Fermentative hydrogen production by diverse microflora

In this study, hydrogen production with activated sludge, a diverse bacterial source has been investigated and compared to microflora from anaerobic digester sludge, which is less diverse. Batch experiments were conducted at mesophilic (37 °C) and thermophilic (55 °C) temperatures. The hydrogen production yields with activated sludge at 37 °C and 55 °C were 0.56 and 1.32 mol H₂/mol glucose consumed, respectively. While with anaerobically digested sludge hydrogen yield was 2.18 mol H₂/mol glucose consumed at 37 °C and 1.25 mol H₂/mol glucose consumed at 55 °C. The results of repeated batch experiments for 615 h resulted in average yields of 1.21 ± 0.62 and 1.40 ± 0.16 mol H₂/mol glucose consumed for activated sludge and anaerobic sludge, respectively. The hydrogen production with activated sludge was not stable during the repeated batches and the fluctuation in hydrogen production was attributed to formation of lactic acid as the predominant metabolite in some batches. The presence of lactic acid bacteria in microflora was confirmed by PCR-DGGE.     

Enhancement of biohydrogen producing using ultrasonication

Ultrasonication was evaluated as a pretreatment for biological hydrogen production from glucose in batch studies, in comparison with heat-shock pretreatment, acid pretreatment, and base pretreatment. The optimized sonication energy for hydrogen production using anaerobic digester sludge was 79 kJ/gTS. Sonication with temperature control (less than 30 °C) increased volumetric hydrogen production by 120% over the untreated sludge, and by 40% over the heat-shock and acid pretreated sludge, with a marginal (∼10%) increase in hydrogen production rate. Upon comparing the molar hydrogen yield in sonicated sludge with and without temperature control, the deleterious effect of heat on some hydrogen producers as reflected by a 30% decrease in yield to 1.03 mol H₂/mol glucose is evident. Sonication with temperature control affected a 45% increase in molar hydrogen yield to 1.55 mol H₂/mol glucose over heat-shock pretreatment at 70 °C for 30 min and acidification to pH 3.0 for 24 h at 4 °C. Sonication with temperature control produced a biomass yield of 0.13 g VSS/g COD, as compared to 0.24 g VSS/g COD for the untreated sludge. The hydrogen yield increased linearly with the molar acetate to butyrate ratio and decreased linearly with the biomass yield.     

预处理温度对活性污泥发酵产氢特性的影响

为寻求适宜的种泥热处理方法,利用摇瓶发酵实验,考察了城市污水处理厂好氧活性污泥分别经65、80、95、110℃热处理30min后,其利用葡萄糖发酵产氢的特性。结果表明:在初始pH=7.0、葡萄糖浓度10g/L、接种量2gMLVSS/L条件下,35℃培养72h,经65℃和95℃处理的种泥表现出较好的发酵产氢性能,其葡萄糖的氢气转化率分别达到1.08和1.11mol/mol,污泥的比产氢率分别为8.36和9.05mmol/gMLVSS;经65℃预处理的种泥发酵体系,表现为丁酸型发酵,其葡萄糖降解率和最大产氢速率分别高达82%和11.29mL/h,而经95℃预处理的种泥发酵体系则呈现混合酸发酵特征,其葡萄糖转化率和最大产氢速率分别仅为76%和4.45mL/h。     

Evaluation of pretreatment methods on harvesting hydrogen producing seeds from anaerobic digested organic fraction of municipal solid waste (OFMSW)

In order to harvest high-efficient hydrogen producing seeds, five pretreatment methods (including acid, heat, sonication, aeration and freeze/thawing) were performed on anaerobic digested sludge (AS) which was collected from a batch anaerobic reactor for treating organic fraction of municipal solid waste. The hydrogen production tests were conducted in serum bottles containing 20 gVS/L (24.8 g COD/L) mixture of rice and lettuce powder at 37 °C. The experimental results showed that the heat and acid pretreatment completely repressed the methanogenic activity of AS, but acid pretreatment also partially repressed hydrogen production. Sonication, freeze/thawing and aeration did not completely suppress the methanogen activity. The highest hydrogen yields were 119.7, 42.2, 26.0, 23.0, 22.7 and 22.1 mL/gVS for heated, acidified, freeze/thawed, aerated, sonicated and control AS respectively. A pH of about 4.9 was detected at the end of hydrogen producing fermentation for all tests. The selection of an initial pH can markedly affect the hydrogen producing ability for heated and acidified AS. The higher initial pH generated higher hydrogen yield and the highest hydrogen yield was obtained with initial pH 8.9 for heated AS.     

