Showing total 13,552 results

1. Promoted Catalytic Activity of CoSx@MoSx/MoOx Supported on Carbon Papers for Electrocatalytic Hydrogen Evolution Reaction.

Author

Hong, Sung Hyun, Tekalgne, Mahider Asmare, Ryu, Sangwoo, Ahn, Sang Hyun, and Kim, Soo Young

Subjects

*CATALYTIC activity, *CARBON paper, *CHEMICAL vapor deposition, *MOLYBDENUM oxides, *HYDROGEN production, *ELECTROCATALYSIS, *MOLYBDENUM catalysts, *COBALT, *HYDROGEN evolution reactions

Abstract

Developing cost-effective and stable materials for the electrocatalysis of hydrogen evolution reaction (HER) remains challenging. In this study, efficient catalysts for HER were synthesized by integrating the cobalt and molybdenum oxides via electrodeposition, followed by subsequent sulfurization of the as-prepared oxides using chemical vapor deposition (CVD). This methodology allowed the incorporation of both cobalt and molybdenum components into the catalyst in a single step. The as-synthesized CoSx@MoSx/MoOx-based catalysts exhibited excellent hydrogen production performance in acidic media owing to the presence of Co-S and Mo-S bonds in the hybrid structure. Particularly, CoSx@MoSx/MoOx(90@360) and MoSx@CoOx(180@180) displayed the best HER performances with low overpotentials of 80 mV and 150 mV, respectively. The catalysts were highly stable, with their stability preserved for over 1000 cycles with marginal reduction in overall efficiency. Therefore, these findings suggest the potential of CoSx@MoSx/MoOx and MoSx@CoOx composites as ideal candidates for developing low-cost catalysts for electrochemical hydrogen production. [ABSTRACT FROM AUTHOR]

Published

2024

2. Solar photocatalytic hydrogen production from pulp and paper wastewater.

Author

Steephen, Ananth, V, Preethi, B, Annenewmy, R, Parthasarathy, Reddy P, Reshwanth, M, Sairam, and Kumar M, Sathish

Subjects

*PAPER pulp, *HYDROGEN production, *FERRIC oxide, *INTERSTITIAL hydrogen generation, *SEWAGE, *METALLIC oxides, *SULFATE waste liquor

Abstract

The solar photocatalytic degradation of pulp and paper mill wastewater has been reported by several scientists. However, this is the first time we are reporting for solar photocatalytic hydrogen production from pulp and paper mill wastewater and simultaneous degradation of pollutants. In this work, CuO based photocatalysts and novel square type photocatalytic reactor of 5 L capacity were used. The result shows that the prepared photocatalysts are solar active, efficient in hydrogen recovery and pollutant degradation from the pulp and paper wastewater. The effects of catalyst loading, sacrificial agent, pollutant removal efficiency and stability check were investigated. At 0.25 g/L of CuO/Fe 2 O 3 , 0.2 M of sacrificial agent (Na 2 SO 3 2−) and hydrogen yield of 1000 mL from 1000 mL of wastewater was achieved. The removal efficiency of TSS, TDS, BOD, COD, turbidity and TOC are around 70, 50, 60, 65, 70 and 45% respectively. Reusability study revealed that CuO/Fe 2 O 3 was chemically stable and could be reused successively (five cycles) without significant changes in its photoactivity and intrinsic properties. [Display omitted] • Visible light active CuO mixed with novel metal oxides were employed. • Hydrogen recovery from black liquor, paper mill wastewater were 1000 mL/h/L and 850 mL/h/L. • Efficiency of degradation of pulp & paper wastewater chemicals were around 50–70%. • AcHieved high recovery of hydrogen from pulp & paper wastewater. [ABSTRACT FROM AUTHOR]

Published

2024

3. Carbon paper supported gold nanoflowers for tunable glycerol electrooxidation boosting efficient hydrogen evolution.

Author

Xie, Yanan, Sun, Lingzhi, Pan, Xun, Zhou, Zhaoyu, Zheng, Yunchun, Yang, Xiaofeng, and Zhao, Guohua

Subjects

*CARBON paper, *SPECIAL drawing rights, *HYDROGEN evolution reactions, *FORMIC acid, *GLYCOLIC acid, *CARBON electrodes, *GLYCERIN

Abstract

Thermodynamically favorable selective electrooxidation reactions coupled with hydrogen evolution reaction (HER) is a promising strategy for simultaneous production of value-added chemicals and hydrogen. In this work, a binder-free gold nanoflowers electrode based on carbon paper is prepared and used as anode catalyst, which results in good charge transfer, high stability and superior catalytic activity for electrooxidation of glycerol. We develop an integrated system of glycerol electrooxidation with HER, and the effect of potential on the distribution of anodic electrooxidation products and cathodic hydrogen production are investigated. At 1.0 V, the overall reaction reaches 10 mA cm−2 and the selectivity of glyceric acid (GLA) reaches 97.2%. At 1.2 V, hydrogen production reaches the highest value of 960 μmol L−1 and the anode product consists of a mixture of glyceric acid, glycolic acid (GA) and formic acid (FA). At 1.3 V, the selectivity of FA reaches 87.3%. Operando technique in situ infrared spectroscopy is used to monitor the immediate evolution and study the pathway of controlled glycerol electrooxidation. This work demonstrates carbon paper is a promising substrate material of binder-free electrode applied in thermodynamically favorable electrocatalytic reactions boosting hydrogen evolution. [Display omitted] • A binder-free electrode based on carbon paper is developed. • Hydrogen production is increased by 24 times with the addition of glycerol. • The selectivity of glyceric acid on carbon paper supported gold nanoflowers is 97.2%. • In situ FTIR reveals the pathway for electrooxidation of glycerol. [ABSTRACT FROM AUTHOR]

Published

2023

4. Surfactant-assisted green liquor dregs pretreatment to enhance the digestibility of paper mill sludge.

Author

Rorke, Daneal C.S., Lekha, Prabashni, Kana, Gueguim E.B., and Sithole, B.Bruce

Subjects

*PAPER mills, *RESPONSE surfaces (Statistics), *HYDROGEN production, *SULFATE pulping process, *HEAVY metals, *ARSENIC, *COBALT, *LIQUORS

Abstract

This study optimizes a novel surfactant-assisted green liquor dregs (GLD) pretreatment of paper mill sludge (PMS), both of which are wastes from the kraft pulping industry, using a combined Response Surface Methodology (RSM) design. Optimized conditions give a maximal reducing sugar release of 16.38 g/L. A substantial reduction in heavy metals aluminum, chromium, cobalt, arsenic, lead, and copper after pretreatment illustrates the enhancement of substrate digestibility by reducing toxic elements. Separate hydrolysis and fermentation (SHF) and simultaneous saccharification and fermentation (SSF) for hydrogen production are assessed. SSF produced a hydrogen yield of 3.72 mL/g, displaying a 36.26% increase from pretreated PMS compared to SHF. These findings provide insights into possible methods of reducing process duration, energy input, and costs incurred with waste disposal within the paper industry. Furthermore, improved hydrogen yield using an SSF process demonstrates the potential beneficiation of pulp and paper GLD and PMS wastes. • A novel surfactant-assisted GLD pretreatment of PMS developed. • An optimal reducing sugar release of 16.38 g/L was obtained. • Novel pretreatment protocol achieved significant heavy metal reduction. • SSF hydrogen production from pretreated PMS increased hydrogen yield by 36.26%. [ABSTRACT FROM AUTHOR]

Published

2021

5. Characterization of paper mill sludge as a renewable feedstock for sustainable hydrogen and biofuels production.

Author

Tawalbeh, Muhammad, Rajangam, Alex S., Salameh, Tareq, Al-Othman, Amani, and Alkasrawi, Malek

Subjects

*PAPER mills, *LIGNOCELLULOSE, *HYDROGEN production, *PULP mills, *FEEDSTOCK, *CELLULOSE fibers, *SWITCHGRASS, *HYDROGEN as fuel

Abstract

Paper and pulp mills generate substantial quantities of cellulose-rich sludge materials that are disposed in landfills at a large scale. For sustainability purposes, sludge materials can be bioprocessed to produce renewable fuels and useful chemicals. The enzymatic hydrolysis of cellulose is the process bottleneck that affects the conversion economics directly by using zero-cost raw materials. In order to study and optimize the process, the characteristics of the sludge raw materials should be first evaluated. In this work, sludge samples were obtained from paper mills located at different locations in Wisconsin and Minnesota. Part of the sludge samples was washed (de-ashed) with hydrochloric acid while the other part remained unwashed. The samples were subjected to multiple spectroscopic analyses techniques to evaluate the morphological properties of cellulose fibers and to estimate the total structural carbohydrate content. The results showed that the de-ashing process changed some fiber characteristics and cellulose crystallinity structure in all sludge samples. Sludge sample A (obtained from Kraft pulp and recycled paper mill region) showed a high percentage of fiber, with crystalline cellulose, compared to the other two sludge samples suggesting that sludge A is a valuable source to make value-added products. Aspen Plus mass and energy calculations performed in view of the 'zero' cost and the reliable supply of sludge raw materials producing 2 mol H 2 /mol glucose. Moreover, the results showed that extracting crystalline cellulose from these sludge samples is more profitable than crystalline cellulose made from the other lignocellulosic feedstocks. The results reported here showed that the utilization of these sludge materials would be an economically attractive and promising alternative for the production of hydrogen. Image 1 • A new method for paper mill sludge (PMS) characterization as renewable feedstock. • The deashing step has a major effect on the bioconversion of the PMS. • Studying the crystalline cellulose of the PMS. • A relation between the characterization and potential sugar yield was established. [ABSTRACT FROM AUTHOR]

Published

2021

6. Towards the development of biofuel production from paper mill effluent.

Author

Vaez, Elhamossadat and Zilouei, Hamid

Subjects

*PAPER mills, *HYDROGEN production, *PH effect, *FERMENTATION, *METHANE as fuel

Abstract

Biohydrogen and biomethane production via two stage sequencing system from paper mill effluent (PME) was evaluated to enhance its COD reduction. Heat-shock pretreatment of anaerobic sludge at 90 °C for 15 min was chosen to obtain a mixed microbial inoculum for dark fermentative hydrogen production. The effect of initial pH (5, 6 and 7) on the efficiency of hydrogen fermentation at different concentrations of substrate (3, 5 and 7 g-COD/L) was investigated, which the maximum hydrogen yield was obtained at initial pH 5. After that, the effects of substrate concentration (3, 5, 7, 10 and 15 g-COD/L) and fermentation temperature (37 and 55 °C) were investigated on the hydrogen production yield. The efficiency of dark hydrogen fermentation for all substrate concentrations was higher at 55 °C. The hydrogen production was enhanced as substrate concentration increased up to 5 g-COD/L, but then it was reduced, and the optimum hydrogen yield of 38.8 mL H 2 /g-COD initial was obtained at substrate concentration of 5 g-COD/L at 55 °C. The highest hydrogen (35.1 mL H 2 /g-COD initial) was obtained at 5 g-COD/L and 55 °C and the highest methane (553.8 mL CH 4 /g-COD initial) was obtained at 3 g-COD/L and 37 °C. Maximum COD reduction of 88.1% was obtained in two-stage sequencing dark fermentation/anaerobic digestion system at 3 g-COD/L and 37 °C. • BioH 2 and bioCH 4 were generated in expend of COD reduction from PME. • Effects of initial pH, COD loading and temperature were studied. • Primary step dark fermentation showed higher hydrogen yields at 55 °C. • Max COD reduction 88.1% was obtained in 2-stage sequencing system (3 g-COD/L, 37 °C). • 38.8 mL H 2 /g-COD initial at 55 °C and 553.8 mL CH 4 /g-COD initial at 37 °C were obtained. [ABSTRACT FROM AUTHOR]

Published

2020

7. Biomass and biohydrogen production during dark fermentation of Escherichia coli using office paper waste and cardboard.

