TARGETED ILLUMINATION STRATEGIES FOR HYDROGEN PRODUCTION FROM PURPLE NON-SULFUR BACTERIA

Craven, John D.

01 January 2019

The movement towards a more sustainable energy economy may require not only the generation of cleaner fuel sources, but the conversion of waste streams into value-added products. Phototrophic purple non-sulfur bacteria are capable of metabolizing VFAs (volatile fatty acids)and generate hydrogen as a byproduct of nitrogen fixation using energy absorbed from light. VFAs are easily produced from dark anaerobic fermentation of food, agricultural, and municipal wastes, which could then be fed into photobioreactors of purple bacteria for hydrogen production. The process of photofermentation by purple bacteria for hydrogen production remains attractive due to the capability of reaching high substrate conversions under mild operating conditions, but increasing the efficiency of converting light energy into hydrogen remains challenging. Purple bacteria cannot utilize the entire solar spectrum, and the dominant region of absorption lies in the near-infrared region above 800 nm. In this work, the model purple non-sulfur bacteria Rhodopseudomonas palustris was used to study different strategies to increase light utilization and hydrogen production. Near-infrared LED arrays were selected to match the target bacteriochlorophyll absorption range, and were tested to be used as a sole illumination source for photofermentation. Additionally, plasmonic nanoparticles with resonant frequencies matching bacterial absorbance were added in solution to increase light utilization through scattering and near field electric enhancement effects at intensities around 100 W/m2 . Both of these approaches proved to increase cellular growth rate and hydrogen production, which opens the door to utilizing more advanced photonic structures for use in bacterial phototrophic processes.

photofermentation

purple non-sulfur bacteria

hydrogen

near-infrared

plasmonic nanoparticles

Chemical Engineering

Biological Hydrogen Production By Using Co-cultures Of Pns Bacteria

Baysal, Gorkem

01 October 2012

Biological hydrogen production is a renewable, carbon-neutral and clean route for hydrogen production. Purple non-sulfur (PNS) bacteria have the ability to produce biohydrogen via photofermentation process. The type of the bacterial strain used in photofermentation is known to have an important effect on hydrogen yield. In this study, the effect of different co-cultures of PNS bacteria on photofermentation process was investigated in search of improving the hydrogen yield. For this purpose, growth, hydrogen production and substrate utilization of single and co-cultures of different PNS bacteria (R. capsulatus (DSM 1710), R. capsulatus hup- v (YO3), R. palustris (DSM 127) and R. sphaeroides O.U.001 (DSM 5864)) were compared on artificial H2 production medium in 150 mL photobioreactors under continuous illumination and anaerobic conditions. In general, higher hydrogen yields were obtained via co-cultivation of two different PNS bacteria when compared with single cultures. Further increase in hydrogen yield was observed with co-cultivation of three different PNS bacteria. Co-cultures of two different PNS bacteria have resulted in up to 1.4 and 2.1 fold increase in hydrogen yield and hydrogen productivity. Whereas co-cultures of three different PNS bacteria have resulted in up to 1.6 and 2.0 fold increase in hydrogen yield and hydrogen productivity compared to single cultures. These results indicate that, defined co-cultures of PNS bacteria produce hydrogen at a higher yield and productivity, due most probably to some synergistic relationship. Further studies regarding the physiological and molecular changes need to be carried out for deeper understanding of the mechanism of hydrogen production in co-cultures.

