Perspectives of Hydrogen Production from Corn Wastes in Poland by Means of Dark Fermentation

Gaweł Sołowski; Izabela Konkol; Adam Cenian

doi:10.1515/eces-2019-0031

Perspectives of Hydrogen Production from Corn Wastes in Poland by Means of Dark Fermentation

Ecological Chemistry and Engineering S ◽

10.1515/eces-2019-0031 ◽

2019 ◽

Vol 26 (2) ◽

pp. 255-263

Author(s):

Gaweł Sołowski ◽

Izabela Konkol ◽

Adam Cenian

Keyword(s):

Hydrogen Production ◽

Dark Fermentation ◽

Production Of Hydrogen

Abstract A model for calculating the maximal theoretical production of hydrogen from corn wastes is proposed. The model has been used to estimate the potential for hydrogen production from cereals wastes such as wheat, barley, and corn which are cultivated in Poland. The potentials for Pomorze and other regions of Poland are compared. The hydrogen produced from cereal wastes in Poland could potentially meet 47 % of national hydrogen demand.

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Bio-electrochemical production of hydrogen and electricity from organic waste

10.21203/rs.3.rs-1032725/v1 ◽

2021 ◽

Author(s):

Giorgia De Gioannis ◽

Alessandro Dell'Era ◽

Aldo Muntoni ◽

Mauro Pasquali ◽

Alessandra Polettini ◽

...

Keyword(s):

Hydrogen Production ◽

Electron Flow ◽

Dark Fermentation ◽

Electrochemical Process ◽

Integrated System ◽

Galvanic Cell ◽

Hydrogen Yield ◽

Cell Coupling ◽

Production Of Hydrogen ◽

Acid Metabolites

Abstract This study investigated the performance of a novel integrated bio-electrochemical system for synergistic hydrogen production from a process combining a dark fermentation reactor and a galvanic cell. The operating principle of the system is based on the electrochemical conversion of protons released upon dissociation of the acid metabolites of the biological process and is mediated by the electron flow from the galvanic cell, coupling biochemical and electrochemical hydrogen production. Accordingly, the galvanic compartment also generates electricity. Four different experimental setups were designed to provide a preliminary assessment of the integrated bio-electrochemical process and identify the optimal configuration for further tests. Subsequently, dark fermentation of cheese whey was implemented both in a stand-alone biochemical reactor and in the integrated bio-electrochemical process. The integrated system achieved a hydrogen yield in the range 75.5 – 78.8 N LH2/kg TOC, showing a 3 times improvement over the biochemical process.

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Characterization of a Polymeric Membrane for the Separation of Hydrogen in a Mixture with CO2

The Open Fuels & Energy Science Journal ◽

10.2174/1876973x01609010126 ◽

2016 ◽

Vol 9 (1) ◽

pp. 126-136 ◽

Cited By ~ 1

Author(s):

Dionisio H. Malagón-Romero ◽

Alexander Ladino ◽

Nataly Ortiz ◽

Liliana P. Green

Keyword(s):

Carbon Dioxide ◽

Hydrogen Production ◽

Test Performance ◽

Low Cost ◽

Time Lag ◽

Polymeric Membrane ◽

Biological Processes ◽

Scanning Calorimetry ◽

Environmentally Sustainable ◽

Production Of Hydrogen

Hydrogen is expected to play an important role as a clean, reliable and renewable energy source. A key challenge is the production of hydrogen in an economically and environmentally sustainable way on an industrial scale. One promising method of hydrogen production is via biological processes using agricultural resources, where the hydrogen is found to be mixed with other gases, such as carbon dioxide. Thus, to separate hydrogen from the mixture, it is challenging to implement and evaluate a simple, low cost, reliable and efficient separation process. So, the aim of this work was to develop a polymeric membrane for hydrogen separation. The developed membranes were made of polysulfone via phase inversion by a controlled evaporation method with 5 wt % and 10 wt % of polysulfone resulting in thicknesses of 132 and 239 micrometers, respectively. Membrane characterization was performed using scanning electron microscopy (SEM), differential scanning calorimetry (DSC), atomic force microscopy (AFM), and ASTM D882 tensile test. Performance was characterized using a 23 factorial experiment using the time lag method, comparing the results with those from gas chromatography (GC). As a result, developed membranes exhibited dense microstructures, low values of RMS roughness, and glass transition temperatures of approximately 191.75 °C and 190.43 °C for the 5 wt % and 10 wt % membranes, respectively. Performance results for the given membranes showed a hydrogen selectivity of 8.20 for an evaluated gas mixture 54% hydrogen and 46% carbon dioxide. According to selectivity achieved, H2 separation from carbon dioxide is feasible with possibilities of scalability. These results are important for consolidating hydrogen production from biological processes.