Author

Poladyan, Anna, Margaryan, Lena, Trchounian, Karen, and Trchounian, Armen

Subjects

*WASTE paper, *BIOMASS production, *ESCHERICHIA coli, *WASTE products, *SOLID waste

Abstract

Growth properties, oxidation-reduction potential kinetics and hydrogen production of Escherichia coli BW25113 parental strain (PS) and hydrogenase (Hyd)-negative mutants were investigated after fermentative growth using office paper waste and cardboard (PW) hydrolysate (PWH). PWH was obtained by using dilute acid method in a steam sterilizer for 1 h, 121 °C. Optimal conditions for bacterial growth and H 2 production were identified (PWH concentrations, pH 7.5). Recording of redox potential using a platinum electrode revealed a drop to −500 ± 10 mV, with a H 2 yield of ~1.45 mmol H 2 L−1 after 4 h of growth using PWH resulted in the formation of 0.20 ± 0.02 g bacterial cell dry weight L−1. Bacterial biomass formation was stimulated ~3-fold upon addition of 0.5% yeast extract, and H 2 production started early - at the beginning of the exponential phase. Moreover, mutants lacking Hyd-1 and Hyd-2 significantly enhanced H 2 production. The findings would be beneficial for the development of H 2 production biotechnology using cheap solid waste materials. • Office waste paper and cardboard hydrolisate (PWH) was upcycled for biomass and biohydrogen. • Dilute acid method in a steam sterilizer, pH adjustment to 7.5 were used for pretreatment. • E. coli wild type yielded H 2 of ~240 mL H 2 (g sugar)−1 at the 4th h of growth. • H 2 production was observed earlier upon 0.5% yeast extract added. • Mutations of hydrogenases Hyd-1 and Hyd-2 enhanced H 2 production. [ABSTRACT FROM AUTHOR]

Published

2020

8. Simple and Sensitive Detection of Bacterial Hydrogen Sulfide Production Using a Paper-Based Colorimetric Assay.

Author

Ahn, Byung-Ki, Ahn, Yong-Jin, Lee, Young-Ju, Lee, Yeon-Hee, and Lee, Gi-Ja

Subjects

HYDROGEN production, HYDROGEN sulfide, LACTOBACILLUS casei, STREPTOCOCCUS mutans, PERIODONTAL disease, ORAL diseases

Abstract

Hydrogen sulfide (H2S) is known to participate in bacteria-induced inflammatory response in periodontal diseases. Therefore, it is necessary to quantify H2S produced by oral bacteria for diagnosis and treatment of oral diseases including halitosis and periodontal disease. In this study, we introduce a paper-based colorimetric assay for detecting bacterial H2S utilizing silver/Nafion/polyvinylpyrrolidone membrane and a 96-well microplate. This H2S-sensing paper showed a good sensitivity (8.27 blue channel intensity/μM H2S, R2 = 0.9996), which was higher than that of lead acetate paper (6.05 blue channel intensity/μM H2S, R2 = 0.9959). We analyzed the difference in H2S concentration released from four kinds of oral bacteria (Eikenella corrodens, Streptococcus sobrinus, Streptococcus mutans, and Lactobacillus casei). Finally, the H2S level in Eikenella corrodens while varying the concentration of cysteine and treatment time was quantified. This paper-based colorimetric assay can be utilized as a simple and effective tool for in vitro screening of H2S-producing ability of many bacteria as well as salivary H2S analysis. [ABSTRACT FROM AUTHOR]

Published

2022

9. The Electrochemical Hydrogen Evolution Reaction Based on Helical Chain Stacked 2D Tellurium Nanoflakes.

Author

Yu, Jing, Wang, Yingying, Liu, Wenjun, Fan, Xiaofeng, Duang, Yuhao, Zhang, Fan, and Jiang, Yanxiao

Subjects

GIBBS' free energy, HYDROGEN production, DENSITY functional theory, CARBON paper, HYDROGEN atom

Abstract

A crucial factor in advancing the broad utilization of electrocatalytic hydrogen evolution reaction (HER) is the development of efficient catalysts with sufficient active sites. Herein, a hydrothermal approach is utilized to fabricate helical chain stacked two‐dimensional (2D) tellurium (Te) nanoflakes, whose HER performance hasn't been systematically studied yet. It is found that Te nanoflakes transferred on carbon fiber paper (CFP) exhibit impressive HER properties and show a load dependence. The overpotential required for HER is significantly reduced to 279 mV under a load condition of 0.86 mg cm−2 at a current density of 10 mA cm−2. Density functional theory (DFT) calculations are further systematically carried out on Te catalytic sites along the helical chain at [0001] direction with a threefold screw symmetry. It is found that the Gibbs free energy of adsorbed hydrogen atom (ΔGH*) on Te sites is significantly lower than that of molybdenum disulfide (MoS2). Besides, the active sites based on surface atom density calculation reveal that Te provides more adsorption sites than layered MoS2. The decreased adsorption energy and efficient adsorption sites in Te may highlight the promising application of elemental crystal Te in electrocatalytic hydrogen production and pave the way for developing new types of electrocatalysts. [ABSTRACT FROM AUTHOR]

Published

2024

10. Mo2C based electrocatalyst with filter paper derived N-doped mesoporous carbon as matrix for H2 production.

Author

Chen, Jin, Yang, Hongxing, Xu, Xinxin, Su, Zhijian, Guo, Yaping, and Wang, Qiang

Subjects

*ELECTROCATALYSTS, *FILTER paper, *MESOPOROUS materials, *HYDROGEN production, *ELECTROCATALYSIS

Abstract

In an attempt to explore high efficient and cheap electrocatalyst for water splitting hydrogen production, small molybdenum carbide nanoparticles with the size about 3–6 nm are loaded on three-dimensional N-doped carbon matrix successfully with ammonium heptamolybdate ((NH 4 ) 6 Mo 7 O 24 ·4H 2 O) and filter paper as precursor by pyrolysis. Due to its small size, large surface area and high conductivity, this electrocatalyst shows excellent activity in hydrogen evolution reaction (HER). In acid media, its overpotential to achieve a current density of 10 mA·cm −2 is as low as 167 mV, with Tafel slope is only 73 mV·dec −1 . The electrocatalyst also shows large exchange current density (j 0 ) with the value 0.15 mA·cm −2 . Furthermore, it shows excellent durability after 1000 cycles of long-term test, and the catalytic current remains stable over 10 h at fixed overpotential. This work elucidates a feasible strategy to obtain efficient electrocatalysts with cheap and naturally sustainable material as precursor and shed some light on the exploration and optimization of electrocatalysts in energy chemistry. The HER of this electrocatalyst is studied and the results illustrate it exhibits a stable hydrogen evolution rate of 44.5 μmol·h −1 with faradaic efficiency about 100%. [ABSTRACT FROM AUTHOR]

Published

2018

11. Surfactant-assisted green liquor dregs pretreatment to enhance the digestibility of paper mill sludge

Author

Prabashni Lekha, Daneal C.S. Rorke, Gueguim E.B. Kana, and Bruce Sithole

Subjects

Renewable Energy, Sustainability and the Environment, business.industry, Chemistry, Pulp (paper), Energy Engineering and Power Technology, Paper mill, 02 engineering and technology, engineering.material, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Pulp and paper industry, 01 natural sciences, 0104 chemical sciences, Fuel Technology, Kraft process, engineering, Green liquor, Fermentation, Response surface methodology, 0210 nano-technology, business, Hydrogen production, Waste disposal

Abstract

This study optimizes a novel surfactant-assisted green liquor dregs (GLD) pretreatment of paper mill sludge (PMS), both of which are wastes from the kraft pulping industry, using a combined Response Surface Methodology (RSM) design. Optimized conditions give a maximal reducing sugar release of 16.38 g/L. A substantial reduction in heavy metals aluminum, chromium, cobalt, arsenic, lead, and copper after pretreatment illustrates the enhancement of substrate digestibility by reducing toxic elements. Separate hydrolysis and fermentation (SHF) and simultaneous saccharification and fermentation (SSF) for hydrogen production are assessed. SSF produced a hydrogen yield of 3.72 mL/g, displaying a 36.26% increase from pretreated PMS compared to SHF. These findings provide insights into possible methods of reducing process duration, energy input, and costs incurred with waste disposal within the paper industry. Furthermore, improved hydrogen yield using an SSF process demonstrates the potential beneficiation of pulp and paper GLD and PMS wastes.

