CAMBRIAN MATGROUND PALEOECOLOGY
225
G
ERDES, G., KLENKE, T., and NOFFKE, N., 2000, Microbial signatures
in peritidal siliciclastic sediments: a catalogue: Sedimentology, v.
47, p. 279–308.
infaunal ecology and evolution during the Proterozoic–Cambrian
transition: PALAIOS, v. 14, p. 58–72.
M
CMENAMIN, M.A.S., 1987, The emergence of animals: Scientific
G
LAESSNER, M.F., 1976, Early Phanerozoic annelid worms and their
geological and biological significance: Journal of the Geological So-
ciety, v. 132, p. 259–275.
American, v. 256, p. 94–102.
M
OORE, J.N., and FRITSCHE, A.E., 1976, Depositional environments
of lower Paleozoic rocks in the White–Inyo Mountains, Inyo Coun-
ty, California: Pacific Coast Paleogeography Field Guide 1: Pacific
Section, Society of Economic Paleontologists and Mineralogists,
Los Angeles, 69 p.
GON, S., III, 1999, A guide to the orders of trilobites, Ͻhttp://
¨
GRIESHABER, M.K., and VOLKEL, S., 1998, Animal adaptations for tol-
erance and exploitation of poisonous sulfide: Annual Reviews of
Physiology, v. 60, p. 33–53.
AGADORN, J.W., and BOTTJER, D.J., 1997, Wrinkle structures: mi-
crobially mediated sedimentary structures common in subtidal
siliciclastic settings at the Proterozoic–Phanerozoic transition:
Geology, v. 25, p. 1047–1050.
AGADORN, J.W., and BOTTJER, D.J., 1999, Restriction of a Late Neo-
proterozoic biotope: suspect-microbial structures and trace fossils
at the Vendian–Cambrian transition: PALAIOS, v. 14, p. 73–85.
AGADORN, J.W., and WAGGONER, B., 2002, The Early Cambrian
problematic fossil Volborthella: new insights from the Basin and
Range: in Corsetti, F.A., ed., Proterozoic–Cambrian of the Great
Basin and Beyond: SEPM Pacific Section Guidebook, Santa Fe
Springs, p. 137–153.
ERON-ALLEN, E., 1915, A short statement upon the theory, and the
phenomena of purpose and intelligence exhibited by Protozoa, as
illustrated by selection and behavior in the Foraminifera: Journal
of the Royal Microscopal Society, v. 1915, p. 547–557.
M
OORE, R.C., LALICKER, C.G., and FISCHER, A.G., 1952, Invertebrate
Fossils: McGraw-Hill, New York, p. 221–226.
H
M
ORSE, J.W., MILLERO, F.J., CORNWELL, J., and RICKARD, D., 1987,
The chemistry of the hydrogen sulfide and iron sulfide systems in
natural waters: Earth-Science Reviews, v. 24, p. 1–42.
OUNT, J.D, 1974, Biostratigraphy of the Lower Cambrian in south-
eastern California: Geological Society of America Abstracts with
Programs, v. 6, p. 224.
OUNT, J.F. and BERGK, K.J., 1998, Depositional sequence stratig-
raphy of Lower Cambrian grand cycles, southern Great Basin,
U.S.A.: International Geology Review, v. 40, p. 55–77.
OUNT, J.F., and SIGNOR, P.W., 1991, The Proterozoic–Cambrian
transition of the White–Inyo Range, eastern California: dawn of
the Metazoa: in Hall, C.A., Jr., Doyle-Jones, V., and Widawski, B.,
eds., Natural History of Eastern California and High-Altitude Re-
search, White Mountain Research Station Symposium, v. 3, p.
455–488.
M
M
M
H
H
H
N
N
N
N
N
EALSON, K., and BERELSON, W., 2003, Layered microbial communi-
ties and the search for life in the Universe: Geomicrobiology Jour-
nal, v. 20, p. 451–462.
H
ISCOTT, R.N., 1982, Tidal deposits of the Lower Cambrian Random
Formation, eastern Newfoundland: facies and palaeoenviron-
ments: Canadian Journal of Earth Sciences, v. 19, p. 2028–2042.
OFFMAN, P.F., KAUFMAN, A.J., HALVERSON, G.P., and SCHRAG, D.P.,
1998, A Neoproterozoic snowball Earth: Science, v. 281, p. 1342–
1346.
ELSON, C.A., 1962, Lower Cambrian–Precambrian succession,
H
White–Inyo Mountains, California: Geological Society of America
Bulletin, v. 73, p. 139–144.
ELSON, C.A., 1966, Geologic map of the Blanco Mountain Quadran-
gle, Inyo and Mono Counties, California: U.S. Geological Survey
Geologic Quadrangle Map GQ-529; 1: 62,500.
EUMANN, A.C., GEBLEIN, C.D., and SCOFFIN, T.P., 1970, The com-
position, structure and erodability of subtidal mats, Abaco, Baha-
mas: Journal of Sedimentary Research, v. 40, p. 274–297.
OFFKE, N., 1998, Multidirected ripple marks rising from biological
and sedimentological processes in modern lower supratidal depos-
its (Mellum Island, southern North Sea): Geology, v. 26, p. 879–
882.
