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Soil Micro-Morphology: A Basic and Applied Science, Proceedings of the VIIIth International Working Meeting of Soil Micromorphology PDF

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Developments in Soil Science 19 SOIL MICRO- MORPHOLOGY: A BASIC AND APPLIED SCIENCE Edited by LOWELL A. DOUGLAS Rutgers University, Department of Soils and Crops, P.O. Box 231, New Brunswick, NJ 08903, U.S.A. Proceedings of the VIIIth International Working Meeting of Soil Micromorphology, San Antonio, Texas - July 1988 Sub-Commision of Soil Micromorphology of International Society of Soil Science ELSEVIER Amsterdam - Oxford - New York - Tokyo 1990 ELSEVIER SCIENCE PUBLISHERS B.V. Sara Burgerhartstraat 25 P.O. Box 211,1000 AE Amsterdam, The Netherlands Distributors for the United States and Canada: ELSEVIER SCIENCE PUBLISHING COMPANY INC 655, Avenue of the Americas New York, NY 10010, U.S.A. Library of Congress Cataloging-in-Publication Data International Working-Meeting or, Soil Micromorphology l8tn : 1988 San Aq:zn;C, ?EX.) Soil micromorphology a basic and applied science 1 edited by Lowell A. Douglas. p. cm. -- (Developments in soil science ; 19) "Proceedings of the VIIIth International Working Meeting of Soil Micromorphology. San Antonio, Texas. July 1988." "Sub-commission of Soil Micromorphology of International Society of Soil Science." Includes bibliographical references. ISBN 0-444-88302-9 1. Soil oicromorphology--Congressesss. I. Douglas. Lowell A. :I. Internation21 Soclety of So;] Science. Sub-csnni~ission of Sol1 M:crorrorphclogy. 111. Title. IV. Series. S593.2.158 1986 635.4 5;-0:22 89-7834. CIP ISBN 0-444-88302-9 0 Elsevier Science Publishers B.V., 1990 All rights reserved. No part of this publication may be reproduced, stored in a retrieval system or transmitted in any form or by any means, electronic, mechanical, photocopying, recording or otherwise, without the prior written permission of the publisher, Elsevier Science Publishers B.V./ Physical Sciences & Engineering Division, P.O. Box 330,1000 AH Amsterdam, The Netherlands. Special regulations for readers in the U.S.A. - This publication has been registered with the Co- pyright Clearance Center Inc. (CCC ), Salem, Massachusetts. Information can be obtained from the CCC about conditions under which photocopies of parts of this publication may be made in the USA. All other copyright questions, including photocopying outside of the USA, should be referred to the copyright owner, Elsevier Science Publishers B.V., unless otherwise specified. No responsibility is assumed by the Publisher for any injury and/or damage to persons or property as a matter of products liability, negligence or otherwise, or from any use or operation of any methods, products, instructions or ideas contained in the material herein. This book is printed on acid-free paper Printed in The Netherlands V Co-Sponsors for IWMSM-88 The following agencies provided financial assistance for the publication of these Proceedings: Soil Science Society of America USDA - Agricultural Research Service USAID - Soil Management Support Services Texas A&M University System Other sponsors: International Society of Soil Science USDA - Soil Conservation Service Organizing Committee Chairman L.P. Wilding Texas A&M University Program M.C. Rabenhorst University of Maryland M.L. Thompson Iowa State University Editorial L.A. Douglas Rutgers University Local Arrangements M.H. Milford Texas A&M University Field Trips B.L. Allen Texas Tech University C.T. Hallmark Texas A&M University Financial Arrangements E.C.A. Runge Texas A&M University Secretary & Publicity L.R. Drees Texas A&M University Commercial Exhibits L.D. Norton USDA-ARS Soil Erosion Lab L.T. West University of Georgia Spouses’ Program Melinda Hallmark Texas A&M University USDA-SCSL iaison R.W. Arnold Washington, D.C. USAID-SMSS Liaison H. Eswaran Washington, D.C. Geol. SOC.A m. Liaison V.T. Holliday University of Wisconsin ISSS Liaison W.G. Sombroek Wageningen, The Netherlands VII PREFACE It is most fitting that the Proceedings of this VIII International Work- ing Meeting on Soil Micromorphology commemorates the pioneering efforts of the late Professor W.L. Kubiena, Father of Micromorphology. Fifty years ago, his classic text, 'Micropedology,' was published at Iowa State Univer- sity. This text was the first to introduce U.S. soil scientists to soil micromorphology. The advances in application of micromorphology and submi- croscopy to meet the challenges of earth and extraterrestrial science dis- ciplines of the next decade are in striking contrast to Kubiena's primary focus on pedology. Micromorphology is the science that studies microfabrics of undisturbed soil materials by microscopic (light optical and less frequently by submicro- scopic) methods, commonly using thin-section techniques. Micromorphology, as used in the U.S., is a tool - not a discipline. It is a means to an end and not an end in itself. The detail, significance, and interpretation of features observed micromorphically are