Environmental Engineering Reference
In-Depth Information
[16]
Dickman M. and Artuz I. Mass mortality of photosynthetic bacteria as a mechanism for
dark lamina formation in sediments of the Black Sea. Nature 1978; 275:191-95.
[17]
Freeman K.H., Wakeham S.G. and Hayes J.M. Predictive isotopic biogeochemistry: hy-
drocarbons from anoxic marine basins. Org Geochem 1994; 21:629-44.
[18]
Fuhrmann S., Overmann J., Pfennig N. and Fischer U. Influence of vitamin B
12
and light
on the formation of chlorosomes in green- and brown-colored
Chlorobium
species. Arch
Microbiol 1993; 16:193-98.
[19]
Glaeser J. and Overmann J. Biogeography, evolution and diversity of the epibionts in
phototrophic consortia. Appl Environ Microbiol 2004; 70:4821-30.
[20]
Gorlenko V.M. “Ecological niches of green sulfur and gliding bacteria.” In:
Green pho-
tosynthetic bacteria.
Olson J.M., Ormerod J.G., Amesz J., Stackebrandt E., Truper H.G.
eds., New York, London: Plenum Press, 1988.
[21]
Grice K., Gibbison R., Atkinson J.E., Schwark L., Eckhardt C.B. and Maxwell J.R.
Maleimides (1
H
-pyrrole-2,5-diones) as molecular indicators of anoxygenic photosynthe-
sis in ancient water columns. Geochim Cosmochim Acta 1996; 60:3913-24.
[22]
Guerrero R., Montesinos E., Pedr os-Alio C., Esteve I., Mas J., Van Gemerden H., Hof-
man P.A.G. and Bakker J.F. Phototrophic sulfur bacteria in two Spanish lakes: Vertical
distribution and limiting factors. Limnol Oceanogr 1985; 30:919-31.
[23]
Guerrero R., Pedros-Ali o C., Esteve I. and Mas J. Communities of phototrophic bacteria
in lakes of the Spanish Mediterranean region. Acta Acad Aboensis 1987; 47:125-51.
[24]
Hartgers W.A., Sinninghe Damste J.S., Requejo A.G., Allan J., Hayes J.M. and de Leeuw
J.W. Evidence for only minor contributions from bacteria to sedimentary organic carbon.
Nature 1994; 369:224-27.
[25]
Hashwa F.A. and Truper H.G. Viable phototrophic sulfur bacteria from the Black-Sea
bottom. Helgolander wiss Meeresunters 1978; 31:249-53.
[26]
Hay B.I. Sediment accumulation in the central western Black Sea over the past 5100
years. Paleoceanogr 1988; 3:491-508.
[27]
Hay B.I. and Arthur M.A. Sediment deposition in the Holocene Black Sea. Deep-Sea Res
1991; 38 (suppl 2):1211-35.
[28]
Hay B.I., Honjo S. and Kempe S. Interannual variability in the particle flux in SW Black
Sea. Deep-Sea Res 1990; 37 (6A):911-28.
[29]
Jannasch H.W., Eimhjellen K., Wirsen C.O. and Farmanfamaian A. Microbial degradation
of organic matter in the deep sea. Science 1971; 171:672-75.
[30]
Jannasch H.W, Truper H.G., Tuttle J.H. “Microbial sulfur cycle in Black Sea.” In:
The
Black Sea - Geology, Chemistry, and Biology
, Degens E.T. and Ross D.A. eds., Tulsa,
Oklahoma: Am. Ass. Petroleum Geologists, 1974.
[31]
Jannasch H.W., Wirsen C.O., Taylor C.D. Undecompressed microbial populations from
the deep sea. Appl environ Microbiol 1976; 32:360-67.
[32]
Jørgensen B.B. and Fossing H. Black Sea Cruise, Knorr-88-2. Preliminary data report,
1990.
[33]
Jørgensen B.B., Fossing H., Wirsen C.O., Jannasch H.W. Sulfide oxidation in the Black
Sea chemocline. Deep-Sea Res 1991; 38 (Suppl):1083-1103.
[34]
Karl D.M. and Knauer G.A. Microbial production and particle flux in the upper 350 m of
the Black Sea. Deep-Sea Res 1991; 38 (Suppl):921-42.