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Hydrogen production from water electrolysis: role of catalysts

Nano Convergence ◽

10.1186/s40580-021-00254-x ◽

2021 ◽

Vol 8 (1) ◽

Author(s):

Shan Wang ◽

Aolin Lu ◽

Chuan-Jian Zhong

Keyword(s):

Hydrogen Production ◽

Water Splitting ◽

Noble Metal ◽

Active Sites ◽

Current Knowledge ◽

Low Cost ◽

Critical Role ◽

Water Electrolysis ◽

Efficient Production ◽

Production Of Hydrogen

AbstractAs a promising substitute for fossil fuels, hydrogen has emerged as a clean and renewable energy. A key challenge is the efficient production of hydrogen to meet the commercial-scale demand of hydrogen. Water splitting electrolysis is a promising pathway to achieve the efficient hydrogen production in terms of energy conversion and storage in which catalysis or electrocatalysis plays a critical role. The development of active, stable, and low-cost catalysts or electrocatalysts is an essential prerequisite for achieving the desired electrocatalytic hydrogen production from water splitting for practical use, which constitutes the central focus of this review. It will start with an introduction of the water splitting performance evaluation of various electrocatalysts in terms of activity, stability, and efficiency. This will be followed by outlining current knowledge on the two half-cell reactions, hydrogen evolution reaction (HER) and oxygen evolution reaction (OER), in terms of reaction mechanisms in alkaline and acidic media. Recent advances in the design and preparation of nanostructured noble-metal and non-noble metal-based electrocatalysts will be discussed. New strategies and insights in exploring the synergistic structure, morphology, composition, and active sites of the nanostructured electrocatalysts for increasing the electrocatalytic activity and stability in HER and OER will be highlighted. Finally, future challenges and perspectives in the design of active and robust electrocatalysts for HER and OER towards efficient production of hydrogen from water splitting electrolysis will also be outlined.

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A Process for Hydrogen Production from the Catalytic Decomposition of Formic Acid over Iridium—Palladium Nanoparticles

Materials ◽

10.3390/ma14123258 ◽

2021 ◽

Vol 14 (12) ◽

pp. 3258

Author(s):

Hamed M. Alshammari ◽

Mohammad Hayal Alotaibi ◽

Obaid F. Aldosari ◽

Abdulellah S. Alsolami ◽

Nuha A. Alotaibi ◽

...

Keyword(s):

Hydrogen Production ◽

Formic Acid ◽

Activated Charcoal ◽

Palladium Nanoparticles ◽

Room Temperature ◽

Catalytic Decomposition ◽

Conversion Yield ◽

Production Of Hydrogen ◽

Commercial Applications

The present study investigates a process for the selective production of hydrogen from the catalytic decomposition of formic acid in the presence of iridium and iridium–palladium nanoparticles under various conditions. It was found that a loading of 1 wt.% of 2% palladium in the presence of 1% iridium over activated charcoal led to a 43% conversion of formic acid to hydrogen at room temperature after 4 h. Increasing the temperature to 60 °C led to further decomposition and an improvement in conversion yield to 63%. Dilution of formic acid from 0.5 to 0.2 M improved the decomposition, reaching conversion to 81%. The reported process could potentially be used in commercial applications.

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Zeolite addition to improve biohydrogen production from dark fermentation of C5/C6-sugars and Sargassum sp. biomass

Scientific Reports ◽

10.1038/s41598-021-95615-1 ◽

2021 ◽

Vol 11 (1) ◽

Author(s):

R. M. Silva ◽

A. A. Abreu ◽

A. F. Salvador ◽

M. M. Alves ◽

I. C. Neves ◽

...

Keyword(s):

Hydrogen Production ◽

Anaerobic Bacteria ◽

Dark Fermentation ◽

Inorganic Materials ◽

Biohydrogen Production ◽

High Rate ◽

Continuous Reactor ◽

Organic Loading Rate ◽

Fermentation Products ◽

Zeolite Type

AbstractThermophilic biohydrogen production by dark fermentation from a mixture (1:1) of C5 (arabinose) and C6 (glucose) sugars, present in lignocellulosic hydrolysates, and from Sargassum sp. biomass, is studied in this work in batch assays and also in a continuous reactor experiment. Pursuing the interest of studying interactions between inorganic materials (adsorbents, conductive and others) and anaerobic bacteria, the biological processes were amended with variable amounts of a zeolite type-13X in the range of zeolite/inoculum (in VS) ratios (Z/I) of 0.065–0.26 g g−1. In the batch assays, the presence of the zeolite was beneficial to increase the hydrogen titer by 15–21% with C5 and C6-sugars as compared to the control, and an increase of 27% was observed in the batch fermentation of Sargassum sp. Hydrogen yields also increased by 10–26% with sugars in the presence of the zeolite. The rate of hydrogen production increased linearly with the Z/I ratios in the experiments with C5 and C6-sugars. In the batch assay with Sargassum sp., there was an optimum value of Z/I of 0.13 g g−1 where the H2 production rate observed was the highest, although all values were in a narrow range between 3.21 and 4.19 mmol L−1 day−1. The positive effect of the zeolite was also observed in a continuous high-rate reactor fed with C5 and C6-sugars. The increase of the organic loading rate (OLR) from 8.8 to 17.6 kg m−3 day−1 of COD led to lower hydrogen production rates but, upon zeolite addition (0.26 g g−1 VS inoculum), the hydrogen production increased significantly from 143 to 413 mL L−1 day−1. Interestingly, the presence of zeolite in the continuous operation had a remarkable impact in the microbial community and in the profile of fermentation products. The effect of zeolite could be related to several properties, including the porous structure and the associated surface area available for bacterial adhesion, potential release of trace elements, ion-exchanger capacity or ability to adsorb different compounds (i.e. protons). The observations opens novel perspectives and will stimulate further research not only in biohydrogen production, but broadly in the field of interactions between bacteria and inorganic materials.