Gamma irradiation as a pretreatment method for enriching hydrogen-producing bacteria from digested sludge

Gamma irradiation was used as a pretreatment method for enriching hydrogen-producing bacteria from digested sludge. The experimental results demonstrated that 5.0 kGy was optimal dose among the different doses (0.5–10 kGy) applied in this study. The maximum cumulative hydrogen production, hydrogen yield, hydrogen production rate and substrate degradation efficiency of the sludge irradiated at such dose were 529.4 mL, 267.7 mL/g glucose, 37.25 mL/h and 98.9%, respectively when the fermentation conditions were as follows: at 36 °C, initial pH 7.0 and 10 g/L glucose as substrate. In comparison with the conventional pretreatment methods, such as heat-shock, acid, base, aeration and chloroform, gamma irradiation was more powerful pretreatment method for enriching hydrogen-producing bacteria. The effect of Gamma irradiation on the microbial community structure of the pretreated sludge needs further study.     

Extreme-thermophilic biohydrogen production by an anaerobic heat treated digested sewage sludge culture

Biohydrogen production process from glucose using extreme-thermophilic H₂-producing bacteria enriched from digested sewage sludge was investigated for five cycles of repeated batch experiment at 70 °C. Heat shock pretreatment was used for preparation of hydrogen-producing bacteria comparing to an untreated anaerobic digested sludge for their hydrogen production performance and responsible microbial community structures. The results showed that the heat shock pretreatment completely repressed methanogenic activity and gave the maximum hydrogen production yield of 355-488 ml H₂/g COD in the second cycle of repeated batch cultivation with more stable gas production during the cultivation when compared with control. Hydrogen production was accompanied by production of acetic acid. The average specific hydrogen in five cycles experiment ranged from 150 to 200 ml H₂/g VSS. PCR-DGGE profiling showed that the extreme-thermophilic culture predominant species were closely affiliated to Thermoanaerobacter pseudethanolicus.     

Biohydrogen production from apple pomace by anaerobic fermentation with river sludge

The biological hydrogen (bio-H₂) production from apple pomace (AP) by fermentation using natural mixed microorganisms in batch process was studied under various experimental conditions. The river sludge was used as a seed after being boiled for 15 min. The results show that the optimal pretreatment for AP was to soak it in the ammonia liquor of 6% for 24 h at room temperature. An optimal fermentation condition for bio-H₂ production was proposed that the pretreated AP at 37 °C, the initial pH of 7.0 and the fermentation concentration of 15 g/l could produce a maximum cumulative H₂ yield (CHYm) of 101.08 ml/g total solid (TS) with an average H₂ production rate (AHPR) of 8.08 ml/g TS/h. During the conversion of AP into H₂, acetic acid, ethanol, propionic acid and butyric acid were main liquid end-products.     

Disruption of sugarcane bagasse lignocellulosic structure by means of dilute sulfuric acid pretreatment with microwave-assisted heating

Disruption of lignocellulosic structure of biomass plays a key role in producing bioethanol from lignocelluloses. This study investigated the impact of dilute sulfuric acid pretreatment on bagasse structure using microwave heating. Three reaction temperatures of 130, 160 and 190 °C with two heating times of 5 and 10 min were considered and a number of instruments were employed to analyze the properties of the bagasse particles. On account of microwave irradiation into the solution with dielectric heating, the experiments indicated that an increase in reaction temperature destroyed the lignocellulosic structure of bagasse in a significant way. The pretreated bagasse particles were simultaneously characterized by fragmentation and swelling. When the reaction temperature was as high as 190 °C, the fragmentation of particles became fairly pronounced so that the specific surface area of the pretreated material grew substantially. Meanwhile, almost all hemicellulose was removed from bagasse and the crystalline structure of cellulose disappeared. In contrast, the feature of lignin was remained clearly. However, a comparison between the heating times of 5 and 10 min revealed that the influence of the heating time on the lignocellulosic structure was not significant, indicating that the pretreatment with 5 min was sufficiently long.     

