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Role of Chitin in Montmorillonite Fabric: Transmission Electron Microscope Observations

Published online by Cambridge University Press:  01 January 2024

Jinwook Kim*
Affiliation:
Department of Earth System Sciences, Yonsei University, Seoul, Korea
Yoko Furukawa
Affiliation:
Naval Research Laboratory, Seafloor Sciences Branch, Stennis Space Center, MS 39529, USA
Kenneth J. Curry
Affiliation:
Department of Biological Sciences, University of Southern Mississippi, Hattiesburg, MS 39406, USA
Richard H. Bennett
Affiliation:
SEAPROBE, Inc., Picayune, MS 39466, USA
*
*E-mail address of corresponding author: [email protected]
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Abstract

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Particle concentration, charge, solution chemistry (i.e. ionic strength), and the nature of organic matter (OM) are the major factors controlling particle flocculation in aqueous environments. In the present study, the nature of clay fabric associated with clay—OM interaction at a range of ionic strengths was the focus. In the flocculation experiments, the aqueous suspension of montmorillonite and chitin was mixed with NaCl/MgSO4 electrolyte solution. Advanced sample-preparation techniques and visualization methods using transmission electron microscopy were used to observe directly the micro- and nano-scale clay—OM fabric of the resulting flocs. Such direct observation elucidated the role of OM in clay flocculation; few attempts have been made in the past due to the technical difficulties in preserving the original structure. A comparison of clay fabric at two different ionic strengths of 0 and 0.14 M revealed that the individual hexagonal clay particles settled slowly with little intra-aggregate void space (void ratio: 0.07) at 0 M while rapid flocculation and settling of clay particles at 0.14 M, with or without OM, resulted in a more open fabric with greater void space (void ratio: 0.33). The silver-staining technique demonstrated effectively the location of electron-transparent chitin in montmorillonite aggregates. Chitin appeared to link the face-to-face (FF) contacts of clay domains by bridging between negatively charged face surfaces. However, the resultant void ratio and the average hydrodynamic diameter (dH) values were lower than in the OM-free system after flocculation. The results indicated that the interplay between ionic strength and OM content affected the floc architecture and void ratio.