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Iridium Complex Catalyzed Hydrogen Production from Glucose and Various Monosaccharides

Catalysts ◽

10.3390/catal11080891 ◽

2021 ◽

Vol 11 (8) ◽

pp. 891

Author(s):

Ken-ichi Fujita ◽

Takayoshi Inoue ◽

Toshiki Tanaka ◽

Jaeyoung Jeong ◽

Shohichi Furukawa ◽

...

Keyword(s):

Hydrogen Production ◽

Catalytic System ◽

Catalytic Reaction ◽

Hydrogen Gas ◽

Water Soluble ◽

Starting Material ◽

Iridium Complex ◽

Production Of Hydrogen ◽

Bipyridine Ligand

A new catalytic system has been developed for hydrogen production from various monosaccharides, mainly glucose, as a starting material under reflux conditions in water in the presence of a water-soluble dicationic iridium complex bearing a functional bipyridine ligand. For example, the reaction of D-glucose in water under reflux for 20 h in the presence of [Cp*Ir(6,6′-dihydroxy-2,2′-bipyridine)(H2O)][OTf]2 (1.0 mol %) (Cp*: pentamethylcyclopentadienyl, OTf: trifluoromethanesulfonate) resulted in the production of hydrogen gas in 95% yield. In the present catalytic reaction, it was experimentally suggested that dehydrogenation of the alcoholic moiety at 1-position of glucose proceeded.

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Enhanced hydrogen production of Rhodobacter sphaeroides promoted by extracellular H+ of Halobacterium salinarum

Annals of Microbiology ◽

10.1186/s13213-021-01621-z ◽

2021 ◽

Vol 71 (1) ◽

Author(s):

Jiang-Yu Ye ◽

Yue Pan ◽

Yong Wang ◽

Yi-Chao Wang

Keyword(s):

Hydrogen Production ◽

Production Rate ◽

Rhodobacter Sphaeroides ◽

Coupled System ◽

Purple Membrane ◽

Halobacterium Salinarum ◽

Control Group ◽

Hydrogen Production Rate ◽

Production Of Hydrogen ◽

The Impact

Abstract Purpose This study utilized the principle that the bacteriorhodopsin (BR) produced by Halobacterium salinarum could increase the hydrogen production of Rhodobacter sphaeroides. H. salinarum are co-cultured with R. sphaeroides to determine the impact of purple membrane fragments (PM) on R. sphaeroides and improve its hydrogen production capacity. Methods In this study, low-salinity in 14 % NaCl domesticates H salinarum. Then, 0–160 nmol of different concentration gradient groups of bacteriorhodopsin (BR) and R. sphaeroides was co-cultivated, and the hydrogen production and pH are measured; then, R. sphaeroides and immobilized BR of different concentrations are used to produce hydrogen to detect the amount of hydrogen. Two-chamber microbial hydrogen production system with proton exchange membrane-assisted proton flow was established, and the system was operated. As additional electricity added under 0.3 V, the hydrogen production rate increased with voltages in the coupled system. Results H salinarum can still grow well after low salt in 14% NaCl domestication. When the BR concentration is 80 nmol, the highest hydrogen production reached 217 mL per hour. Both immobilized PC (packed cells) and immobilized PM (purple membrane) of H. salinarum could promote hydrogen production of R. sphaeroides to some extent. The highest production of hydrogen was obtained by the coupled system with 40 nmol BR of immobilized PC, which increased from 127 to 232 mL, and the maximum H2 production rate was 18.2 mL−1 h−1 L culture. In the 192 h experiment time, when the potential is 0.3 V, the hydrogen production amount can reach 920 mL, which is 50.3% higher than the control group. Conclusions The stability of the system greatly improved after PC was immobilized, and the time for hydrogen production of R. sphaeroides significantly extended on same condition. As additional electricity added under 0.3 V, the hydrogen production rate increased with voltages in the coupled system. These results are helpful to build a hydrogen production-coupled system by nitrogenase of R. sphaeroides and proton pump of H. salinarum. Graphical abstract

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