QR Bacteria 75-99.5

Obtenção e caracterização filogenética de consórcio de bactérias púrpuras não-sulforosas consumidoras de ácidos orgânicos visando a produção de hidrogênio em reator anaeróbio de batelada / Obtaintion and phylogenetic characterization of consortium of phototrophic purple non-sulfur bacteria for hydrogen production from organic acids in the anaerobic batch reactor

Lazaro, Carolina Zampol

17 April 2009

O objetivo deste trabalho foi enriquecer consórcio microbiano a partir de mistura de lodo granular de digestor anaeróbio de fluxo ascendente sob condições fototróficas anoxigênicas. Por meio de técnica de biologia molecular foi possível identificar 17 unidades taxonômicas operacionais (UTO) no consórcio microbiano, dentre as quais seqüências similares a Rhodobacter, gênero amplamente citado nos estudos de produção de gás hidrogênio por bactérias fototróficas. Exames microscópicos do consórcio fototrófico indicaram predomínio de bacilos Gram-negativos. Ensaios sob condições fototróficas foram realizados com dois meios de cultivo (RCVB e FANG) e os seguintes substratos orgânicos: ácido acético, butírico, cítrico, lático e málico, empregados como fonte de carbono, tanto para o crescimento celular, como para a produção do gás hidrogênio. A relação C/N inicial foi 30/4 e posteriormente 15/2, com o objetivo de favorecer o crescimento celular e a produção do \'H IND.2\'. A concentração dos substratos foi determinada de forma com que essa relação se mantivesse a mesma. O crescimento celular e consumo dos ácidos orgânicos foram similares para os dois meios de cultivo empregados. Entretanto, a produção do gás hidrogênio foi maior nos ensaios com o meio FANG. Dentre os substratos utilizados o consumo dos ácidos cítrico e málico foram os maiores (~100%), para concentrações iniciais de 3,3 g/L e 2,6 g/L, respectivamente. O menor consumo 25% foi observado em meio RCVB e ácido acético (2,5 g/L). O crescimento da biomassa variou de 0,06 g/L a 1,1 g/L, enquanto que a velocidade máxima específica de crescimento variou de 0,4 a 0,2 g SSV/L.d entre os substratos utilizados. A menor e maior concentração de hidrogênio foram de 8,5 e 22 mmol \'H IND.2\'/L, para os reatores alimentados com ácido lático e málico em meio FANG, respectivamente. Pôde-se concluir que o consórcio fototrófico enriquecido foi capaz de utilizar os ácidos orgânicos para produção do gás hidrogênio. / The aim of this work was enrich a mixture of granular sludge of an up flow anaerobic sludge blanket (UASB) under anoxygenic phototrophic conditions. The techniques of molecular biology identified 17 operational taxonomic units (UTO) in the microbial consortium among the sequences analised, which were similar to Rhodobacter, genus widely cited in studies of hydrogen gas production by phototrophic bacteria. Microscopic examinations of the phototrophic consortium showed predominance of Gram-negative bacilli. Tests were conducted under phototrophic conditions with two culture media (RCVB and FANG) and the following organic substrates: acetic, butyric, citric, lactic and malic acids that were used as carbon source for both cell growth and for the hydrogen gas production. The carbon nitrogen ratio (C/N) in the preliminaries tests was 30/4 and then it was changed to15/2 in order to improve the cell growth and hydrogen production. The concentration of substrates was determined for remain the same carbon/nitrogen ratio among the substrates. The cell growth and consumption of organic acids were similar for the two culture media used. However, the production of hydrogen gas was higher in trials with the medium FANG. Among the substrates used, the consumption of malic and citric acids were the highest (~100%) for initial concentrations of 3.3 g/L and 2.6 g/L, respectively. The shortest consumption (25%) was observed for the cells that grew on acetic acid, 2.5 g/L in RCVB culture medium. The growth of the biomass varied from 0.06 g/L to 1.1 g/L, whereas the maximum specific growth rate ranged from 0.4 to 0.2 g VSS/L.d between the substrates used. The lowest and highest concentrations of hydrogen were 8.5 and 22 mmol \'H IND.2\'/L for the reactor fed with lactic acid and malic acid in FANG\'s medium, respectively. It was concluded that the phototrophic consortium was able to use those organic acids for the production of hydrogen gas.