lost if not set in context with soil as a natural landscape body. Thus, micromorphology is commonly applied to obtain specific microfabric information supplemental to the physical set- ting, macromorphological features, and physical, chemical, mineralogical, biological, and submicroscopy databases. It is a powerful intermediate resolution tool to refine macromorphological observations and generalize sub- microscopic observations. It serves to bridge the telescoping array of ob- servations from the visible range (low resolutionlhigh field of view) to the submicroscopic range (high resolutionllow field of view). Historically, micromorphology has evolved from the late 30's and early 40's in the U.S. through early efforts of Kubiena (1938) and associates at Iowa State University (Cady et al, 1986). Collectively, these pioneers ob- served microfabrics of soil we would consider today as Mollisols, Alfisols, and Inceptisols. While noting many pedological features in thin section, they suggested micromorphology may become a promising soil correlation tool. In the late 40's and ~O'S,f ive papers were published in major scientific outlets by Cady, Frei, Cline, Grossman, Buol and Hole (Wilding and Flach, 1985). This was the formative period for development of the 7th Approxima- tion, (Soil Survey Staff, 1960) in the U.S.. Most micromorphology studies of this period were on Alfisols, Mollisols, Spodosols and Inceptisols in the North Central and Northeastern regions of the U.S.. Emphasis was on VIII fragipans, argillic horizons, mineral transformations in rock weathering and composition of ped surfaces relative to ped interiors. From the 60's to the mid ~O'S,4 0 papers were published in U.S. journals with emphasis on the diagnostic horizons and their definitions as criteria for Soil Taxonomy (Soil Survey Staff, 1975). It was also the period when implications of micromorphology to soil/plant/root relationships were developed and micromor- phology work extended to all regions of the nation. Brewer's (1964) text was published to provide a systematic framework to describe and integrate micromorphology with pedogenesis. From the mid 70's to date, a dynamic growth and changing focus in the use of micromorphology has evolved. The thrust switched from a descriptive science to a problem-solving one and from a pedological oriehtation to multidisciplinary utilitarian applications. Ex- amples are micromorphology as a tool for: 1) tracing pathways of water move- ment and pollutants in soils; 2) the degradation of soil structure with con- sequent formation of crusts and tillage pans; 3) micromorphic evidence of soil failure and faulting; and, 4) utilization of micromorphology as an ar- cheological/paleopedological tool. During this period, the coupling of micromorphology and submicroscopy occurred. The publication of Soil Micromorphology and Soil Classification (Douglas and Thompson, 1985) il- lustrated the application of micromorphology in developing class differen- tiae for Soil Taxonomy. Micromorphology terminology in the U.S. has been steeped for nearly 25 years in Brewer's legacy and that of Kubiena before Brewer. The ISSS ter- minology (Bullock et al., 1985) is only beginning to gain acceptance. It will take time for conversion and adoption. The ISSS system is received with mixed enthusiasm by most U.S. scientists using micromorphology. This system is well-illustrated, provides for international reference and in- cludes an excellent chapter on organic components. However, many will argue that this system is tedious, difficult to apply, sometimes confusing and time-consuming. A future goal for this Working Group is to continue to strive for greater simplicity in micromorphology communication with allied earth scientists. A few micromorphology challenges are offered for the future. Micromor- phology needs better application and utilization in teaching. Students need to see the architecture of the 'real soil world' which can only be ap- preciated in microfabrics. Micromorphology offers the teacher an excellent visual aid to demonstrate fundamental properties and constraints of soil sys- tems. Another niche for micromorphology is to help develop better natural resource inventories. Micromorphology provides a tool to critically IX evaluate models of landscape evolution and soil patterns. Once validated, these models permit soil scientists to make more rapid and accurate soil sur- veys. The end product is better interpretations of soil resources for use management and environmental quality control assessments. The Interna- tional Geosphere Biosphere Program is a vehicle through which such contribu- tions could be made globally. Another area is the quantification of microfabrics by image analysis. This endeavor is still in a state of flux. Two schools of thought are prominent: 1) let the eye be the integrator and use image analysis to quantify visual entities of importance; and 2) let image analysis equipment do the entire task of identification, classifica- tion and quantification. This dilemma does not appear to be near