OFFKE, N., 2000, Extensive microbial mats and their influences on
the erosional and depositional dynamics of a siliciclastic cold wa-
ter environment (Lower Arenigian, Montagne Noire, France):
Sedimentary Geology, v. 136, p. 207–215.
OFFKE, N., GERDES, and KLENKE, T.H., 2003a, Benthic cyanobacte-
ria and their influence on the sedimentary dynamics of peritidal
depositional systems (siliciclastic, evaporitic salty, and evaporitic
carbonatic): Earth Science Reviews, v. 62, p. 163–176.
OFFKE, N., GERDES, G., KLENKE, T.H., and KRUMBEIN, W.E., 2001a,
Microbially induced sedimentary structures—a new category
within the classification of primary sedimentary structures: Jour-
nal of Sedimentary Research, v. 71, p. 649–656.
OFFKE, N., GERDES, G., KLENKE, T.H., and KRUMBEIN, W.E., 2001b,
Microbially induced sedimentary structures indicating climato-
logical, hydrological and depositional conditions within Recent
and Pleistocene coastal facies zones (southern Tunisia): Facies, v.
44, p. 23–30.
OFFKE, N., HAZEN, R., and NHELKO, N., 2003b, Earth’s earliest mi-
crobial mats in a siliciclastic marine environment (2.9 Ga Mozaan
Group, South Africa): Geology, v. 31, p. 673–676.
OFFKE, N., KNOLL, A.H., and GROTZINGER, J.P., 2002, Sedimentary
controls on the formation and preservation of microbial mats in
siliciclastic deposits: a case study from the Upper Neoproterozoic
Nama Group, Namibia: PALAIOS, v. 17, p. 533–544.
ESCHGER, R., and VETTER, R.D., 1992, Sulfide detoxification and tol-
erance in Halicryptus spinulosus (Priapulida): a multiple strategy:
Marine Ecology Progress Series, v. 86, p. 167–179.
J
ENSEN, S., SAYLOR, B.Z., GEHLING, J.G., and GERMS, G.J.B., 2000,
Complex trace fossils from the terminal Proterozoic of Namibia:
Geology, v. 28, p. 143–146.
JøRGENSEN, B.B., and GALLARDO, V.A., 1999, Thioploca spp.: filamen-
tous sulfur bacteria with nitrate vacuoles: MiniReview in FEMS
Microbiology Ecology, v. 28, p. 301–313.
JøRGENSEN, B.B., NELSON, D.C., and WARD, D.M., 1992, Grazing and
bioturbation in modern microbial mats: in Schopf, J.W., and Klen,
C., eds., The Proterozoic Biosphere: A MultidisciplinaryApproach:
Cambridge University Press, Cambridge, p. 295–297.
JøRGENSEN, B.B., and REVSBECH, N.P., 1985, Diffusive boundary lay-
ers and the oxygen uptake of sediments and detritus: Limnology
and Oceanography, v. 30, p. 111–122.
N
N
N
N
K
IRSCHVINK, J.L., and HAGADORN, J.W., 2000, A grand unified theory
of biomineralization: in Ba¨uerlein, E., ed., The Biomineralization
of Nano- and Micro-Structures: Wiley-VCH, Weinheim, p. 139–
150.
K
NOLL, A.H., 1996, Breathing room for early animals: Nature, v. 382,
p. 111–112.
K
OPASKA-MERKEL, D.C., and GRANNIS, J., 1990, Detailed structure of
wrinkle-marks: Alabama Academy of Science Journal, v. 61, p.
236–243.
LI, R.H., CARMICHAEL, W.W., BRITTAIN, S., EAGLESHAM, G.K., SHAW,
G.R., LIU, Y.D. and WATANABE, M.W., 2001, First report of the cy-
anotoxins cylindrospermopsin and deoxycylindrospermopsinfrom
Raphidiopsis curvata (Cynaobacteria): Journal of Phycology, v. 37,
p. 1–6.
N
L
OWENSTAM, H.A., 1981, Minerals formed by organisms: Science, v.
211, p. 1126–1131.
L
OWENSTAM, H.A., and MARGULIS, L., 1980, Evolutionary prerequi-
sites for early Phanerozoic calcareous skeletons: Biosystems, v. 1,
p. 27–41.
N
M
ANWELL, C., 1960, Histological specificity of respiratory pigments—
II. Oxygen transfer systems involving hemerythrins in sipunculid
worms of different ecologies: Comparative Biochemistry and
Physiology, v. 1, p. 277–285.
O
O
O
M
ARTINSSON, A., 1965, Aspects of a Middle Cambrian thanatotope on
ESCHGER, R., and VISMANN, B., 1994, Sulfide tolerance in Hetero-
mastus filiformis (Polychaeta): mitochondrial adaptations: Ophe-
lia, v. 40, p. 147–158.
¨
Oland: Geologiska Fo¨reningens i Stockholm Fo¨rhandlingar, v. 87,
p. 181–230.
M
CI
LROY, D., and LOGAN, G.A., 1999, The impact of bioturbation on
RR, P.J., 2003, Ecospace utilization in early Phanerozoic deep-ma-