Dark fermentative biohydrogen production by mesophilic bacterial consortia isolated from riverbed sediments

Dark fermentative bacterial strains were isolated from riverbed sediments and investigated for hydrogen production. A series of batch experiments were conducted to study the effect of pH, substrate concentration and temperature on hydrogen production from a selected bacterial consortium, TERI BH05. Batch experiments for fermentative conversion of sucrose, starch, glucose, fructose, and xylose indicated that TERI BH05 effectively utilized all the five sugars to produce fermentative hydrogen. Glucose was the most preferred carbon source indicating highest hydrogen yields of 22.3 mmol/L. Acetic and butyric acid were the major soluble metabolites detected. Investigation on optimization of pH, temperature, and substrate concentration revealed that TERI BH05 produced maximum hydrogen at 37 °C, pH 6 with 8 g/L of glucose supplementation and maximum yield of hydrogen production observed was 2.0–2.3 mol H₂/mol glucose. Characterization of TERI BH05 revealed the presence of two different bacterial strains showing maximum homology to Clostridium butyricum and Clostridium bifermentans.     

Effect of temperature on anaerobic fermentative hydrogen gas production from feedlot cattle manure using mixed microflora

Hydrogen production from the anaerobic fermentation of feedlot cattle manure was examined in batch cultures over a temperature range from 36 to 60 °C at a pH of 5.2. The amount of hydrogen produced increased with temperature to a maximum of 65 L H₂ kg TS⁻¹ at 52 °C. At temperatures > 52 °C, acetate was the main volatile fatty acid (VFA) accumulated, while at <52 °C butyrate accumulated the most. Formate was detected in the 56 and 60 °C treatments but was absent in all others. Thermophilic conditions resulted in the highest hydrogen production rates, with maximum hydrogen production occurring 52 °C. Changing incubation temperature by small (4 °C) increments up or down from 52 °C resulted in changes in the metabolic flux (conversion of substrate to VFA and gaseous products) of the anaerobic digestion system. These findings indicate that the hydrogen production potential of anaerobic systems utilizing heat treated cattle manure as inoculum is affected greatly by incubation temperature.     

Performance of Pd on activated carbon as hydrogen electrode with respect to hydrogen yield in a single cell proton exchange membrane (PEM) water electrolyser

Palladium (Pd) on activated carbon is used as electrocatalyst coated on Nafion 115 membrane as Hydrogen electrode and RuO₂ is coated on other side of membrane used as oxygen electrode. 5 wt% and 10 wt% Pd on activated carbon is prepared as membrane electrode assembly (MEA) and investigated the performance of the same using inhouse prepared 10 cm² single cell. The performance of the single cell assembly and the hydrogen yield are reported during electrolysis operation at temperatures 27 °C, 45 °C and 65 °C at 0.1, 0.2, 0.3, 0.4, 0.5 A/cm² current densities with respect to voltages.     

Feasibility of biohydrogen production at low temperatures in unbuffered reactors

Feasibility of biohydrogen production by dark fermentation at two temperatures (22 °C and 37 °C) in unbuffered batch reactors was evaluated using heat-treated compost as inocula and sucrose as substrate, without any initial pH adjustment or inorganic nutrient supplements. Gas production was quantified by two different pressure release methods – intermittent pressure release (IPR) and continuous pressure release (CPR). Hydrogen production (47.2 mL/g COD/L) and sucrose-to-hydrogen conversion efficiency (53%) were both found to be highest at the lower temperature and IPR conditions. Hydrogen production was higher at the lower temperature irrespective of the pressure release condition. The high yield of 4.3 mol of hydrogen/mole of sucrose obtained in this study under IPR conditions at 22 °C is equivalent to or better than the literature values reported for buffered reactors. Even though literature reports have implied potential inhibition of hydrogen production at high hydrogen partial pressures resulting from IPR conditions, our results did not show any negative effects at hydrogen partial pressures exceeding 5.0 × 10⁴ Pa. While our findings are contrary to literature reports, they make a strong case for cost-effective hydrogen production by dark fermentation.     