Type
Article
Copyright
Copyright © Clay Minerals Society 2012

References

Aylmore, L.A.G. and Quirk, J.P., 1960 Domain or turbostratic structure of clay Nature 187 10461048.CrossRefGoogle Scholar
Batchelor, G.K., 1967 An Introduction to Fluid Dynamics Cambridge, UK Cambridge University Press.Google Scholar
Bennett, R.H. Bryant, W.R. and Keller, G.H., 1977 Clay fabric and geotechnical properties of selected submarine sediment cores from the Mississippi Delta U.S. Department of Commerce-NOAA-ERL Publication, NOAA Professional Paper 9 86.Google Scholar
Bennett, R.H. Bryant, W.R. and Keller, G.H., 1981 Clay fabric of selected submarine sediments: Fundamental properties and models Journal of Sedimentary Petrology 51 217232.Google Scholar
Bennett, R.H. and Hulbert, M.H., 1986 Clay Microstructure. International Human Resources Development Corporation, Boston, USA 161.CrossRefGoogle Scholar
Bennett, R.H. Fischer, K.M. Lavoie, D. Bryant, W.R. and Rezak, R., 1989 Porometry and fabric of marine clay and carbonate sediments: determinants of permeability Marine Geology 89 127152.CrossRefGoogle Scholar
Bennett, R.H. Hulbert, M.H. Meyer, M.M. Lavoie, D.M. Briggs, K.B. Lavoie, D.L. Baerwald, R.J. and Chiou, W.A., 1996 Fundamental response of pore water pressure to microfabric and permeability characteristics: Eckernforde Bay Geo-Marine Letters (special issue) 16 182188.CrossRefGoogle Scholar
Bennett, R.H. Ransom, B. Kastner, M. Baerwald, R.J. Hulbert, M.H. Sawyer, W.B. Olsen, H. and Lambert, M.W., 1999 Early Diagenesis: Impact of Organic matter on Mass Physical Properties and Processes, California Continental Margin Journal of Marine Geology 159 734.CrossRefGoogle Scholar
Bennett, R.H. Lambert, M.W. Hulbert, M.H. Curry, C.W. Olsen, H.W. and Lowrie, A., 2004.Microfabric and Organic Matter Impact on Burial Diagenesis From Mud to Shale Siltstones, Mudstones and Shales: Depositional Processes and Reservoir Characteristics, SEPM-AAPG Special Symposium Short Course 9, available on CD through SEPMCrossRefGoogle Scholar
Berne, B.J. and Pecora, R., 1990 Dynamic Light Scattering Malabar, Florida, USA Krieger Publishing Company.Google Scholar
Boyer, J.N. and Kator, H.I., 1985 Method for measuring microbial degradation and mineralization of 14C-labeled chitin obtained from the blue crab, Callinectes sapidus Microbial Ecology 11 185192.CrossRefGoogle Scholar
Bryant, W.R. and Bennett, R.H., 1988 Origin, physical, and mineralogical nature of red clays: the Pacific basin as a model Geo-Marine Letters 8 189249.CrossRefGoogle Scholar
Chason, H. and Trevethan, M. (2006) Turbulence in a small subtopical estuary with semi-diurnal tides. Proceedings of the 2nd International Conference on Estuaries and Coasts (ICEC-2006), Guangzhou, Guangdong Province, China. Guangdong Economy Publishers, Vol. 1 (ISBN 7-80728-422-6).Google Scholar
Curry, K.J. Bennett, R.H. Mayer, L.M. Curry, A.L. Abril, M. Biesiot, P. and Hulbert, M.H., 2007 Direct visualization of clay microfabric signatures driving organic matter preservation in fine-grained sediment Geochimica et Cosmochimica Acta 71 17091720.CrossRefGoogle Scholar
Curry, K.J. Bennett, R.H. Smithka, P.J. Hulbert, M.H., Malik, A. and Rawat, R.J., 2009 Hierarchical modeling of biogeochemical processes and mechanisms that drive clay nano- and microfabric development New Nanotechniques Hauppauge, New York, USA Nova Science Publishers, Inc. 287317.Google Scholar
Dachs, J. and Bayona, J.M., 1997 Large volume preconcentration of dissolved hydrocarbons and polychlorinated biphenyls from seawater Intercomparison between C18 disks and XAD-2 column. Chemosphere 35 16691679.Google Scholar
Duan, S.W. and Bianchi, T.S., 2006 Seasonal changes in the abundance and composition of plant pigments in particulate organic carbon in the lower Mississippi and Pearl Rivers Estuaries and Coasts 29 427442.CrossRefGoogle Scholar
Eisma, D. and Li, A., 1993 Changes in suspended-matter floc size during the tidal cycle in the Dollard estuary Netherlands Journal of Sea Research 31 107117.CrossRefGoogle Scholar
Elimelech, M. Gregory, J. Jia, X. and Williams, R.A., 1995 Particle Deposition and Agglomeration: Measurement, Modeling and Simulation UK Butterworth-Heinemann Ltd.Google Scholar
Furukawa, Y. Watkins, J.L. Kim, J.-W. Curry, K.J. and Bennett, R.H., 2009 Aggregation of montmorillonite and organic matter in aqueous media containing artificial seawater Geochemical Transactions 10 2.CrossRefGoogle ScholarPubMed
Gates, W.P. Jaunet, A. Tessier, D. Cole, M.A. Wilkinson, H.T. and Stucki, J.W., 1998 Swelling and texture of iron bearing smectites reduced by bacteria Clays and Clay Minerals 46 487497.CrossRefGoogle Scholar
Goldschmidt, V.M., 1926 Undersokelser over lersedimenter Nordisk Jordbrugs forskuing 4–7 434445.Google Scholar
Hill, P.S., 1996 Sectional and discrete representations of floc breakage in agitated suspensions Deep Sea Research I 43 679702.CrossRefGoogle Scholar
Hill, P.S. Voulgaris, G. and Trowbridge, J.H., 2001 Controls on floc size in a continental shelf bottom boundary layer Journal of Geophysical Research-Oceans 106 95439549.CrossRefGoogle Scholar
