Sage Journals: Discover world-class research

Abstract

Microbialites can have complex morphologies that preserve clues to ancient microbial ecology. However, extracting and interpreting these clues is challenging due to both the complexity of microbial structures and the difficulties of connecting morphology to microbial processes. Fenestrate microbialites from the 2521±3 Ma Gamohaan Formation, South Africa, have intricate structures composed of three distinct microbial structures: steeply dipping supports (surfaces defined by organic inclusions), more shallowly dipping supports with diffuse organic inclusions below them, and draping laminae. In polished slabs, shallowly dipping supports with diffuse organic inclusions show apparent dips from 27° to 60°, and supports without associated zones of diffuse inclusions dip 75° to 88°, which suggests a distinction between support types based on orientation. However, dips exposed in polished slabs are apparent dips, and three-dimensional analysis is required for analysis of true dips. Through the Keck Center for Active Visualization in Earth Sciences (KeckCAVES), we used locally developed software that controls a three-dimensional environment with head and hand tracking (an “immersive environment”) to visualize and interpret virtual microbialite data sets. Immersive environments have not penetrated into standard scientific work processes (“workflows”) due to their high costs, steep learning curves, and low productivity for users. By contrast, our suite of software tools allowed us to develop a personalized scientific workflow that provides a complete path from initial ideas to characterization of fenestrate microbialites' features. Results of three-dimensional analysis of fenestrate microbialites show that supports with inclusions dip 65° to 75°, whereas supports without inclusions dip 85° to 90°. These results demonstrate that all supports have very steep dips, and a 10° dip gap exists between supports with and without inclusions, which suggests they grew in fundamentally different ways. Results also emphasize how valuable three-dimensional analysis is when combined with a comprehensive workflow for understanding intricate structures such as fenestrate microbialites. Key Words: Immersive visualization—Geoscience—CAVES—Workflow—Microbialites. Astrobiology 11, 509–518.

Get full access to this article

View all access options for this article.

References

Allwood

A.C.

, Walter

M.R.

, Kamber

B.S.

, Marshall

C.P.

, Burch

I.W.

2006. Stromatolite reef from the Early Archaean era of Australia. Nature, 441:714–718.

Batchelor

, Burne

, Henry

, Watt

2003. Mathematical and image analysis of stromatolite morphogenesis. Math Geol, 35:789–803.

Billen

M.I.

, Kreylos

, Hamann

, Jadamec

M.A.

, Kellogg

L.H.

, Staadt

, Sumner

D.Y.

2008. A geoscience perspective on immersive 3D gridded data visualization. Comput Geosci, 34:1056–1072.

Buick

, Dunlop

J.S.R.

, Groves

D.I.

1981. Stromatolite recognition in ancient rocks: an appraisal of irregularly laminated structures in an Early Archaean chert-barite unit from North Pole, Western Australia. Alcheringa: An Australasian Journal of Palaeontology, 5:161–181.

Buick

, Groves

D.I.

, Dunlop

J.S.R.

, Lowe

D.R.

1995. Abiological origin of described stromatolites older than 3.2 Ga: comment and reply. Geology, 23:191–192.

Burne

R.V.

, Moore

L.S.

1987. Microbialites: organosedimentary deposits of benthic microbial communities. Palaios, 2:241–254.

Clarke

J.A.

, Tambussi

C.P.

, Noriega

J.I.

, Erickson

G.M.

, Ketcham

R.A.

2005. Definitive fossil evidence for the extant avian radiation in the Cretaceous. Nature, 433:305–308.

Cruz-Neira

, Sandin

D.J.

, DeFanti

T.A.

, Kenyon

R.V.

, Hart

J.C.

1992. The CAVE: audio visual experience automatic virtual environment. Commun ACM, 35:64–72.

GeoWall. 2011. The Geowall Consortium. http://www.geowall.org.

10.

Gery

G.J.

1991. Electronic Performance Support Systems: How and Why to Remake the Workplace through the Strategic Application of Technology. Weingarten Publications Inc.: Boston, 1–302.

11.

Glaessner

M.F.

, Preiss

W.V.

, Walter

M.R.

1969. Precambrian columnar stromatolites in Australia: morphological and stratigraphic analysis. Science, 164:1056–1058.

12.

Grotzinger

J.P.

, Knoll

A.H.

1999. Stromatolites in Precambrian carbonates: evolutionary mileposts or environmental dipsticks? Annu Rev Earth Planet Sci, 27:313–358.

13.

Grotzinger

J.P.

, Rothman

D.H.

1996. An abiotic model for stromatolite morphogenesis. Nature, 383:423–425.

14.

Grotzinger

J.P.

, Watters

W.A.

, Knoll

A.H.

2000. Calcified metazoans in thrombolite-stromatolite reefs of the terminal Proterozoic Nama Group, Namibia. Paleobiology, 26:334–359.

15.

Hofmann

H.J.

