Patent Publication Number: US-4921800-A

Title: Microbial process for photohydrogen production from cellulose in high saline water medium

Description:
The following specification particularly describes and ascertains the nature of this invention and the manner in which it is to be performed. 
     Photogeneration of hydrogen by microbes is acquiring importance as a feasible route for energy generation. Among various attempts to photoproduce hydrogen using microbes, considerable attention has been paid to use of marine photosynthetic organisms. In what follows, we describe a novel method for photo-producing hydrogen using the marine photrophic bacterium, Rhodospirillum salinarum. 
     Recently, worldwide attention has been focused on the bioconversion of cellulosic residues into fuels food and energy. The major materials available for this purpose are from agricultural sources which are renewable. Therefore, development of a process for hydrogen production using solar energy, cellulosic materials and sea water is highly desirable. 
     Interest been focused on developing a process by which a marine thermophilic phototrophic bacterium Rhodospirillum salinarum ATCC 35394 (American Type Culture Collection, Rockville, Md.) which was isolated from Portugal by H. Nissen and D. Dundas is used for photohydrogen production with natural light and with organic acid and cellulose as substrates. Another advantage of using this strain is that it is thermophilic and can grow and produce H2 even at a temperature of 42 C. This strain was repeatedly subcultured on a medium described below with either DL-malic acid or cellulose as a carbon source until two pure strains were obtained: one which could grow on malate and also on cellulose. 
     The medium used was as described by Nissen and Dundas (Arch. Microbial., 130, 251-256, 1984) with one of the following carbon sources (1 g per liter of the medium): 
     (1) DL-malic acid 
     (2) microcrystalline cellulose. 
     Sea water connectrated to contain 10% sodium chloride was used for preparing the medium. 
     The media were sterilized by autoclaving and were sparged with ultra pure, sterile argon gas to remove traces of oxygen from the head space and medium and were inoculated with R. salinarum from the selected population maintained at 42 C. under diffused solar energy. The process runs were conducted with 1 l and 5 l glass and plastic vessels in a temperature range of 37-77 C. and illuminance of 15000 lux, provided by natural solar radiation. Samples of culture were periodically withdrawn from the process runs and were checked for growth on &#34;Spectronic-20&#34; spectrophotometer at a wavelength of 660 nm, using a predetermined calibration curve relating absorbance to dry weight of cells. The evolved gas was analyzed for gas composition on a gas chromatograph. 
    
    
     EXAMPLE 
     I give below data on photoproduction of hydrogen by R. salinarum utilizing DL-malic acid and cellulose as substrates. 
     
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Growth (dry wt. mg/l culture)                                             
                      hydrogen produced                                   
DL-malic                  (mg/g dry wt/day)                               
DAY   acid        Cellulose   DL-malic                                    
                                      Cellulose                           
______________________________________                                    
C      10                     --      --                                  
14     500         530        42      40                                  
22    1000        1050        26      20                                  
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     The data presented above is meant to provide an example of the outcome of the process, which is of batch mode, and in no way implies its limits. 
     Summarizing the results I state: 
     (i) the organism is able to use solar energy, organic materials and concentrated sea water to produce H 2 . 
     (ii) that the organism is able to produce H 2  even at temperatures as high as 42 C.