resolution and would serve as a fruitful area for future research and dialogue. The diverse program of the VIII International Working Meeting on Soil Micromorphology, from which papers in this Proceedings are taken, address multifaceted and multidisciplinary, current micromorphic activities. They emphasize: 1) soil and ecological conditions of the arid and semiarid regions of the world (Aridisols, Vertisols, soils enriched with carbonates, gypsum and salts); 2) hydromorphic or wetland conditions); 3) current and na- tional/international research priorities (soil erosion and degradation, water quality and conservation and waste disposal); 4) applications of micromorphology to agronomic and earth scientists (soil/root interface, soil structure and porosity, water movement and retention, and mineral degrada- tion and synthesis); 5) education/technology transfer); 6) micromorphic tech- niques (new differential dissolution procedures, quantification of micromor- phology, submicroscopy, and dye stains for component identification); and 7) applications to other disciplines (geology, paleopedology and extrater- restrial sciences). Thanks are extended to all cosponsors of the IWMSM-88, to the Organiza- tion Committee and to the Field-Trip Tour leaders. Special recognition go to the extraordinary efforts of the SecretarylPublicity Chairperson (Dr. L.R. Drees), the Local Arrangements Chairperson (Dr. M.H. Milford) and the Mid-Conference and South Texas Tour Chairperson (Dr. C.T. Hallmark). Without their continual assistance and encouragement this Working Meeting could not have been hosted in such a professional manner. Finally, we are all indebted to Dr. L.A. Douglas, who has served as Editor-in-Chief of the Proceedings. All the papers were refereed by members of the Working Group. Dr. Douglas' dedication in bringing this publication to fruition is most meritorious and notable. X REFERENCES Brewer, R., 1964. Fabric and Mineral Analysis of Soils, John Wiley & Sons, New York. Bullock, P., Federoff, N., Jongerius, A., Stoops, G., Tursina, T., and Babel, U., 1985. Handbook for Soil Thin Section Description, Waine Research Publications, Mount Pleasant, UK, p. 152. Cady, J.G., Wilding, L.P., and Drees, L.R., 1986. Petrographic microscope techniques. In: A. Klute (ed.), Methods of Analyses, Part 1, 2nd ed. Agronomy, 9: 185-218. Douglas, L.A. and Thompson, M.L., 1985. Soil micromorphology and soil classification. In: SSSA Special Pub. No. 15, Soil Sci. SOC. America, p. 216. Kubiena, W.L, 1938. Micropedology, Collegiate Press, Ames, Iowa. Soil Survey Staff, 1960. Soil classification, a comprehensive system. In: 7th Approximation, USDA-SCS, U.S. Government Printing Office, Washington, D.C. Soil Survey Staff, 1975. Soil taxonomy: A basic system of soil classi- fication for making and interpreting soil surveys, USDA-SCS, U.S. Government Printing Office, Washington, D.C. Wilding, L.P. and Flach, K., 1985. Micropedology and soil taxonomy. In: L.A. Douglas and M.L. Thompson (eds.), Micromorphology and Soil Classification, Spec. Pub. No. 15, Soil Sci. SOC. Am.. Larry P. Wilding Soil & Crop Sciences Dept. Texas A&M University College Station, Texas 77843 1 THE FUTURE OF SOIL MICROMORPHOLOGY M.J. KOOISTRA Netherlands Soil Survey Institute, P.O. Box 98, 6700 AB Wageningen (The Netherlands) ABSTRACT The future of soil micromorphology can only be grasped properly if the scope of soil micromorphology is clearly defined. Looking at the definitions of soil micromorphology and submicroscopy the conclusion has to be drawn that soil micromorphology is not a science in itself; it is a scientific activity to obtain specific information. This information has to add real extra value to the research concerned, not only at feature level, but expressed as processes and their implications, and needs to be available within the limitations of costs and time. Micromorphological research, however, is a specialist's job because specialized knowledge is required to select the appropriate methods and techniques to obtain the required information, and to identify features and processes and to quantify them and their effects. In practice, this level of extra information is rarely reached. In the successive steps of a micromorphological study, there are several weak point:; which need improvement. The most obvious technical points are: inadequate sampling procedures, restricted knowledge of available techniques of light microscopy and submicroscopy, and lack of reliable quantitative analyses. In micromorphological research itself, the level of interpretation is often t.oo low, because diagnostic criteria for different processes and their magnitude are not sufficiently known, and syntheses of micromorphological results with results from other fields of research are not stressed sufficiently. Historically, micromorphology was applied to the genesis and classification of soil. In the last decade, more fields of application have emerged, st-imulated by new developments in light microscopy and submicroscopy, microchemical analysis and quantitative approaches. Examples of these new fields are: the relations between biotic and abiotic processes; the effects of different land uses including agricultural practices; the reconstruction of past. environments and of human-induced events in sedimentology and archaeology. If the weak points of micromorphology are improved and the level to which micromorphologists are trained is increased substantially, micromorphology will enlarge its scope further and its future will be promising. 