Published

2021

12. Direct current assisted bio-hydrogen production from acid hydrolyzed waste paper.

Author

Onaran, Gülizar and Argun, Hidayet

Subjects

*WASTE paper, *DIRECT currents, *CHARGE exchange, *HYDROGEN production, *FATTY acids, *ELECTRICITY

Abstract

One of the most important problems in dark fermentative hydrogen production is the need for the regulation of the ambient pH due to the formation of volatile fatty acids. For this purpose, alkaline chemicals are usually used; however, alkaline addition to the media increases salt formation, which negatively affects microbial activity. In this study, pH adjustment was performed by providing direct current as an alternative to alkali addition. Experiments were carried out batchwise and electricity was only applied to neutralize the acidic pH value. The waste paper hydrolysate was used as a substrate and the effects of applied voltage (0.25–3 V), substrate concentration (4.8–41.2 g/L at 1 V) and electrode distance (0.3–1.3 cm at 1 V) on hydrogen production performance was investigated. Voltages less than 1 V required too much time to keep the pH convenient and voltages more than 1.5 V adversely affected hydrogen production performance. Providing direct current to the fermentation media significantly reduced the adaptation phase. Conditions for optimal pH adjustment and hydrogen production were obtained at 1 V, 20 g glucose/L and 0.5 cm electrode distance. • Most convenient H 2 production was obtained at 1 V, 20 g glucose/L and 0.5 cm electrode distance. • H 2 was efficiently produced up to 29.1 g glucose/L with DC assistance. • Proper electrode distance enables sufficient electron transfer for pH regulation. [ABSTRACT FROM AUTHOR]

Published

2019

13. High-performance RuO2/CNT paper electrode as cathode for anion exchange membrane water electrolysis.

Author

Jeong, Jae-Yeop, Lee, Jong Min, Park, Yoo Sei, Jin, Song, Myeong, Shin-Woo, Heo, Sungjun, Lee, Hoseok, Albers, Justin Georg, Choi, Young-Woo, Seo, Min Ho, Choi, Sung Mook, and Lee, Jooyoung

Subjects

*ION-permeable membranes, *CARBON nanotubes, *WATER electrolysis, *HYDROGEN evolution reactions, *CATHODES, *ELECTRODES, *HYDROUS

Abstract

This study reports on the synthesis and characterization of an effective cathode paper electrode comprising comparatively inexpensive hydrous RuO 2 (h-RuO 2) nanoparticles on carbon nanotubes (CNT) for anion exchange membrane (AEM) water electrolysis. The concentration of hydrous RuO 2 nanoparticles on the CNT was varied to assess their impact on the electrocatalyst for the hydrogen evolution reaction (HER). The electrocatalytic performance of h-RuO 2 /CNT comprising 22.0 wt% of Ru was evaluated. Promising results were obtained, with a current density of −10 mA/cm2 at only 36 mV of overpotential and a mass activity of −2.41 A/g Ru at 100 mV. Additionally, we conducted first-principles calculations to compare the HER catalytic activities of crystalline RuO 2 and hydrous RuO 2 with varying vacancies and to determine the H 2 O concentration in the structural lattice using free-energy diagrams. The study findings demonstrate that the h-RuO 2 /CNT paper can be used as an efficient electrocatalyst for AEM water electrolysis. [Display omitted] • A highly efficient HER catalyst decorated hydrous RuO 2 (h-RuO 2) nanoparticles on carbon nanotubes (CNT) was prepared. • The paper electrode composed of h-RuO 2 /CNT network structure improved conductivity and achieved excellent HER properties. • This paper electrodes applied to high-efficiency AEM water electrolysis as cathode. [ABSTRACT FROM AUTHOR]

Published

2024

14. Use of Cellulose for the Production of Photocatalytic Films for Hydrogen Evolution Along the Lines of Paper Production

Author

Matthias Driess, Tabea A. Thiel, Reinhard Schomäcker, Minoo Tasbihi, Michael Schwarze, Carsten Walter, Michael Schroeter, and Prashanth W. Menezes

Subjects

chemistry.chemical_compound, General Energy, Materials science, chemistry, Chemical engineering, Paper production, Photocatalysis, Production (economics), Hydrogen evolution, Cellulose, Hydrogen production

Abstract

Following the example of photovoltaics, one approach to large-scale photocatalytic hydrogen production is the irradiation of a correspondingly large catalyst area. Paper production is a process in which large areas can already be produced based on the main component: cellulose. Herein, the TiO2 photocatalyst modification PC500, which also uses platinum nanoparticles as a cocatalyst, is supported in two different ways using cellulose. On the one hand, the catalyst is fixed to the surface of a commercial filter paper and, on the other hand, a photocatalytic paper is produced. For comparison, the catalyst is immobilized by means of drop coating using Nafion and measured as a suspension. The cellulose-stabilized films are active and hydrogen production is comparable with the activity obtained from the drop-coating method. The experiments show that the aggregation behavior of cellulose can be used to produce photocatalytically active films. The preparation is easy and can be applied to different kinds of (photo)catalysts. Although the films are very active, their stability during reaction due to swelling and hydrogen production must be further improved.

Published

2022

15. Towards the development of biofuel production from paper mill effluent

Author

Hamid Zilouei and Elhamossadat Vaez

Subjects

060102 archaeology, Hydrogen, Renewable Energy, Sustainability and the Environment, 020209 energy, chemistry.chemical_element, 06 humanities and the arts, 02 engineering and technology, Dark fermentation, Pulp and paper industry, Anaerobic digestion, chemistry, Biogas, Fermentative hydrogen production, 0202 electrical engineering, electronic engineering, information engineering, 0601 history and archaeology, Biohydrogen, Fermentation, Hydrogen production

Abstract

Biohydrogen and biomethane production via two stage sequencing system from paper mill effluent (PME) was evaluated to enhance its COD reduction. Heat-shock pretreatment of anaerobic sludge at 90 °C for 15 min was chosen to obtain a mixed microbial inoculum for dark fermentative hydrogen production. The effect of initial pH (5, 6 and 7) on the efficiency of hydrogen fermentation at different concentrations of substrate (3, 5 and 7 g-COD/L) was investigated, which the maximum hydrogen yield was obtained at initial pH 5. After that, the effects of substrate concentration (3, 5, 7, 10 and 15 g-COD/L) and fermentation temperature (37 and 55 °C) were investigated on the hydrogen production yield. The efficiency of dark hydrogen fermentation for all substrate concentrations was higher at 55 °C. The hydrogen production was enhanced as substrate concentration increased up to 5 g-COD/L, but then it was reduced, and the optimum hydrogen yield of 38.8 mL H2/g-CODinitial was obtained at substrate concentration of 5 g-COD/L at 55 °C. The highest hydrogen (35.1 mL H2/g-CODinitial) was obtained at 5 g-COD/L and 55 °C and the highest methane (553.8 mL CH4/g-CODinitial) was obtained at 3 g-COD/L and 37 °C. Maximum COD reduction of 88.1% was obtained in two-stage sequencing dark fermentation/anaerobic digestion system at 3 g-COD/L and 37 °C.

Published

2020

16. Yields from glucose, xylose, and paper sludge hydrolysate during hydrogen production by the extreme thermophile Caldicellulosiruptor saccharolyticus

Author

Kádár, Zsófia, de Vrije, Truus, van Noorden, Giel E., Budde, Miriam A. W., Szengyel, Zsolt, Réczey, Kati, and Claassen, Pieternel A. M.

Published

2004

17. Hydrogen production from paper sludge hydrolysate

Author

Kádár, Zsófia, De Vrije, Truus, Budde, Miriam A. W., Szengyel, Zsolt, Réczey, Kati, and Claassen, Pieternel A. M.

Published

2003

18. Development of Technology Generating Electric Energy Using Aluminum Based Waste (Technology of Hydrogen Generation from Paper-based Waste with Aluminum)

Subjects

Electric energy, Materials science, chemistry, Aluminium, business.industry, chemistry.chemical_element, Paper based, Process engineering, business, Hydrogen production

Published

2020

19. Hydrogen gas production from waste paper by dark fermentation: Effects of initial substrate and biomass concentrations.

Author

Eker, Serkan and Sarp, Meltem

Subjects

*HYDROGEN production, *WASTE paper, *FERMENTATION, *BIOMASS, *GLUCOSE

Abstract

In this study, waste paper was used as the raw material for hydrogen gas production by dark fermentation at different initial substrate and cell concentrations. Glucose obtained from acid hydrolyzed waste paper was used at six different concentrations between 3.84 and 45.5 gL −1 to determine the effects of sugar concentration on bio-hydrogen production. The highest cumulative hydrogen gas was obtained at 18.9 gL −1 initial sugar concentration. Sugar concentrations above 18.9 gL −1 resulted in product inhibition. Similarly, the initial biomass concentration was varied between 0.25 and 2 gL −1 while sugar concentration was kept constant at 18.58 ± 2.45 gL −1 to determine the effects of initial biomass concentration. The highest cumulative hydrogen gas production was obtained with the initial biomass concentration of 0.5 gL −1 . The highest hydrogen yield (140 ml H 2 g −1 total sugar) was observed at 3.84 gL −1 total sugar concentration. Hydrogen yield decreased with increasing initial sugar concentration due to inhibition by volatile fatty acids (VFAs) produced by dark fermentation and furan derivatives produced from acid hydrolysis of waste paper. [ABSTRACT FROM AUTHOR]

Published

2017

20. High-purity hydrogen production from biogas by sorption-enhanced steam reforming over Ni-MgO-CaO bifunctional catalyst with paper fiber as template.