Bioconversion of corncob to hydrogen using anaerobic mixed microflora

Biohydrogen production from corncob using natural anaerobic microflora was reported for the first time. The optimum pretreatment condition for the corncob was determined to be 100 °C, 30 min, and 1% HCl (w/w). The maximum hydrogen yield of 107.9 ml/g-TVS and hydrogen production rate of 4.20 ml/g-TVS h⁻¹ was obtained under the condition of 10 g/l substrate concentration and initial pH 8.0. Butyrate and acetate were the dominant metabolic by-products of hydrogen fermentation. Chemical composition analysis, Fourier transform infrared spectroscopy (FTIR) and X-ray diffraction (XRD) were used to study the mechanism of degrading corncob for hydrogen production. The amorphous domains of cellulose and hemicellulose were hydrolyzed into fermentable saccharides through acid pretreatment and the microorganisms had a devastating effect on the crystallinity of the cellulose. The hydrogen yield from pretreated corncob was much higher than from raw corncob. Therefore, the acid pretreatment played a crucial role on hydrogen production from corncob.     

Kinetic analysis of photosynthetic growth,hydrogen production and dual substrate utilization by Rhodobacter capsulatus

Rhodobacter capsulatus is purple non-sulfur (PNS) bacterium which can produce hydrogen and CO₂ by utilizing volatile organic acids in presence of light under anaerobic conditions. Photofermentation by PNS bacteria is strongly affected by temperature and light intensity. In the present study we present the kinetic analysis of growth, hydrogen production, and dual consumption of acetic acid and lactic acid at different temperatures (20, 30 and 38 °C) and light intensities (1500, 2000, 3000, 4000 and 5000 lux). The cell growth data fitted well to the logistic model and the cumulative hydrogen production data fitted well to the Modified Gompertz Model. The model parameters were affected by temperature and light intensity. Lactic acid was found to be consumed by first order kinetics. Rate of consumption of acetic acid was zero order until most of the lactic acid was consumed, and then it shifted to first order. The results revealed that the optimum light intensities for maximum hydrogen production were 5000 lux for 20 °C and 3000 lux for 30 °C and 38 °C.     

Effect of temperature on fermentative hydrogen production by mixed cultures

Effect of temperatures ranging from 20 °C to 55 °C on fermentative hydrogen production by mixed cultures was investigated in batch tests. The experimental results showed that, at initial pH 7.0, during the fermentative hydrogen production using glucose as substrate, the substrate degradation efficiency and hydrogen production potential increased with increasing temperatures from 20 °C to 40 °C. The maximal substrate degradation efficiency was 98.1%, the maximal hydrogen production potential was 269.9 mL, the maximal hydrogen yield was 275.1 mL/g glucose and the shortest lag time was 7.0 h. The temperature for fermentative hydrogen production by mixed cultures was optimized to be 40 °C. The expanded Ratkowsky models could be used to describe the effect of temperatures on the hydrogen production potential, maximum hydrogen production rate and the lag time during fermentative hydrogen production.     

Enriching hydrogen-producing bacteria from digested sludge by different pretreatment methods

The pretreatment of digested sludge by different methods, including ionizing irradiation, heat-shock, acid and base, was performed for enriching hydrogen-producing bacteria. These methods were evaluated and compared based on their suitability in the enrichment of hydrogen-producing bacteria in dark fermentation with glucose as a substrate in batch tests. The experimental results showed that the seed sludge pretreated by ionizing irradiation achieved the best hydrogen production among the different pretreatment methods, and the maximum hydrogen production potential, maximum hydrogen production rate, hydrogen yield and substrate degradation rate were 525.6 mL, 37.2 mL/h, 267.7 mL/g glucose (2.15 mol/mol glucose) and 98.9%, respectively. Ionizing irradiation can be a good optional pretreatment method for enriching hydrogen-producing bacteria from digested sludge. The effect of ionizing irradiation on the microbial community structure dynamics of the pretreated sludge deserves further study, which will help us to understand the mechanisms leading to the effect of high bio-hydrogen production.     