Hulbert, M.H. Bennett, R.H. Baerwald, R.J. Long, R.L. Curry, K.J. Curry, A.L. and Abril, M.T., 2002 Observations of the sediment-water interface: Marine and fresh water environments Marine Georesources and Geotechnology 20 255274.CrossRefGoogle Scholar
Jaisi, D.P. Dong, H. Kim, J.-W. He, Z. and Morton, J., 2007 Nontronite particle aggregation induced by microbial Fe(III) reduction and exopolysaccharide production Clays and Clay Minerals 55 98109.CrossRefGoogle Scholar
Jaisi, D.P. Shanshan, J. Dong, H. Blake, R.E. Eberl, D.D. and Kim, J.-W., 2008 Role of microbial Fe(III) reduction and solution chemistry in aggregation and settling of suspended particles in the Mississippi River Delta Plain, Louisiana, USA Clays and Clay Minerals 56 416428.CrossRefGoogle Scholar
Johnstone, J., 1908 Conditions of Life in the Sea Cambridge, UK Cambridge University Press 332.Google Scholar
Kim, J.-W. and Peacor, D.R., 2002 Crystal-size distributions of clays during episodic diagenesis: The Salton Sea geothermal system Clays and Clay Minerals 50 371–80.CrossRefGoogle Scholar
Kim, J.-W. Peacor, D.R. Tessier, D. and Elsass, F., 1995 A technique for maintaining texture and permanent expansion of smectite interlayers for TEM observations Clays and Clay Minerals 43 5157.CrossRefGoogle Scholar
Kim, J.-W. Furukawa, W. Dong, H. and Newell, S.W., 2005 The role of microbial Fe(III) reduction in the clay flocculation Clays and Clay Minerals 53 572579.CrossRefGoogle Scholar
Kim, G.Y. Yoon, Hong, J. Kim, J.-W. Kim, D.-C. Dae, Kim, B.-K. and Kim, S.-Y., 2007 The effects of microstructure on shear properties of shallow marine sediments Marine Georesources & Geotechnology 25 3751.CrossRefGoogle Scholar
Kretzschmar, R. Holthoff, H. and Sticher, H., 1998 Influence of pH and humic acid on coagulation kinetics of kaolinite: A dynamic light scattering study Journal of Colloid and Interface Science 202 95103.CrossRefGoogle Scholar
Lagaly, G., 1981 Characterization of clays by organic compounds Clay Minerals 16 121.CrossRefGoogle Scholar
Lagaly, G. Barrer, R.M. and Goulding, K., 1984 Clayorganic interactions (and discussion) Philosophical Transactions of the Royal Society (London) A14 311 315332.Google Scholar
Lagaly, G., 1986 Interaction of alkylamines with different types of layered compounds Solid State Ionics 22 4351.CrossRefGoogle Scholar
Leppard, G.G. Heissenberger, A. and Herndl, G.J., 1996 Ultrastructure of marine snow I. Transmission electron microscopy methodology. Marine Ecology Progress Series 135 289298.CrossRefGoogle Scholar
Montgomery, M.T. Welshmeyer, N.A. and Kirchman, D.L., 1990 A simple assay for chitin: application to sediment trap samples from the subarctic Pacific Marine Ecology Progress Series 64 301308.CrossRefGoogle Scholar
Mietta, F. Chassagne, C. Manning, A.J. and Winterwerp, J.C., 2009 Influence of shear rate, organic matter content, pH and salinity on mud flocculation Ocean Dynamics 59 751763.CrossRefGoogle Scholar
Mietta, F. Chassagne, C. Verney, R. and Winterwerp, J.C., 2011 On the behaviour of mud floc size distribution: model calibration and model behaviour Ocean Dynamics 61 257271.CrossRefGoogle Scholar
O’Brien, N.R., 1971 Fabric of kaolinite and illite floccules Clays and Clay Minerals 19 353359.CrossRefGoogle Scholar
O’Melia, C.R., 1980 Aquasols: the behavior of small particles in aquatic systems Environmental Science and Technology 14 10521060.CrossRefGoogle Scholar
Pignatello, J.J. and Day, M., 1996 Mineralization of methyl parathion insecticide in soil by hydrogen peroxide activated with iron(III)-NTA or -HEIDA complexes Hazardous Waste & Hazardous Materials 13 237244.CrossRefGoogle Scholar
Pinheiro, J.P. Mota, A.M. Doliveira, J.M.R. and Martinho, J.M.G., 1996 Dynamic properties of humic matter by dynamic light scattering and voltammetry Analytica Chimica Acta 329 1524.CrossRefGoogle Scholar
Reuter, J.H., 1977 Organic matter in estuaries Chesapeake Science 18 120121.CrossRefGoogle Scholar
Sloane, R.L. and Kell, T.R., 1966 The fabric of mechanically compacted kaolin Fourteenth National Conference on Clay and Clay Minerals 14 289296.CrossRefGoogle Scholar
Terzaghi, K., 1925 Principles of soil mechanics settlement and consolidation of clay Engineering News-Record 874878.Google Scholar
Theilen, F.R. Pecher, I.A. et al. ,Hoven, J.M. 1991 et al. , Assessment of shear strength of the sea bottom from shear wave velocity measurements on box cores and in-situ Shear Wave in Marine Sediments Dordrecht, The Netherlands Kluwer Academic Publishers 6774.CrossRefGoogle Scholar
Vali, H. and Hesse, R., 1990 Alkylammonium ion treatment of clay minerals in ultrathin section: A new method for HRTEM examination of expandable layers American Mineralogists 75 14431446.Google Scholar
Verney, R. Lafite, R. and Brun-Cottan, J.-C., 2009 Flocculation potential of estuarine particles: The importance of environmental factors and of the spatial and seasonal variability of suspended particulate matter Estuaries and Coasts 32 678693.CrossRefGoogle Scholar