1973. Stromatolites: characteristics and utility. Earth-Science Reviews, 9:339–373.

16.

Hofmann

H.J.

1976. Graphic representation of fossil stromatoids: new method with improved precision. Stromatolites, Developments in Sedimentology, 20

Walter

M.R.

Elsevier Scientific Publishing Company: Amsterdam, 15–20.

17.

Hofmann

H.J.

, Grey

, Hickman

A.H.

, Thorpe

R.I.

1999. Origin of 3.45 Ga coniform stromatolites in Warrawoona Group, Western Australia. Geol Soc Am Bull, 111:1256–1262.

18.

Horodyski

R.J.

1976. Stromatolites from the Middle Proterozoic Altyn Limestone, Belt Supergroup, Glacier National Park, Montana. Stromatolites, Developments in Sedimentology, 20

Walter

M.R.

Elsevier Scientific Publishing Company: Amsterdam, 585–597.

19.

Howell

, Woo

, Chough

S.K.

2011. Dendroid morphology and growth patterns: 3-D computed tomographic reconstruction. Palaeogeogr Palaeoclimatol Palaeoecol, 299:335–347.

20.

Jacobs

A.M.

, Kilb

, Kent

2008. 3-D interdisciplinary visualization: tools for scientific analysis and communication. Seismological Research Letters, 79:867–876.

21.

KeckCAVES. 2011. W.M. Keck Center for Active Visualization in the Earth Sciences. UC Davis: Davis, CA http://keckcaves.org.

22.

Kreylos

2008. Environment-independent VR development. Advances in Visual Computing. Bebis

Spring-Verlag: Berlin, 901–912.

23.

Lowe

D.R.

1994. Abiological origin of described stromatolites older than 3.2 Ga. Geology, 22:387–390.

24.

Lowe

D.R.

1995. Abiological origin of described stromatolites older than 3.2 Ga: reply. Geology, 23:191–192.

25.

Maloof

A.C.

, Rose

C.V.

, Beach

, Samuels

B.M.

, Calmet

C.C.

, Erwin

D.H.

, Poirier

G.R.

, Yao

, Simons

F.J.

2010. Possible animal-body fossils in pre-Marinoan limestones from South Australia. Nat Geosci, 3:653–659.

26.

McConnell

R.L.

1975. Biostratigraphy and depositional environment of algal stromatolites from the Mescal Limestone (Proterozoic) of central Arizona. Precambrian Res, 2:317–328.

27.

McLoughlin

, Wilson

L.A.

, Brasier

M.D.

2008. Growth of synthetic stromatolites and wrinkle structures in the absence of microbes—implications for the early fossil record. Geobiology, 6:95–105.

28.

Preiss

W.V.

1976. Basic field and laboratory methods for the study of stromatolites. Stromatolites, Developments in Sedimentology, 20

Walter

M.R.

Elsevier Scientific Publishing Company: Amsterdam, 5–13.

29.

Richardson

, Stafford-Fraser

, Wood

K.R.

, Hopper

1998. Virtual network computing. IEEE Internet Computing, 2:33–38.

30.

Sumner

D.Y.

1997a. Carbonate precipitation and oxygen stratification in late Archean seawater as deduced from facies and stratigraphy of the Gamohaan and Frisco formations, Transvaal Supergroup, South Africa. Am J Sci, 297:455–487.

31.

Sumner

D.Y.

1997b. Late Archean calcite-microbe interactions: two morphologically distinct microbial communities that affected calcite nucleation differently. Palaios, 12:302–318.

32.

Sumner

D.Y.

2001. Microbial influences on local carbon isotopic ratios and their preservation in carbonate. Astrobiology, 1:57–70.

33.

Sumner

D.Y.

, Bowring

S.A.

1996. U-Pb geochronologic constraints on deposition of the Campbellrand Subgroup, Transvaal Supergroup, South Africa. Precambrian Res, 79:25–35.

34.

Sumner

D.Y.

, Grotzinger

J.P.

1996. Herringbone calcite; petrography and environmental significance. Journal of Sedimentary Research, 66:419–429.

35.

Walter

M.R.

1972. Stromatolites and the biostratigraphy of the Australian Precambrian and Cambrian. Special Paper 11. Palaeontological Association of London: London.

36.

Walter

M.R.

, Bauld

, Brock

T.D.

1976. Microbiology and morphogenesis of columnar stromatolites (Conophyton, Vacerrilla) from hot springs in Yellowstone National Park. Stromatolites, Developments in Sedimentology, 20

Walter

M.R.

Elsevier Scientific Publishing Company: Amsterdam, 273–310.

37.

Watters

W.A.

, Grotzinger

J.P.

2001. Digital reconstruction of calcified early metazoans, terminal Proterozoic Nama Group, Namibia. Paleobiology, 27:159–171.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

65.07 MB

Understanding Microbialite Morphology Using a Comprehensive Suite of Three-Dimensional Analysis Tools

Abstract

Get full access to this article

References

Supplementary Material