Author

Zhou, Jingxun, Dang, Chengxiong, and Cai, Weiquan

Subjects

*STEAM reforming, *CARBON sequestration, *BIOGAS production, *BIOGAS, *CATALYSTS, *FIBERS

Abstract

• The hygroscopic property of paper fiber is used to prepare a bifunctional catalyst. • The impregnation time for preparing the hollow microtubular Ni-MgO-CaO is 1 min. • 94.1 % of hydrogen is stably produced on 5Ni-10MgO-CaO from biogas for 50 cycles. • Only 37.1 % loss of the sorption-enhanced effect is shown during the entire cycle. Sorption-enhanced steam reforming (SESR) process is a promising technology aiming at the production of high purity hydrogen with CO 2 capture. The key to the success of this process is the availability of high-performance bifunctional catalysts. Herein, we develop a hollow microtubular Ni-MgO-CaO bifunctional catalyst with paper fiber as template. Due to the strong hygroscopic properties of paper fibers, it provides a method for the rapid synthesis of catalysts with design components by adsorbing solution. The characterizations indicate that the impregnation time (1 min vs 24 h) has no effect on the structural properties of Ni-MgO-CaO bifunctional catalysts. MgO as an inert spacer can weaken the sintering of CaO to ensure a stable CO 2 uptake. Moreover, the agglomeration of Ni particles is inhibited by the MgO coating on their surface. 5Ni-10MgO-CaO as the best performing catalyst displays high stability for the SESR of biogas (SESRB) reaction, during which 94.1 % purity of hydrogen with a 95.2 % conversion of CH 4 is stably produced and only 37.1 % decrease of sorption-enhanced effect is observed in 50 SESRB-calcination cycles. [ABSTRACT FROM AUTHOR]

Published

2024

21. Direct current assisted bio-hydrogen production from acid hydrolyzed waste paper

Author

Hidayet Argun and Gülizar Onaran

Subjects

Alkalinity, Energy Engineering and Power Technology, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Hydrolysate, Hydrogen production performance, Hydrolysis, Electro-fermentation, Bio-hydrogen, Electrodes, Hydrogen production, Direct current, Substrates, Ph, Renewable Energy, Sustainability and the Environment, Chemistry, Dark fermentative hydrogen production, Substrate concentrations, Waste paper towel, Production, Substrate (chemistry), Bio-hydrogen production, Waste paper, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Alkali metal, 0104 chemical sciences, Fuel Technology, Chemical engineering, Fermentative hydrogen production, Fermentation, Volatile fatty acids, Microbial activities, 0210 nano-technology, Dark fermentation, Hydrogen

Abstract

One of the most important problems in dark fermentative hydrogen production is the need for the regulation of the ambient pH due to the formation of volatile fatty acids. For this purpose, alkaline chemicals are usually used; however, alkaline addition to the media increases salt formation, which negatively affects microbial activity. In this study, pH adjustment was performed by providing direct current as an alternative to alkali addition. Experiments were carried out batchwise and electricity was only applied to neutralize the acidic pH value. The waste paper hydrolysate was used as a substrate and the effects of applied voltage (0.25-3 V), substrate concentration (4.8-41.2 g/L at 1 V) and electrode distance (0.3-1.3 cm at 1 V) on hydrogen production performance was investigated. Voltages less than 1 V required too much time to keep the pH convenient and voltages more than 1.5 V adversely affected hydrogen production performance. Providing direct current to the fermentation media significantly reduced the adaptation phase. Conditions for optimal pH adjustment and hydrogen production were obtained at 1 V, 20 g glucose/L and 0.5 cm electrode distance. (C) 2018 Hydrogen Energy Publications LLC. Published by Elsevier Ltd. All rights reserved.

Published

2019

22. Biohydrogen production from paper industry wastes by SSF: A study of the influence of temperature/enzyme loading

Author

Leopoldo J. Ríos-González, J.A. Rodríguez-de la Garza, Thelma K. Morales-Martínez, I.M.M. Moreno-Dávila, and Yolanda Garza-García

Subjects

Hydrogen, Renewable Energy, Sustainability and the Environment, Energy Engineering and Power Technology, chemistry.chemical_element, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Pulp and paper industry, 01 natural sciences, Methane, 0104 chemical sciences, chemistry.chemical_compound, Hydrolysis, Fuel Technology, chemistry, Fermentation, Sewage treatment, Biohydrogen, Fiber, 0210 nano-technology, Hydrogen production

Abstract

The present work focused in assessing the hydrogen production from pretreated wastes of the paper industry (PIW) by simultaneous saccharification and fermentation (SSF) using anaerobic biofilms developed in natural fibers (ixtle) at different conditions. Anaerobic sludge from brewery wastewater treatment was used for biofilms and they were developed in plastic spheres covered with fiber cord from ixtle. The solid wastes of paper industry were previously pretreated with H2SO4 at 2.5% (v/v) at 120 °C by 30 min. The solids pretreated were hydrolyzed and fermented in batch reactors. All reactors were kept at an initial pH of 5.0 and three levels of enzyme loadings (10, 40 and 70 FPU/mL) and temperatures (35, 45, 55 °C) were assessed. The maximum hydrogen obtained (60.75 mmol/h*g volatile solids) was at 45 °C and 70 FPU/mL, moreover, no methane was detected in all cases.

Published

2019

23. Effects of nickle, nickle-cobalt and nickle-cobalt-phosphorus nanocatalysts for enhancing biohydrogen production in microbial electrolysis cells using paper industry wastewater

Author

Amit Kumar Chaurasia, Ravi Shankar, and Prasenjit Mondal

Subjects

Energy recovery, Electrolysis, Environmental Engineering, Materials science, Bioelectric Energy Sources, Phosphorus, General Medicine, Cobalt, Management, Monitoring, Policy and Law, Wastewater, Pulp and paper industry, law.invention, Industrial wastewater treatment, Activated sludge, law, Nickel, Biohydrogen, Waste Management and Disposal, Hydrogen production, Waste disposal, Hydrogen

Abstract

Paper industries are water-intensive industries that produce large amount of wastewater containing dyes, toxicity and high nutrient content. These industries require sustainable technology for their waste disposal and MEC could be one of them. However, effective MEC operation at neutral pH and ambient temperature requires economical and efficient cathodes that are capable to treat indusial wastewater along with recovery of energy/biohydrogen. Co-deposits of Nickel, Nickel–Cobalt and Nickel–Cobalt–Phosphorous on the surface of SS and Cu base metals distinctly were used as cathodes in MEC for the concurrent treatment of real paper industry wastewater and biohydrogen production. MECs were utilized in batch mode at neutral pH, applied voltage of 0.6 V and 30 ± 2 °C temperature with paper industry wastewater and activated sludge as microbial sources. The fabricated Nickel–Cobalt–Phosphorous gives the higher hydrogen production rate of 0.16 ± 0.002 m3(H2) m−3d−1 and 0.14 ± 0.002 m3(H2) m −3d −1 respectively, with ~33–42 % treatment efficiency for a 500 ml wastewater in 7-day batch cycle in both the cases; while it is lowest in the case of the control cathodes (SS1 (0.07 ± 0.002 m3(H2) m−3d−1) & Cu1 (0.06 ± 0.004 m3(H2) m−3d−1)). It was also found that fabricated cathodes have the capability to treat industrial wastewater at ambient conditions efficiently with higher energy recovery. Prepared cathodes show enhanced hydrogen production and treatment efficiency as well as are competitive to some reported literature.

Published

2021

24. RETRACTED CHAPTER: Hydrogen Gas Production from Paper–Pulp Industry Wastewater by Electrodeposited Cathodes in MECs

Author

Prasenjit Mondal and Amit Kumar Chaurasia

Subjects

Electrolysis, Energy recovery, Materials science, Hydrogen, chemistry.chemical_element, Pulp and paper industry, law.invention, Industrial wastewater treatment, Activated sludge, Wastewater, chemistry, law, Biohydrogen, Hydrogen production

Abstract

In this study, microbial electrolysis cells (MECs) are used for the treatment of actual paper and pulp industry wastewater and production of biohydrogen, for the evaluation of economical and low-cost cathodes. Nickel, nickel–cobalt and nickel–cobalt–phosphate electroplating on SS and Cu rod are explored as-fabricated cathode catalysts in MECs for the estimation of their electrocatalytic activity in terms of energy recovery and treatment efficiency using paper–pulp industry real wastewater. Developed cathodes are explore in MECs in a controlled temperature of 30 ± 2 °C, under applied voltage of 0.6 V at neutral pH with paper–pulp industry wastewater and activated sludge as inoculum. Simultaneous treatment of paper–pulp industry wastewater with hydrogen production rates (1.1–3.87 m3/m3-d) and 54–64% of initial COD removal. Obtained results suggest that fabricated cathodes have potential to become alternative to Pt. for the treatment of real industrial wastewater using MECs. It also indicates that the hydrogen production and MECs performance greatly depend on the composition of wastewater and inoculum. MECs performances were evaluated in terms of hydrogen production rate, columbic efficiencies, overall energy efficiency and volumetric current density.

Published

2021

25. Improved biohydrogen production and treatment of pulp and paper mill effluent through ultrasonication pretreatment of wastewater.

Author

Hay, Jacqueline Xiao Wen, Wu, Ta Yeong, Juan, Joon Ching, and Md. Jahim, Jamaliah

Subjects

*HYDROGEN production, *PAPER mills, *ENERGY consumption, *WASTEWATER treatment, *ENERGY economics

Abstract

Pulp and paper mill effluent (PPME), a rich cellulosic material, was found to have great potential for biohydrogen production through a photofermentation process. However, pretreatments were needed for degrading the complex structure of PPME before biohydrogen production. The aim of this study was to gain further insight into the effect of an ultrasonication process on PPME as a pretreatment method and on photofermentative biohydrogen production using Rhodobacter sphaeroides NCIMB. The ultrasonication amplitudes and times were varied between 30–90% and 15–60 min, respectively, and no dilution or nutrient supplementation was introduced during the biohydrogen production process. A higher biohydrogen yield, rate, light efficiency and COD removal efficiency were attained in conditions using ultrasonicated PPME. Among these different pretreatment conditions, PPME with ultrasonication pretreatment employing an amplitude of 60% and time of 45 min (A60:T45) gave the highest yield and rate of 5.77 mL H 2 /mL medium and 0.077 mL H 2 /mL h, respectively, while the raw PPME without ultrasonication showed a significantly lower yield and rate of 1.10 mL H 2 /mL medium and 0.015 mL H 2 /mL h, respectively. The results of this study demonstrated the potential of using ultrasonication as a pretreatment for PPME because the yield and rate of biohydrogen production were highly enhanced compared to the raw PPME. Economic analysis was also performed in this study, and in comparison with raw PPME, the highest net saving was $0.2132 for A60:T45. [ABSTRACT FROM AUTHOR]

Published

2015

26. Cellulose fibers/polydopamine/zinc sulfide composite paper: predoping in situ fabrication for biphase interface photocatalytic hydrogen production from water.