Influence of seed sludge and pretreatment method on hydrogen production in packed-bed anaerobic reactors

Several studies have reported on the effects of inoculums source and pretreatment on biological hydrogen production. However, there have been few studies on continuous reactors. This paper investigated the influence of different seed sludge sources and pretreatment methods on biohydrogen production in up-flow anaerobic fixed-bed reactors fed with sucrose. The following inoculum sources were included in the study: (1) anaerobic sludge from an up-flow anaerobic sludge blanket (UASB) reactor used to treat poultry slaughterhouse wastewater (Sl), (2) anaerobic sludge from a UASB reactor used to treat swine wastewater (Sw) and (3) autofermentation (A). Heat (He) and acid (Ac) shock were used to increase hydrogen production and suppress hydrogen consumption. The average hydrogen yields (HY) in the experiment were 2.1 (A), 2.0 (SlHe), 2.0 (SlAc), 1.0 (Sl), 1.0 (SwAc), 0.7 (SwHe) and 0.7 (Sw) mol H₂ mol⁻¹ sucrose. Although heat shock produced the maximum HY value (SlHe), acid pretreatment (SlAc) resulted in more stable hydrogen production with the largest average value, which could be an advantage of using pH shock. The autofermentation process presented HY values similar to those produced with SlAc and SlHe, making it a suitable seed sludge for biohydrogen production because pretreatment was not required.     

Syngas yield during pyrolysis and steam gasification of paper

Main characteristics of gaseous yield from steam gasification have been investigated experimentally. Results of steam gasification have been compared to that of pyrolysis. The temperature range investigated were 600–1000 °C in steps of 100 °C. Results have been obtained under pyrolysis conditions at same temperatures. For steam gasification runs, steam flow rate was kept constant at 8.0 g/min. Investigated characteristics were evolution of syngas flow rate with time, hydrogen flow rate and chemical composition of syngas, energy yield and apparent thermal efficiency. Residuals from both processes were quantified and compared as well. Material destruction, hydrogen yield and energy yield is better with gasification as compared to pyrolysis. This advantage of the gasification process is attributed mainly to char gasification process. Char gasification is found to be more sensitive to the reactor temperature than pyrolysis. Pyrolysis can start at low temperatures of 400 °C; however char gasification starts at 700 °C. A partial overlap between gasification and pyrolysis exists and is presented here. This partial overlap increases with increase in temperature. As an example, at reactor temperature 800 °C this overlap represents around 27% of the char gasification process and almost 95% at reactor temperature 1000 °C.     

High/low temperature operation of electric double layer capacitor utilizing acidic cellulose-chitin hybrid gel electrolyte

An acidic cellulose-chitin hybrid gel electrolyte consisting of cellulose, chitin, 1-butyl-3-methylimidazolium, 1-allyl-3-methylimidazolium bromide, and an aqueous H₂SO₄ solution is investigated for electric double layer capacitors (EDLCs) with activated carbon fiber cloth electrodes. The acidic cellulose-chitin hybrid gel electrolyte shows a high ionic conductivity comparable to that for an aqueous 2 mol dm⁻³ H₂SO₄ solution at 0-80 °C. This system's temperature dependence in EDLC performance is investigated by galvanostatic charge-discharge measurement. An EDLC cell with the acidic hybrid gel electrolyte has higher capacitance than that with the aqueous H₂SO₄ solution in the range of operation temperatures (−10 to 60 °C). Moreover, the capacitance retention of the EDLC cell with the acidic hybrid gel electrolyte is better than that of a cell with the H₂SO₄ solution at 60 °C over 10,000 cycles. This suggests that the proposed acidic gel electrolyte has excellent stability in the presence of a strong acid, even at a high temperature of 60 °C.     

Acidophilic biohydrogen production from rice slurry

Batch experiment results showed that hydrogen production from rice slurry was found most effective at pH 4.5, 37 °C treating a slurry containing 5.5 g-carbohydrate/L. An anaerobic digester sludge was used as seed after a 100 °C heat treatment for 30 min. After a 36 h acclimation period, the sludge had a maximum specific hydrogen production rate of 2.1 L/(g-VSS d) and a hydrogen yield of 346 mL/g-carbohydrate, corresponding to 62.6% of stoichiometric yield. The effluent was composed mostly of acetate (28.3–43.0%) and butyrate (51.4–70.9%). Based on the 16S rDNA analysis, the 28 clones developed from this acidophilic hydrogen-producing sludge may be classified into nine OTUs, all of which are affiliated with the genus Clostridium. Phylogenetic analysis shows that eight OTUs (96.4% of population) form a distinct group with Clostridium sp. 44a-T5zd. Results indicate the acidophilic hydrogen-producing bacteria found in this study are unknown, and warrant further studies.