16S rRNA gene sequencing

Ácidos orgânicos

Filogenia

Gás hidrogênio

Hydrogen gas

Organic acids

Phototrophic purple non-sulfur bacteria

Phylogeny

Sequenciamento do gene RNAr 16S

Obtenção e caracterização filogenética de consórcio de bactérias púrpuras não-sulforosas consumidoras de ácidos orgânicos visando a produção de hidrogênio em reator anaeróbio de batelada / Obtaintion and phylogenetic characterization of consortium of phototrophic purple non-sulfur bacteria for hydrogen production from organic acids in the anaerobic batch reactor

Carolina Zampol Lazaro

17 April 2009

O objetivo deste trabalho foi enriquecer consórcio microbiano a partir de mistura de lodo granular de digestor anaeróbio de fluxo ascendente sob condições fototróficas anoxigênicas. Por meio de técnica de biologia molecular foi possível identificar 17 unidades taxonômicas operacionais (UTO) no consórcio microbiano, dentre as quais seqüências similares a Rhodobacter, gênero amplamente citado nos estudos de produção de gás hidrogênio por bactérias fototróficas. Exames microscópicos do consórcio fototrófico indicaram predomínio de bacilos Gram-negativos. Ensaios sob condições fototróficas foram realizados com dois meios de cultivo (RCVB e FANG) e os seguintes substratos orgânicos: ácido acético, butírico, cítrico, lático e málico, empregados como fonte de carbono, tanto para o crescimento celular, como para a produção do gás hidrogênio. A relação C/N inicial foi 30/4 e posteriormente 15/2, com o objetivo de favorecer o crescimento celular e a produção do \'H IND.2\'. A concentração dos substratos foi determinada de forma com que essa relação se mantivesse a mesma. O crescimento celular e consumo dos ácidos orgânicos foram similares para os dois meios de cultivo empregados. Entretanto, a produção do gás hidrogênio foi maior nos ensaios com o meio FANG. Dentre os substratos utilizados o consumo dos ácidos cítrico e málico foram os maiores (~100%), para concentrações iniciais de 3,3 g/L e 2,6 g/L, respectivamente. O menor consumo 25% foi observado em meio RCVB e ácido acético (2,5 g/L). O crescimento da biomassa variou de 0,06 g/L a 1,1 g/L, enquanto que a velocidade máxima específica de crescimento variou de 0,4 a 0,2 g SSV/L.d entre os substratos utilizados. A menor e maior concentração de hidrogênio foram de 8,5 e 22 mmol \'H IND.2\'/L, para os reatores alimentados com ácido lático e málico em meio FANG, respectivamente. Pôde-se concluir que o consórcio fototrófico enriquecido foi capaz de utilizar os ácidos orgânicos para produção do gás hidrogênio. / The aim of this work was enrich a mixture of granular sludge of an up flow anaerobic sludge blanket (UASB) under anoxygenic phototrophic conditions. The techniques of molecular biology identified 17 operational taxonomic units (UTO) in the microbial consortium among the sequences analised, which were similar to Rhodobacter, genus widely cited in studies of hydrogen gas production by phototrophic bacteria. Microscopic examinations of the phototrophic consortium showed predominance of Gram-negative bacilli. Tests were conducted under phototrophic conditions with two culture media (RCVB and FANG) and the following organic substrates: acetic, butyric, citric, lactic and malic acids that were used as carbon source for both cell growth and for the hydrogen gas production. The carbon nitrogen ratio (C/N) in the preliminaries tests was 30/4 and then it was changed to15/2 in order to improve the cell growth and hydrogen production. The concentration of substrates was determined for remain the same carbon/nitrogen ratio among the substrates. The cell growth and consumption of organic acids were similar for the two culture media used. However, the production of hydrogen gas was higher in trials with the medium FANG. Among the substrates used, the consumption of malic and citric acids were the highest (~100%) for initial concentrations of 3.3 g/L and 2.6 g/L, respectively. The shortest consumption (25%) was observed for the cells that grew on acetic acid, 2.5 g/L in RCVB culture medium. The growth of the biomass varied from 0.06 g/L to 1.1 g/L, whereas the maximum specific growth rate ranged from 0.4 to 0.2 g VSS/L.d between the substrates used. The lowest and highest concentrations of hydrogen were 8.5 and 22 mmol \'H IND.2\'/L for the reactor fed with lactic acid and malic acid in FANG\'s medium, respectively. It was concluded that the phototrophic consortium was able to use those organic acids for the production of hydrogen gas.