Author

Zheng, Libo, Zhong, Kaihua, Huang, Xiujie, and Qian, Xueren

Subjects

HETEROJUNCTIONS, CELLULOSE fibers, HYDROGEN production, ZINC sulfide, INTERSTITIAL hydrogen generation, SOLAR cells, HYDROGEN as fuel

Abstract

Solar-driven water splitting by inorganic semiconductor photocatalysts is considered a promising method to produce hydrogen fuel. Loading inorganic semiconductor on cellulose fiber to construct photocatalytic paper contributes to the dispersion and recycling of photocatalyst. In addition, the photocatalytic paper floating on water can build a solid–gas biphase photocatalytic interface (photothermal-generated steam/photocatalytic paper/hydrogen), replacing the traditional liquid–solid–gas triphase photocatalytic interface (liquid water/photocatalyst/hydrogen) for improving photocatalytic kinetics. Here, we design and synthesize a photocatalytic composite paper with zinc sulfide (ZnS) anchored onto cellulose fibers (CF) with the help of polydopamine (PDA). PDA achieves high load and uniform distribution of ZnS on cellulose fibers, and forms the ZnS/PDA heterojunction to increase photogenerated charge separation efficiency and photocatalytic stability. Solid–gas biphase photocatalytic interface constructed by the CF/PDA/ZnS composite paper minimizes the interface barriers of hydrogen transport and water molecular adsorption for improving hydrogen evolution rate. The CF/PDA/ZnS composite paper shows a high hydrogen production rate up to 18706.8 μmol h−1 g−1. Stable loading of ZnS/PDA heterojunction in composite paper contributes to the photocatalytic stability. In the third photocatalytic cycle, the hydrogen evolution rate of CF/PDA/ZnS composite paper remains 96.4%. This work inspires that anchoring of inorganic semiconductor on cellulose fibers with the help of PDA can be a promising strategy for designing efficient photocatalytic paper for solar hydrogen production. [ABSTRACT FROM AUTHOR]

Published

2024

27. Electrochemical reforming of methane using SrZr0.5Ce0.4Y0.1O3-δ proton-conductor cell combined with paper-structured catalyst.

Author

Maeda, Shota, Shiratori, Yusuke, Kurashina, Daisuke, Fujisaki, Takaya, Leonard, Kwati, and Matsumoto, Hiroshige

Subjects

*SOLID state proton conductors, *METHANATION, *FARADAY'S law, *ELECTRIC batteries, *STEAM reforming, *PROTON conductivity, *HYDROGEN production

Abstract

Reforming of hydrocarbon which is an important hydrogen production method proceeds in two steps, i.e. steam reforming and shift reaction. Due to different thermodynamics, the two reactions are conventionally conducted at different temperatures. This study examines one step methane reforming by use of proton-conducting electrochemical cell in combination with a reforming catalyst. Promotion of the reforming reaction was intended by extracting hydrogen via electrochemical hydrogen pumping with a proton conductor cell. In order to compensate for the slow kinetics of the steam reforming, a paper catalyst loaded with Ni was placed in front of the electrochemical cell. Electrolyte support cells were used to verify this concept, and the effect of the electrochemical hydrogen pump was investigated from the composition of the outlet gas. Electrode support cells using a thin film electrolyte was used to reduce overvoltage. It is demonstrated that the steam reforming reaction and the shift reaction take place in one electrochemical cell. Effective catalyst placement and energy efficiency is discussed. Reforming of methane was performed for hydrogen producing with proton conducting SrZr 0.5 Ce 0.4 Y 0.1 O 3-δ (SZCY541) and Ni-loaded paper-structured catalyst (Ni-PSC). When Ni-PSC is used as anode, electrode-supported cell shows enough H 2 evolution rate in agreeing with Faraday's law. Image 1 • Methane reforming was examined using protonic SrZr0.5Ce0.4Y0.1O3-δ electrolyte. • Ni-loaded paper-structured catalyst effectively improved the conversion of CH 4 to H 2. • Electrode-support cell was more effective for steam reforming and the shift reaction. [ABSTRACT FROM AUTHOR]

Published

2020

28. Up-cycling of waste paper for increased photo-catalytic hydrogen generation of graphitic carbon nitride under visible light exposure

Author

Xiaonan Yang, Xu Tian, Mengqi Xue, Daochuan Jiang, and Yupeng Yuan

Subjects

Materials science, General Chemical Engineering, Thermal decomposition, Composite number, Graphitic carbon nitride, chemistry.chemical_element, General Chemistry, chemistry.chemical_compound, chemistry, Amorphous carbon, Chemical engineering, Photocatalysis, Carbon, Hydrogen production, Visible spectrum

Abstract

Background Up-cycling of waste papers to value-added carbon products has significant environmental and economic benefits in real life. This work aims to recycle the waste papers to construct amorphous carbon modified graphitic carbon nitride composite photocatalysts for efficient photocatalytic hydrogen generation from water under visible light. Methods Amorphous carbon (labeled as a-C) was yielded from the office waste papers by simple sulphuric-acid treatment and then combined with graphitic carbon nitride (g-CN) to form the g-CN/a-C composite photocatalysts by the thermolysis of a-C and melamine mixture. Significant Findings The addition of a-C enlarges the surface area of g-CN from 11.52 m2 g−1 of pristine g-CN to 28.12 m2 g−1 of g-CN/a-C-100. In addition, the a-C incorporation can significantly separate the electrons from the photoexcited g-CN owing to the excellent conductivity of a-C. As a result, an increased photocatalytic H2 generation was realized under visible light exposure. The g-CN/a-C-100 sample with optimized a-C contents offers the highest photocatalytic H2 generation rate of up to 17.1 μmol h−1, which is ∼12 times higher than that of pristine g-CN under the same condition. The present study manifests the great potential of the recycling of office waste papers for increased photocatalytic H2 generation.

Published

2021

29. Temperature-phased anaerobic co-digestion of food waste and paper waste with and without recirculation: Biogas production and microbial structure

Author

Benyi Xiao, Aijun Zhu, Jialing Ni, Kengo Kubota, Jing Wu, Yu You Li, Lu Li, Zhe Kong, and Yu Qin

Subjects

Environmental Engineering, 010504 meteorology & atmospheric sciences, Hydrogen, chemistry.chemical_element, 010501 environmental sciences, 01 natural sciences, Methane, chemistry.chemical_compound, Bioreactors, Biogas, Environmental Chemistry, Anaerobiosis, Cellulose, Waste Management and Disposal, 0105 earth and related environmental sciences, Hydrogen production, Sewage, Chemistry, Temperature, Pulp and paper industry, Pollution, Refuse Disposal, Anaerobic digestion, Food waste, Food, Biofuels, Degradation (geology)

Abstract

Two temperature-phased anaerobic digestion (TPAD) systems (55 °C in the first reactor and 35 °C in the second reactor) with and without recirculation were operated in parallel for the co-digestion of food waste and paper waste. A long-term experiment was carried out for these two systems with the paper waste ratios elevated from 0 to 50%. The removal efficiencies of COD, TS, VS, carbohydrate and protein in the recirculated TPAD system were higher than those of the non-recirculated system. The successful acclimation of thermophilic cellulose-degrading bacteria in the first reactor (RT1), partly due to recirculation, ensured the effective degradation of cellulose when the paper waste ratio was higher than 40%, resulting in the production of large amounts of hydrogen in reactor RT1. In the absence of recirculation, the main substance produced in the first reactor of the non-recirculated system (T1) was lactic acid. This gradually led to over-acidification and a low degradation efficiency and no methane or hydrogen was produced in T1. Recirculation helped to establish a stable bacterial community capable of producing bio-hydrogen in reactor RT1. The relatively low pH of 5.5 in the RT1 inhibited the activity of hydrogenotrophic archaea without consuming hydrogen, facilitating high hydrogen production levels.

Published

2019

30. Use of Cellulose for the Production of Photocatalytic Films for Hydrogen Evolution Along the Lines of Paper Production.

Author

Schwarze, Michael, Thiel, Tabea A., Tasbihi, Minoo, Schroeter, Michael, Menezes, Prashanth W., Walter, Carsten, Driess, Matthias, and Schomäcker, Reinhard

Subjects

CELLULOSE, PLATINUM nanoparticles, CARBON nanofibers, HYDROGEN production, FILMMAKING, ATOMIC hydrogen, STEAM reforming

Abstract

Following the example of photovoltaics, one approach to large‐scale photocatalytic hydrogen production is the irradiation of a correspondingly large catalyst area. Paper production is a process in which large areas can already be produced based on the main component: cellulose. Herein, the TiO2 photocatalyst modification PC500, which also uses platinum nanoparticles as a cocatalyst, is supported in two different ways using cellulose. On the one hand, the catalyst is fixed to the surface of a commercial filter paper and, on the other hand, a photocatalytic paper is produced. For comparison, the catalyst is immobilized by means of drop coating using Nafion and measured as a suspension. The cellulose‐stabilized films are active and hydrogen production is comparable with the activity obtained from the drop‐coating method. The experiments show that the aggregation behavior of cellulose can be used to produce photocatalytically active films. The preparation is easy and can be applied to different kinds of (photo)catalysts. Although the films are very active, their stability during reaction due to swelling and hydrogen production must be further improved. [ABSTRACT FROM AUTHOR]

Published

2022

31. Bio-hydrogen production by SSF of paper industry wastes using anaerobic biofilms: A comparison of the use of wastes with/without pretreatment

Author

Leopoldo J. Ríos-González, Yolanda Garza-García, M. M. Rodríguez-Garza, E.B. Herrera-Ramírez, and I.M.M. Moreno-Dávila

Subjects

Central composite design, Hydrogen, Renewable Energy, Sustainability and the Environment, 020209 energy, Energy Engineering and Power Technology, chemistry.chemical_element, 02 engineering and technology, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Pulp and paper industry, Hydrolysis, Fuel Technology, chemistry, 0202 electrical engineering, electronic engineering, information engineering, Fermentation, Response surface methodology, Fiber, 0210 nano-technology, Anaerobic exercise, Hydrogen production

Abstract

In this research, we carried out the process of simultaneous saccharification and fermentation (SSF) of paper industry wastes with/without chemical pretreatment, using reactors in batch with anaerobic biofilms developed in spheres covered with ixtle fiber cord. Biofilms were previously developed a UASB reactor using anaerobic sludge with acid/thermal pretreatment to remove hydrogen consuming bacteria. Subsequently, the process of saccharification and simultaneous fermentation (SSF) of paper industry waste without chemical pretreatment was evaluated using batch reactors with developed anaerobic biofilms. The key process parameters were: pH (4, 5 and 6) and enzyme loading of Celluclast enzyme (10, 40 and 70 FPU) at a temperature of 45° C The results for hydrogen production with paper industry wastes without pretreatment showed optimal working conditions to maximize hydrogen production by SSF process at: pH (5) and an enzyme load of 70 FPU, so the maximum hydrogen yield obtained was 31.188 mmol/h × gSV. The results obtained from the evaluation of the process of SSF performed with paper industry wastes subjected to chemical pretreatment with H 2 SO 4 2.5% showed the optimum working conditions to maximize hydrogen production: pH (4), an enzyme load of 70 FPU, the maximum value of hydrogen yield obtained was 55 844 mmol/h *gSV. The key process parameters were optimized by the response surface methodology (RSM) based on a two factor-three level central composite design (CCD), using as variables: pH (4.5 and 6), enzyme loading of Celluclast ® (10, 40 and 70 UPF) and temperature (45 °C), for paper industry wastes with/without acid pretreatment. The results showed the analysis of variance was performed to test the importance of the polynomial equation of second order, so equations obtained for both residues (with/without pretreatment) describe the hydrogen yield in this study.

