the bio-hydrogen production system, ethanol-type fermentation bacteria had the largest H2-production capability, butyric acid type fermentation bacteria took the second place, and propionic acid-type fermentation bacteria had the least H2-poduction capability. When the organic loading rate (OLR) is 24kgCOD/m3•d, HRT is 8h and temperature is 35 °C, the highest hydrogen production capability corresponding were 4.2, 1.3 and 0.018 mol•kg MLVSS−1•d−1, so ethanol-type fermentation was optimal type for hydrogen production.
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47

Wan, Chin-Feng, Shih-Tse Yang, Hsiang-Yi Lin, Ya-Ju Chang, and An-Tai Wu. "A turn-on indole-based sensor for hydrogen sulfate ion." Luminescence 29, no. 5 (September 16, 2013): 500–503. http://dx.doi.org/10.1002/bio.2575.

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48

Huang, Kai, Yonghua Sun, Lin Liu, and Chaoyu Hu. "Chemiluminescence of 3‐aminophthalic acid anion–hydrogen peroxide–cobalt (II)." Luminescence 35, no. 3 (May 2020): 400–405. http://dx.doi.org/10.1002/bio.3740.

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49

Stepacheva, A., P. Guseva, and A. Dozhdelev. "Supercritical Solvent Composition Influence on Bio-oil Model Compound Deoxygenation." Bulletin of Science and Practice 5, no. 11 (November 15, 2019): 18–25. http://dx.doi.org/10.33619/2414-2948/48/02.

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Hydrofining of oxygen-containing compounds of bio-oil allows efficient use of the final product as a liquid fuel from biomass. Deoxygenation is considered to be one of the most perspective ways to modernize bio-oil. Generally, deoxygenation is carried out under fairly strict conditions in the presence of hydrogen in a medium of high-boiling hydrocarbons. This paper describes a new approach to deoxygenation of model compounds of bio-oil using supercritical liquids as a solvent and hydrogen donor. The possibility of using a complex solvent consisting of non-polar n-hexane with a low critical point (Tc = 234.5 °C, Pc = 3.02 MPa) and propanol-2 used as a hydrogen donor is evaluated. Experiments have shown that in the presence of 20 vol. % propanol-2 in n-hexane a maximum (99%) conversion of model bio-oil compounds with the formation of phenols with a yield of up to 95% is observed.
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Zhang, Zhiping, Yameng Li, Chenyang Wang, Bing Hu, Jianjun Hu, Chao He, Yanyan Jin, Shengnan Zhu, and Quanguo Zhang. "Capacity Analysis of Photo-Fermentation Bio-Hydrogen Production from Different Food Wastes." Journal of Biobased Materials and Bioenergy 14, no. 2 (April 1, 2020): 303–7. http://dx.doi.org/10.1166/jbmb.2020.1956.

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Food waste is rich in starch or cellulose, which can be utilized as carbon source for fermentation. Hence, in this paper, different food wastes (vegetable, rice, corn, potato) were taken as substrate to evaluate their hydrogen yield potential. The characteristics of fermentation broth, cumulative hydrogen yield, and hydrogen production rate were investigated in the photo-fermentation bio-hydrogen production process. Modified Gompertz Model was utilized to deal with experiment data. Results showed that food waste can be effectively utilized by photosynthetic bacteria. Waste rice was determined to have the best hydrogen production capacity with hydrogen yield of 696 mL, and the maximum hydrogen production rate of 17.71 mL/h, the average hydrogen concentration was 55.78%.
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