Ácidos orgânicos

Filogenia

Gás hidrogênio

Sequenciamento do gene RNAr 16S

16S rRNA gene sequencing

Hydrogen gas

Organic acids

Phototrophic purple non-sulfur bacteria

Phylogeny

Optimization production conditions of photosynthetic purple bacteria biomass at pilot scale to remove sulphide from aquaculture pond

Do, Thi Lien, Do, Thi To Uyen, Le, Thi Nhi Cong, Hoang, Phuong Ha, Cung, Thi Ngoc Mai

16 January 2019

For the purpose of sulphide removal in aquaculture ponds, three strains (name: TH21, QN71, QN51) were isolated and selected with the highest sulphide removal activity from Thanh Hoa and Quang Ninh coastal zones. These strains have identified and tested in a number of aquaculture ponds in different areas with good water quality results. With the objective of purple non sulfur bacteria biomass production containing 3 selected strains for wide application and suitable price for farmers, in this study, we study on optimum conditions of mixed purple non sulfur bacteria biomass production at pilot scale. The results showed that the sources of substrates were soybean meal (1g/l) and acetate (0.5g/l). These substrates are low cost, easy to find, convenient in large culture. The mixture of photosynthetic bacteria can be cultured in glass tanks, under micro aerobic and natural lighting conditions that produce highly concentrated photosynthetic bacteria and lowest rest media. / Nhằm mục tiêu xử lý sulphide trong môi trường nuôi trồng thủy sản, chúng tôi đã phân lập và lựa chọn được ba chủng vi khuẩn tía quang hợp có khả năng loại bỏ sulphide cao nhất ký hiệu TH21, QN71, QN52 từ các vùng ven biển Thanh Hóa và Quảng Ninh. Các chủng này đã được định loại và thử nghiệm tại một số ao nuôi thủy sản ở các vùng khác nhau thu được kết quả tốt về chất lượng nước. Để tạo chế phẩm vi khuẩn tía quang hợp từ 3 chủng lựa chọn được ứng dụng rộng rãi và có giá thành phù hợp cho nông hộ, trong nghiên cứu này, chúng tôi nghiên cứu tối ưu hóa các điều kiện sản xuất sinh khối hỗn hợp 3 chủng vi khuẩn tía quang hợp ở quy mô pilot. Kết quả cho thấy đã tìm kiếm được nguồn cơ chất là bột đậu tương (1g/l) và acetate (0.5g/l) là những chất có giá thành thấp, dễ tìm kiếm, thuận tiện trong nhân nuôi ở quy mô lớn. Hỗn hợp vi khuẩn tía quang hợp có thể nuôi trong các bể kính, ở điều kiện vi hiếu khí, có ánh sáng chiếu tự nhiên có thể sản xuất được chế phẩm vi khuẩn tía quang hợp có mật độ cao, cơ chất còn lại sau sản xuất là ít nhất.

info:eu-repo/classification/ddc/363.7

ddc:363.7

Metabolic Engineering to Improve Biohydrogen Production by Rhodobacter capsulatus JP91

Sherteel, Rajaa

04 1900

No description available.

Production de bio hydrogène

Génie métabolique

Bactérie violette sans soufre

R. capsulatus JP91

R. capsulatus RS15

Photofermentation

Polyhydroxy butyrate

PHB synthase

Biohydrogen production

Metabolic engineering

Purple none sulfur bacteria