Published

2017

32. Comparison of various structure designs of SO2-depolarized electrolysis cell.

Author

Ma, Xiaoshan, Ding, Xifeng, Xiao, Peng, Wang, Laijun, Qu, Yongshui, Zhang, Ping, and Chen, Songzhe

Subjects

*CARBON paper, *ELECTROLYTIC cells, *DRAG (Hydrodynamics), *PRESSURE drop (Fluid dynamics), *FLUID flow

Abstract

SO 2 -depolarized electrolysis (SDE) is the key step of the hybrid sulfur (HyS) process, which is one of the simplest thermochemical cycles for producing hydrogen by water splitting. Exploration and optimization of flow field/structure design is essential for improving the efficiency of SDE. In this work, graphite plates with different flow channels, together with porous graphite felts or carbon papers as diffusion layers are adopted to fabricate SDE cells with different structures. Evaluation of the cell structures is carried out, by comparing the SDE performance and taking into account the fluid resistance (pressure drop) of anode side. The effects of graphite felt compression ratio, hydrophilicity or hydrophobicity of carbon papers, anodic fluid flow rate, and operating temperature on the SDE performance are investigated. Square porous flow fields provided by graphite felts show excellent performance. Serpentine channel covered by hydrophobic carbon paper reveals advantages when adopted on the cathode side. Combination of above two flow fields and using them on anode and cathode sides respectively, could achieve excellent SDE performance. Under the condition of 40 °C and 360 mL/min anolyte flow rate, the current density could reach 760 mA/cm2 at the cell voltage of 1.19 V. • 16 SDE cells are fabricated with different flow field plates and diffusion layers. • Performance of electrolytic cells with different structure varies greatly. • Anodic fluid resistance used to assist analysis of performance difference of cells. • Effects of felt compression ratio and carbon paper hydrophobicity are discussed. • High performance achieved by arranging GF & hydrophobic carbon paper properly. [ABSTRACT FROM AUTHOR]

Published

2023

33. Enhancing reaction interface with modified microporous layers for high-efficiency hydrogen production in PEM water electrolysis.

Author

Ding, Lei, Xie, Zhiqiang, Wang, Weitian, and Zhang, Feng-Yuan

Subjects

*CARBON paper, *WATER electrolysis, *INTERFACIAL resistance, *HYDROGEN production, *ELECTRON transport

Abstract

Improving the reaction interface is imperative for increasing catalyst utilization and enhancing overall cell performance in proton exchange membrane electrolyzer cells (PEMECs). Herein, a thin Nafion-carbon-mixed microporous layer coated carbon paper (Nafion-C MPL/CP) is first developed as an efficient cathode liquid/gas diffusion layer for PEMECs. With the Nafion-C MPL/CP, low cell voltages of 1.64, 1.74 and 1.84 V are delivered, which are 50, 80 and 140 mV lower than those of the conventional bare carbon paper at 2, 4 and 6 A/cm2, respectively, achieving about 3-fold higher catalyst utilization. Meanwhile, superior performance is also demonstrated compared to the commercial PTFE-C MPL/CP. The remarkable performance of the Nafion-C MPL/CP should be attributed to the enhanced reaction interface, which not only provides rich active sites with abundant electron and proton transport pathways for the electrochemical reaction but also reduces the interfacial contact resistance and mass transport losses. Moreover, excellent stability of the Nafion-C MPL/CP is demonstrated at a current density of 1.8 A/cm2 with no performance degradation during over 100-h operation. Due to the enhanced reaction interface with significantly improved catalyst utilization, the developed Nafion-C MPL/CP shows great potential to reduce the hydrogen production cost and accelerate PEMEC commercialization. [ABSTRACT FROM AUTHOR]

Published

2024

34. Nanoporous oxide coating on carbon paper electrodes to enable bio-hydrogen production in microbial electrolysis cells.

Author

Srivastava, Pratiksha, González, Cristina, Palma, Jesus, and Garcia-Quismondo, Enrique

Subjects

*CARBON electrodes, *OXIDE coating, *CARBON paper, *MICROBIAL cells, *ELECTROLYSIS, *OXIDE electrodes, *MICROBIAL fuel cells

Abstract

To counteract expensive cathodes, a single chamber microbial electrolysis cell (MEC) equipped with nanoporous oxide coating on a carbon paper electrode as a cathode was explored. The performance of the MEC was evaluated based on the chemical oxygen demand (COD) removal efficiency, catalytic activity, and hydrogen production. The obtained results indicated that nanoporous oxide coated carbon electrode with TiO 2 achieved maximum H 2 yield (3.0 mol H 2 mol−1 acetate), followed by ZrO 2 and SiO 2. In contrast, the uncoated carbon electrode achieved lower hydrogen yield (0.08 mol H 2 mol−1 acetate). A maximum COD removal of 82% was achieved from the carbon electrode coated with TiO 2 followed by 80.5% from SiO 2 and 79% from ZrO 2. Additionally, based on linear sweep voltammetry, nanoporous oxide coated electrodes started H 2 evolution at a lower potential than the uncoated electrode, thereby exhibiting a higher catalytic rate. This investigation showed that carbon electrodes with nanoporous coating can be one of the economical (low cost) and potential electrodes to be used as a cathode in the MEC for hydrogen production instead of expensive metallic electrodes. [Display omitted] • Low-cost, high potential cathode electrodes were explored. • Nanoporous oxide coated electrodes exhibited high catalytic activity. • Efficient H 2 production with low applied potential. • H 2 yield was higher for nanoporous coated electrodes than uncoated. [ABSTRACT FROM AUTHOR]

Published

2023

35. Hydrogen Production Using Electrodeposited Ni and Ni/Co on Carbon Paper as Cathode Catalyst in Microbial Electrolysis Cells

Author

Yuxue Wang

Subjects

Electrolysis, Materials science, business.product_category, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, law.invention, Cathode catalyst, Chemical engineering, law, Electrochemistry, Carbon paper, 0210 nano-technology, business, Hydrogen production

Published

2018

36. Effect of catalyst distribution in the combustion catalytic layer on heat and mass transport characteristics of the microchannel reactor

Author

Kong, Weiqiang, Shen, Qiuwan, Huang, Naibao, Yan, Min, and Li, Shian

Published

2024

37. Bio-hydrogen production by SSF of paper industry wastes using anaerobic biofilms: A comparison of the use of wastes with/without pretreatment.

Author

Moreno-Dávila, I.M.M., Herrera-Ramírez, E.B., Rodríguez-Garza, M.M., Garza-García, Y., and Ríos-González, L.J.

Subjects

*HYDROGEN production, *ANAEROBIC reactors, *RESPONSE surfaces (Statistics), *BIOFILMS, *PAPER industry, *MANAGEMENT

Abstract

In this research, we carried out the process of simultaneous saccharification and fermentation (SSF) of paper industry wastes with/without chemical pretreatment, using reactors in batch with anaerobic biofilms developed in spheres covered with ixtle fiber cord. Biofilms were previously developed a UASB reactor using anaerobic sludge with acid/thermal pretreatment to remove hydrogen consuming bacteria. Subsequently, the process of saccharification and simultaneous fermentation (SSF) of paper industry waste without chemical pretreatment was evaluated using batch reactors with developed anaerobic biofilms. The key process parameters were: pH (4, 5 and 6) and enzyme loading of Celluclast enzyme (10, 40 and 70 FPU) at a temperature of 45° C The results for hydrogen production with paper industry wastes without pretreatment showed optimal working conditions to maximize hydrogen production by SSF process at: pH (5) and an enzyme load of 70 FPU, so the maximum hydrogen yield obtained was 31.188 mmol/h × gSV. The results obtained from the evaluation of the process of SSF performed with paper industry wastes subjected to chemical pretreatment with H 2 SO 4 2.5% showed the optimum working conditions to maximize hydrogen production: pH (4), an enzyme load of 70 FPU, the maximum value of hydrogen yield obtained was 55 844 mmol/h *gSV. The key process parameters were optimized by the response surface methodology (RSM) based on a two factor-three level central composite design (CCD), using as variables: pH (4.5 and 6), enzyme loading of Celluclast ® (10, 40 and 70 UPF) and temperature (45 °C), for paper industry wastes with/without acid pretreatment. The results showed the analysis of variance was performed to test the importance of the polynomial equation of second order, so equations obtained for both residues (with/without pretreatment) describe the hydrogen yield in this study. [ABSTRACT FROM AUTHOR]

Published

2017

38. Enzymatic saccharification and fermentation of paper and pulp industry effluent for biohydrogen production

Author

Lakshmidevi, Rajendran and Muthukumar, Karuppan

Subjects

*WASTE paper, *FERMENTATION, *HYDROGEN production, *ENTEROBACTER aerogenes, *PAPER industry, *PULP mills, *HYDROLYSIS, *ENZYME activation

Abstract

Abstract: Paper and pulp industry effluent was enzymatically hydrolysed using crude cellulase enzyme (0.8–2.2FPU/ml) obtained from Trichoderma reesei and from the hydrolysate biohydrogen was produced using Enterobacter aerogenes. The influence of temperature and incubation time on enzyme production was studied. The optimum temperature for the growth of T. reesei was found to be around 29°C. The enzyme activity of 2.5FPU/ml was found to produce about 22g/l of total sugars consisting mainly of glucose, xylose and arabinose. Relevant kinetic parameters with respect to sugars production were estimated using two fraction model. The enzymatic hydrolysate was used for the biohydrogen production using E. aerogenes. The growth data obtained for E. aerogenes were fitted well with Monod and Logistic equations. The maximum hydrogen yield of 2.03mol H2/mol sugar and specific hydrogen production rate of 225mmol of H2/g cell/h were obtained with an initial concentration of 22g/l of total sugars. The colour and COD of effluent was also decreased significantly during the production of hydrogen. The results showed that the paper and pulp industry effluent can be used as a substrate for biohydrogen production. [Copyright &y& Elsevier]

Published

2010

39. Ni(NO3)2-induced high electrocatalytic hydrogen evolution performance of self-supported fold-like WC coating on carbon fiber paper prepared through molten salt method.