1 INTRODUCTION At the International Working Meeting on Soil Micromorphology a workshop/panel discussion was organized on the future of soil micromorphology. A short introduction was prepared to focus attention on this topic and to provide a framework for the discussion. This paper reflects the content of that introduction, augmented by important remarks from the panel members and the audience. The panel members were: Dr. H.J. Altemuller, F.A.L., Braunschweiy, 2 B.R.D.; Dr. L.M. Bresson, 1.N.A.-Grignon, France, and Dr. G. Stoops, R.U. Gent, Belgium. 2 SCOPE OF SOIL MICROMORPHOLOGY To be able to consider the scope of soil micromorphology, some basic definitions must first be given. For a start, the concept of soil micromorphology has to be defined. It can be formulated as follows: "Soil micromorphology is the study of undisturbed materials, viz. soils, sediments, unconsolidated rock, generally in thin sections, with light and submicroscopic techniques". This definition immediately leads to the formulation of a second definition, for submicroscopy: "Submicroscopy is the study of undisturbed materials, whether or not hardened or processed into thin sections with instruments which analyse emitted radiation of wavelengths smaller than visible light (Bisdom/Kooistra)". From these two definitions it must be concluded that soil micromorphology in itself is not a science but a scientific activity using specific techniques. Figure 1 gives an overview of the procedure and kind of specific information obtained by a micromorphological study. The features observed are translated into processes, whose strengths and interrelations can be identified and used (often in combination with other analytical data) on a higher level, for extrapolations, explanations, models and predictions. identification 1 ELJ location observations distribution & r- interrelations description/ quantification tables etc. reflect 3 identification strength/frequency interrelations actuality result in extrapolation/ generalization synthesis models predict ions Fig. 1. Overview of the procedure and use of specific information obtained by micromorphological research. 3 Micromorphology can be applied to a wide range of sciences. At the moment the main ones are soil science, geology, physical geography, agricultural sciences, biology, archaeology and engineering. Consequently, the strength of micromorphology is that it adds new information unobtainable from the research approaches of other scientific fields. Micromorphology in itself, however, is a specialist's job, because it requires ample knowledge of identification of features, processes, quantitative analyses and their implications, as well as a thorough knowledge of methods and techniques. On the basis of this conclusion the fundamental requirements of a micromorphological study can be formulated: - Adequate information must be produced: it must be valuable not only at feature level, but be expressed as processes and effects for higher level applications. This information needs to be available within the constraints of finances and time. - The results must be easy to incorporate in the field of science concerned. This implies: simple terminology, adequate quantitative data and clear interpretations. The scope of micromorphological research implies that a micromorphologist can rarely work in isolation, because cooperation with other specialists will often be required. The micromorphologist also needs to have an open mind, to pick up demands for research and to translate them into micromorphological research which really does provide essential extra information (Fig. 2). 3 THE SCREENING PROCEDURE IN MICROMORPHOLOGICAL RESEARCH Below, the consequences of the abovementioned scope of soil micromorpholoqy for the successive steps in the research procedure are considered. The procedure chosen is first to formulate the general practice and then to formulate future requirements. The latter are not necessarily already avajlable. For certain steps, much research needs to be done before application can be realized. The intention is to sketch the main lines for future development. This may stimulate reflections and actions to improve and develop new approaches. The procedure of a micromorphological study can be split up in the following steps, which are all of basic importance and determine the ultimate quality of the research performed: 1 sampling, 2 preparation of sections, 3 techniques, 4 presentation of data, 5 interpretation, 6 synthesis. These items will now be considered in turn.

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