Author

Zhang, Lei, Huang, Juntong, Hu, Zhihui, Li, Xibao, Ding, Tianyi, Hou, Xifeng, Chen, Zhi, Ye, Zhiguo, and Luo, Ruiying

Subjects

*HYDROGEN evolution reactions, *CARBON paper, *FUSED salts, *CARBON fibers, *HYDROGEN as fuel, *CATALYST structure, *HYDROGEN production

Abstract

• Self-supporting x Ni-WC@CFP catalysts with fold-like structure were prepared through one-step molten salt method. • 4M Ni-WC@CFP showed excellent HER activity in 0.5 M H 2 SO 4 (overpotential of 73 mV at 10 mA cm−2 and Tafel slope of 66.4 mV dec−1). • The increasing concentration of Ni(NO 3) 2 promoted first and then inhibited the catalytic performance of x Ni-WC@CFP electrocatalysts, resulting from the synergistic effect of Ni and W on hydrogen adsorption energy. Exploring high-performance and inexpensive electrocatalysts for hydrogen evolution reaction to substitute Pt-based compounds is important to sustain hydrogen production. Herein, WC based self-supported catalysts doped with different concentration of nickel nitrate solution (Ni(NO 3) 2) were synthesized on carbon fiber paper (CFP) by one-step molten salt method (abbreviated as x Ni-WC@CFP). With the increasing of Ni(NO 3) 2 concentration, fold-like structures were formed on the catalysts, which was conducive to active sites exposure. As Ni(NO 3) 2 concentration increased from 1M to 5M, the catalytic performance of the electrocatalyst showed a trend of increasing first and then decreasing. The optimal 4M Ni-WC@CFP showed comparable catalytic ability in 0.5M H 2 SO 4 with a low overpotential of 73 mV at 10 mA cm−2 and Tafel slope of 66.4 mV dec−1. However, excessive nickel doping would inhibit HER performance. The density functional theory calculation further verified the experimental results. The adsorption energy of hydrogen showed a decreasing trend with the rising amount of Ni doped in, while the W-H binding energy would change in an opposite direction as over doped Ni. This work provided an insight for the preparation of high-efficiency self-supported W-based electrocatalysts and expounded the influence trend of Ni doping concentration on the performance of electrocatalysts. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2022

40. Biological hydrogen production from paper mill effluent via dark fermentation in a packed bed biofilm reactor.

Author

Namdarimonfared, Mahboubeh, Zilouei, Hamid, and Tondro, Hadiseh

Subjects

*PACKED bed reactors, *HYDROGEN production, *PAPER mills, *UPFLOW anaerobic sludge blanket reactors, *INTERSTITIAL hydrogen generation, *FERMENTATION

Abstract

[Display omitted] • Evaluation of dark fermentative hydrogen production using paper mill effluent (PME) • Investigation of the impact of different HRTs on the biofilm reactor performance. • H 2 production rate was enhanced to 6.21 L H 2 d−1 L−1 by decreasing HRT to 2 h. • Max. yield of H 2 was 0.96 mmol H 2 g−1 COD at 8 h HRT. • Production of VFAs as valuable by-products as well as COD removal. This study assessed the feasibility of continuous hydrogen production in an anaerobic packed bed biofilm reactor (APBR) using paper mill effluent (PME) without any pretreatment or modification. To form a microbial biofilm on supports, the reactor was seeded with a thermal pretreated anaerobic sludge. After the start-up stage, under mesophilic conditions and pH control, the system performance in the case of hydrogen production as biofuel and VFAs as valuable by-products as well as COD removal was investigated at different hydraulic retention times (HRTs) (24, 16, 12, 8, 4, 2 and 1.2 h). The highest hydrogen concentration in the produced gas was 41.5 % obtained at HRT 4 h. The highest hydrogen production rate and yield were 6.21 L H 2 d−1 L−1 at HRT 2 h and 0.96 mmol H 2 g−1 COD at HRT 8 h, respectively. With decreasing the HRT from 24 to 1.2 h, the OLR was increased from 27.35 to 547 g COD L−1 d−1 that positively affect the hydrogen production rate for all HRTs except for the shortest HRT. Furthermore, COD removal efficiency was reduced from 25.2 to 6 %. Low value of COD removal efficiency is because of conversion of organic inlet to valuable metabolites such as VFAs in the effluent. [ABSTRACT FROM AUTHOR]

Published

2023

41. Effects of N/C, P/C and Fe/C ratios on dark fermentative hydrogen gas production from waste paper towel hydrolysate

Author

Hidayet Argun and Gülizar Onaran

Subjects

Hydrogen, Activated carbon, Energy Engineering and Power Technology, chemistry.chemical_element, 02 engineering and technology, Quadratic modeling, Hydrolysate, Independent variables, 0502 economics and business, medicine, Acid hydrolysis, Nutrient formulation, Objective functions, 050207 economics, Hydrogen production, Renewable Energy, Sustainability and the Environment, Chemistry, Hydrolysis, 05 social sciences, Production performance, Production, Dark fermentation, Waste paper, Statistical experiments, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Carbon, Fuel Technology, Biochemistry, Yield (chemistry), Fermentation, Fermentation media, 0210 nano-technology, Acids, Nuclear chemistry, medicine.drug

Abstract

The effects of N/C, P/C and Fe/C ratios on dark fermentative hydrogen gas production from activated carbon treated WPT hydrolysate were investigated using Box-Behnken statistical experiment design. N/C, P/C and Fe/C ratios were chosen as independent variables while the H-2 yield and SHPR were set as the objective functions. H-2 yield and SHPR functions were described by two quadratic model functions. The addition of a proper amount of N, P and Fe to the fermentation media was found to be essential to enhance the H-2 production performance. Linear and interaction terms of N/C and Fe/C did have a significant effect on the H-2 yield in the model function. However, the SHPR was significantly affected by the linear and interaction terms of N/C and P/C. The most convenient N/C, P/C and Fe/C ratios resulting maximum H-2 yield (0.656 mol H-2/mol glucose) and SHPR (241.64 mL H-2/g biomass.h) were determined as 0.05, 0.09 and 0.003 (w/w), respectively. (C) 2017 Hydrogen Energy Publications LLC. Published by Elsevier Ltd. All rights reserved.

Published

2017

42. Electrochemical reforming of methane using SrZr0.5Ce0.4Y0.1O3-δ proton-conductor cell combined with paper-structured catalyst

Author

Shota Maeda, Kwati Leonard, Daisuke Kurashina, Hiroshige Matsumoto, Yusuke Shiratori, and Takaya Fujisaki

Subjects

Materials science, Hydrogen, Methane reformer, Renewable Energy, Sustainability and the Environment, education, Energy Engineering and Power Technology, chemistry.chemical_element, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Water-gas shift reaction, 0104 chemical sciences, Electrochemical cell, Catalysis, Steam reforming, Fuel Technology, chemistry, Chemical engineering, 0210 nano-technology, health care economics and organizations, Hydrogen production, Proton conductor

Abstract

Reforming of hydrocarbon which is an important hydrogen production method proceeds in two steps, i.e. steam reforming and shift reaction. Due to different thermodynamics, the two reactions are conventionally conducted at different temperatures. This study examines one step methane reforming by use of proton-conducting electrochemical cell in combination with a reforming catalyst. Promotion of the reforming reaction was intended by extracting hydrogen via electrochemical hydrogen pumping with a proton conductor cell. In order to compensate for the slow kinetics of the steam reforming, a paper catalyst loaded with Ni was placed in front of the electrochemical cell. Electrolyte support cells were used to verify this concept, and the effect of the electrochemical hydrogen pump was investigated from the composition of the outlet gas. Electrode support cells using a thin film electrolyte was used to reduce overvoltage. It is demonstrated that the steam reforming reaction and the shift reaction take place in one electrochemical cell. Effective catalyst placement and energy efficiency is discussed.

Published

2020

43. Biomass and biohydrogen production during dark fermentation of Escherichia coli using office paper waste and cardboard

Author

Lena Margaryan, Anna Poladyan, Karen Trchounian, and Armen Trchounian

Subjects

Hydrogenase, Renewable Energy, Sustainability and the Environment, Chemistry, Energy Engineering and Power Technology, Biomass, 02 engineering and technology, Dark fermentation, Bacterial growth, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Hydrolysate, 0104 chemical sciences, Fuel Technology, Yeast extract, Biohydrogen, Food science, 0210 nano-technology, Hydrogen production

Abstract

Growth properties, oxidation-reduction potential kinetics and hydrogen production of Escherichia coli BW25113 parental strain (PS) and hydrogenase (Hyd)-negative mutants were investigated after fermentative growth using office paper waste and cardboard (PW) hydrolysate (PWH). PWH was obtained by using dilute acid method in a steam sterilizer for 1 h, 121 °C. Optimal conditions for bacterial growth and H2 production were identified (PWH concentrations, pH 7.5). Recording of redox potential using a platinum electrode revealed a drop to −500 ± 10 mV, with a H2 yield of ~1.45 mmol H2 L−1 after 4 h of growth using PWH resulted in the formation of 0.20 ± 0.02 g bacterial cell dry weight L−1. Bacterial biomass formation was stimulated ~3-fold upon addition of 0.5% yeast extract, and H2 production started early - at the beginning of the exponential phase. Moreover, mutants lacking Hyd-1 and Hyd-2 significantly enhanced H2 production. The findings would be beneficial for the development of H2 production biotechnology using cheap solid waste materials.

Published

2020

44. Dark fermentative hydrogen gas production from lime treated waste paper towel hydrolysate

Author

Gülizar Onaran and Hidayet Argun

Subjects

Paper, Environmental Engineering, Hydrogen, Paper products, Putty, Biomass, chemistry.chemical_element, Lime, 02 engineering and technology, 010501 environmental sciences, engineering.material, 01 natural sciences, Hydrolysate, Hydrolysis, Glucose concentration, Hydrolysis conditions, Adhesives, Independent variables, Acid hydrolysis, Food science, Glucose production, Objective functions, Waste Management and Disposal, 0105 earth and related environmental sciences, Waste management, Renewable Energy, Sustainability and the Environment, Chemistry, Waste paper towel, Dark fermentation, 021001 nanoscience & nanotechnology, Waste paper, Statistical experiments, Waste treatment, Glucose, Yield (chemistry), Fermentation, engineering, Hydrogen production, 0210 nano-technology, Detoxification, Lime putty

Abstract

This study presents dark fermentative hydrogen gas production from acid hydrolysed waste paper towel hydrolysate. Firstly, Box-Behnken statistical experiment design was used to investigate glucose production from waste paper towel by acid hydrolysis. S/L ratio, hydrolysis time and pH were chosen as independent variables while glucose concentration in the hydrolysate was the objective function. Highest glucose concentration of 32.17 g/L was obtained at S/L ratio of 100 g/L, pH 0 (gauge pH) and 180 min hydrolysis time. All variables were found to have significant effect on glucose formation. Glucose concentration increased by increasing the S/L ratio and hydrolysis time, but decreased by increasing the pH. Secondly, the hydrolysate obtained at most convenient hydrolysis conditions was subjected to lime putty treatment for the removal of 5-HMF and SO4 2-. Thirdly, H2 gas was produced from the detoxified hydrolysate by dark fermentation. Maximum H2 formation yield, rate and H2 percentage in the gas phase were 1.02 mol H2/mol glucoseconsumed, 130.22 mL H2/g biomass.h and 43%, respectively. The remaining 5-HMF after lime treatment was effectively removed in dark fermentation. © 2017, Springer Science+Business Media Dordrecht.

Published

2018

45. Reusing pulp and paper mill effluent as a bioresource to produce biohydrogen through ultrasonicated Rhodobacter sphaeroides.

Author

Hay, Jacqueline Xiao Wen, Wu, Ta Yeong, Ng, Boon Junn, Juan, Joon Ching, and Md. Jahim, Jamaliah

Subjects

*HYDROGEN production, *NATURAL resources, *RHODOBACTER sphaeroides, *PAPER industry, *RAW materials, *FERMENTATION

Abstract

Pulp and paper industry is a water-intensive industry. This industry commonly produces considerable amount of effluent, especially from virgin raw materials processing. The effluent, namely pulp and paper mill effluent has the potential to adversely affect the receiving watercourses. However, the nutrients in the pulp and paper mill effluent could be reused as a substrate in biohydrogen production. In this study, photofermentative biohydrogen production was investigated using Rhodobacter sphaeroides and pulp and paper mill effluent as a substrate. An application of low power ultrasound on R. sphaeroides was predicted to increase photofermentative biohydrogen production but excessive ultrasound effects might inhibit the production due to possible cell disruption. Hence, various ultrasonication duration (5, 10 and 15 min) and amplitude (15%, 30% and 45%) were applied on the bacteria to determine the recommended ultrasonication conditions for improving biohydrogen production. The recommended conditions were operated at ultrasonication amplitude and duration of 30% and 10 min, respectively. A maximum biohydrogen yield of 9.62 mL bioH 2 /mL medium was obtained under this condition, which was 66.7% higher than the result obtained using R. sphaeroides without undergoing ultrasonication (control). The light efficiency and cell concentration were increased by 67% and 150%, respectively, using ultrasonication amplitude and duration of 30% and 10 min, respectively as compared to the control. The present results demonstrated that moderate power of ultrasonication applied on R. sphaeroides was an effective method for enhancing photofermentative biohydrogen production using raw pulp and paper mill effluent as a bioresource. [ABSTRACT FROM AUTHOR]

Published

2016

46. Hydrogen, ethanol and cellulase production from pulp and paper primary sludge by fermentation with Clostridium thermocellum.

Author

Moreau, Alexandre, Montplaisir, Daniel, Sparling, Richard, and Barnabé, Simon

Subjects

*HYDROGEN production, *ETHANOL as fuel, *PAPER industry, *SLUDGE management, *CLOSTRIDIUM thermocellum, *LIGNOCELLULOSE

Abstract

Pulp and paper industry primary sludge being largely composed of lignocellulosic fibres, it could be used as carbon source by bacteria having cellulolytic capability. The aim of this study was to evaluate the use of cellulose contained in this type of sludge for Clostridium thermocellum to produce ethanol, hydrogen and cellulases. In an ATCC 1191 medium containing 5 kg m −3 dry primary sludge from recycled paper mill, batch culture reached stationary phase after 2 days. All of the available cellulose was hydrolysed after 60 h of incubation, with a final pH of 5.83. Metabolites produced after 60 h of fermentation were acetate (8.50 mol m −3 ), ethanol (11.30 mol m −3 ), lactate (8.75 mol m −3 ), formate (0.27 mol m −3 ), hydrogen (11.20 mol m −3 ) and carbon dioxide (18.41 mol m −3 ). Cellulase activity was detected in the supernatant after 36 h, with a maximal activity of 0.25 U cm −3 at 72 h. Pulp and paper primary sludge appeared to be a readily usable substrate for C. thermocellum at this concentration, yielding both potential biofuels (hydrogen and ethanol) as well as active cellulases. [ABSTRACT FROM AUTHOR]

Published

2015

47. Hierarchical Ni–Mo–P nanoarrays toward efficient urea oxidation reaction.

Author

Li, Jing, Hu, Feng, Hei, Jinpei, Liu, Guoan, Wei, Hui, Wang, Nannan, and Wei, Hehe

Subjects

OXYGEN evolution reactions, HYDROGEN evolution reactions, UREA, CATALYTIC activity, CARBON paper, OXIDATION, HYDROGEN production

Abstract

The urea oxidation reaction (UOR), which possesses a low theoretical potential and superior kinetics, is an attractive substitute for the anodic oxygen evolution reaction (OER) in overall water splitting; however, the implementation of hydrogen production in overall urea splitting is impeded by the deficiency of highly efficient, durable and cost-effective catalysts. Herein, we fabricated an Ni2P–MoP2 heterostructure with a hierarchical structure grown on carbon paper (Ni–Mo–P/CP), which exhibited robust activity and outstanding durability for the electrocatalytic oxidation of urea. The Ni–Mo–P/CP catalyst possessed an ultralow potential of 1.39 V to obtain the current density of 100 mA cm−2, small Tafel slope (27 mV dec−1) and long-term durability with almost no decay within 15 h. The experimental characterization revealed that the optimized electronic structure and the synergistic effect of abundant exposed active sites in the Ni–Mo–P/CP catalyst contribute to the efficient UOR catalytic activity. This work enriches the candidate catalysts for the UOR and promotes the industrial development of hydrogen production. [ABSTRACT FROM AUTHOR]

Published

2022

48. Ultrasonication pre-treatment of combined effluents from palm oil, pulp and paper mills for improving photofermentative biohydrogen production.

Author

Budiman, Pretty Mori and Wu, Ta Yeong

Subjects

*SONICATION, *HYDROGEN production, *PAPER mills, *CHEMICAL oxygen demand, *RHODOBACTER sphaeroides, *CARBON content of water, *WASTEWATER treatment

Abstract

The improvement of batch photofermentative biohydrogen production was investigated using ultrasonication pre-treatment on a combined effluent of palm oil and pulp and paper mills. The effects of the amplitude (30–90%) and ultrasonication duration (5–60 min) were investigated in terms of their influences on the biohydrogen yield and chemical oxygen demand (COD) removal. The recommended ultrasonication parameters were found at the higher ranges of amplitude and duration (A70T45). Using A70T45 ultrasonication, the production of biohydrogen at 30 °C could be enhanced up to 8.72 mL H 2 /mL medium , with a total COD removal of 36.9%. During pre-treatment at A70T45, an energy input of 775 J/mL was supplied to disintegrate complex compounds into simpler structures. As a result, an increase in the soluble organic matter concentration was achieved, which led to enhanced biohydrogen production. On the other hand, the lowest biohydrogen yield (4.67 mL H 2 /mL medium ) and total COD removal (28.8%) were obtained in the control without pre-treatment. The enthalpy of the photofermentation process was estimated to be 141.1 kJ/mol with a threshold temperature of 30.9 °C based on a modified Arrhenius approach. [ABSTRACT FROM AUTHOR]

Published

2016

49. A flexible paper-based hydrogen fuel cell for small power applications

Author

Yifei Wang, Yingguang Zhang, Holly Y.H. Kwok, Huimin Zhang, Dennis Y.C. Leung, Wending Pan, and Xu Lu

Subjects

Materials science, Renewable Energy, Sustainability and the Environment, business.industry, Open-circuit voltage, Energy Engineering and Power Technology, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, 0104 chemical sciences, Hydrogen storage, Fuel Technology, Power rating, Electrode, Optoelectronics, 0210 nano-technology, business, Faraday efficiency, Power density, Voltage, Hydrogen production

Abstract

In this work, a paper-based hydrogen fuel cell is developed without the need for hydrogen storage. Instead, an embedded aluminum foil inside the paper is utilized for in-situ hydrogen generation. The electrodes and current collectors are also deposited on the paper, leading to a lightweight, compact and flexible hydrogen fuel cell with an OCV reaching 0.93 V and a peak power density of 4 mW cm−2. Benefited from the impeded hydroxyl ion diffusion, the hydrogen generation rate is well controlled, leading to a high faradaic efficiency of 72%. In addition, the cell can be operated under different bending angles with negligible power loss. Furthermore, it can be conveniently stacked in the same piece of paper for higher voltage and power outputs. Such a novel fuel cell design is especially suitable for powering various flexible devices with small rated power.

Published

2019

50. Comparative assessment of the scientific structure of biomass-based hydrogen from a cross-domain perspective.

Author

Okuda, Kunihiko and Sasaki, Hajime

Subjects

HYDROGEN as fuel, SUSTAINABILITY, BIOMASS energy, ENERGY development, HYDROGEN production

Abstract

Biomass-based hydrogen production is an innovative approach for realizing carbon-neutral energy solutions. Despite their promise, both structures differ in terms of the biomass energy domain, which is at the entry point of the technology, and the hydrogen energy domain, which is at the exit point of the technology. In this study, we conducted structural and predictive analyses via cross-domain bibliometric analysis to clarify the differences in the structures and perspectives of researchers across domains and to suggest ways to strengthen collaboration to promote innovation. Our study revealed that the hydrogen energy domain has a balanced impact on realizing a hydrogen society using biomass-based hydrogen production technology, while the biomass energy domain has a strong interest in the process of processing biomass. The results reveal that different communities have different ideas about research, resulting in a divide in the areas to be achieved. This comparative analysis reveals the importance of synergistic progress through interdisciplinary efforts. By filling these gaps, our findings can lead to the development of a roadmap for future research and policy development in renewable energy and highlight the importance of a unified approach to sustainable hydrogen production. The contribution of this study is to provide evidence for the importance of cross-disciplinary cooperation for R&D directors and policy makers. [ABSTRACT FROM AUTHOR]

Published

2024