SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES ? NUMBER 13 Distinctive Properties of Turbiditic and Hemipelagic Mud Layers in the Algero-Balearic Basin, Western Mediterranean Sea Nicolaas A. Rupke and Daniel Jean Stanley SMITHSONIAN INSTITUTION PRESS City of Washington 1974 ABSTRACT Rupke, Nicolaas A., and Daniel Jean Stanley. Distinctive Properties of Turbiditic and Hemipelagic Mud Layers in the Algero-Balearic Basin, Western Mediter- ranean Sea. Smithsonian Contributions to the Earth Sciences, number 13, 40 pages, 21 figures, 8 tables, 1974.?Two types of mud layers alternate in domi- nantly muddy cores of the southern Balearic Basin. Type A muds (a few cm to over 50 cm thick), macroscopically homogeneous, occur above turbidite sands or silt laminae. Type B muds (imperceptible to about 50 cm thick), compara- tively coarse due to interspersed microskeletons, occur below turbidite sands or silt laminae, and lie above type A muds. The two types are distinguished in X- radiographs on the basis of texture and sedimentary structures. Type A and B mud layers in six cores were sampled at 1 to 8 cm intervals. Type A muds are distribution graded (upward shift of the entire size distri- bution to finer sizes), continuing the upward grading of the underlying sand turbidites. A granulometric change occurs at the boundary with type B muds which contain sand (to 16 percent), largely tests of forams and pteropod shells. The sand fraction of type A muds (< 1 percent) differs from that of type B in the proportion of terrigenous constituents and in remains of pelagic forams and of pteropods. Type B muds are not graded; their grain-size distribution is uniform. They have a higher (26 to 46 percent) carbonate content than type A (16 to 39 percent). In some instances, peak-height ratios of clay minerals change across the boundary between type A and type B mud layers. It is concluded that type A muds are turbiditic (deposited instantaneously), while B muds are hemi- pelagic deposits. Carbon-14 ages were determined on the carbonate sand fraction of type B layers. The ages were plotted against the total sediment thickness above the dated samples in each core. A statistically significant correlation exists. How- ever, when the turbiditic sand and mud layers are omitted and the ages are plotted only against the combined thicknesses of the hemipelagic type B layers, an even stronger correlation is obtained. The hemipelagic rate of sedimentation during the past 16,000 years approximates 10 cm/1000 years. The frequency of tur- bidity current incursions at a particular core location averages 3 per 2000 years. OFFICIAL PUBLICATION DATE is handstamped in a limited number of initial copies and is recorded in the Institution's annual report, Smithsonian Year. SI PRESS NUMRFR 5089. SERIFS COVER DESIGN:Aerial view of Ulawun Volcano, New Britain. Library of Congress Cataloging in Publication Data Rupke, Nicolaas A.Distinctive properties of turbiditic and hemipelagic mud layers in the Algero-Balearic Basin, western Mediterranean Sea. (Smithsonian contributions to the earth sciences, no. 13)Supt. of Docs, no.: SI 1.26: 13. 1. Marine sediments?Western Mediterranean. 2. Turbidites?Western Mediterranean. I. Stan-ley, Daniel Jean, joint author. II. Title. III. Series: Smithsonian Institution. Smithsonian contributions to the earth science, no. 13.QE1.S227 no. 13. [GC389] 550'.8s [551.4'62'1] 74-1273 For sale by the Superintendent of Documents, U.S. Government Printing Office, Washington, D.C. 20402 Price 95 cents Contents Page Introduction 1 Geographic and Geologic Setting 3 Core Locations 5 Lithologic Description of Cores . ? 5 General 5 X-radiographic Identification of Mud Layers 9 Variations within Cores 9 Variations between Cores . 9 Color of Sediment 10 Analysis of Rhythms 11 General 11 Analytical Procedures 12 Grain-Size Distribution 15 Carbonate Content 19 Composition of the Sand Fraction 21 Clay Mineralogy 27 Discussion 28 Types of Depositional Mechanisms . 28 Mud Deposition?General . 30 Turbiditic Mud Deposition?Type A Muds . . 30 Hemipelagic Mud Deposition?Type B Muds 31 Normal Bottom Current Activity 31 Mud Turbidites and Contourites 31 Ancient Flysch and Flysch-like Successions 32 Radiocarbon Ages and Rates of Sedimentation 32 Conclusions 35 Literature Cited 36 in Distinctive Properties of Turbiditic and Hemipelagic Mud Layers in the Algero-Balearic Basin, Western Mediterranean Sea Nicolaas A. Rupke and Daniel Jean Stanley Introduction Graded sands and sandstones, alternating with fine-grained layers, form thick accumulations in modern deep-sea basins and in ancient geosynclinal belts, where they are called flysch. The deep-sea sands are generally believed to be the products of turbidity currents that transport coarse-grained sediments to the deep marine environment, smooth out topography, and construct abyssal plains (cf. summary by Horn, Ewing, and Ewing, 1972). A compelling amount of evidence points to a tur- bidity current emplacement of most flysch sand- stones as well, in spite of some remaining problems (cf. review by Kuenen, 1967). The flysch-type sands and sandstones exhibit a characteristic assemblage of internal and bedding plane structures. The internal sedimentary struc- tures occur in a fixed succession of structural inter- vals or divisions, viz., a basal, graded division (a), a lower division of parallel lamination (b), a divi- sion of current ripple lamination (c), an upper Nicolaas A. Rupke and Daniel Jean Stanley: Division of Sedi- mentology, Department of Paleobiology, Smithsonian Institu- tion, Washington, D.C. 20560. Rupke, present address: Department of Geology and Mineralogy, Oxford University, Oxford 0X1 3PR, Great Britain. division of parallel lamination (d), and a largely structureless, fine-grained or pelitic division (e) (Bouma, 1962, fig. 8). This succession of sedimen- tary structures, defined from ancient flysch sand- stones, applies to modern deep-sea sands as well (cf. review by Walker, 1970). The interpretation of the flysch-type sands and sandstones as turbidity current deposits or turbidites is to a significant extent based on these sedimentary structures and their reproduction in experimental flume studies (summarized in Middleton, 1965). In the fine-grained division (variously called pelite,1 lutite, clay or shale layer, argillite, and mud2 or mudstone layer), primary sedimentary structures are virtually absent. Accordingly, the question of the origin of the pelitic division is still largely unresolved and has often remained unad- dressed in many publications on turbidite sequences. In most of the early, often classic, papers on tur- x In this study we use the term "pelite," defined as a "sedi- ment or sedimentary rock composed of the finest detritus (clay- or mud-size particles)" (AGI, Glossary of Geology, 1972). 2 Mud is defined as "an unconsolidated sediment consisting of clay and/or silt, together with material of other dimen- sions (such as sand), mixed with water, without connotation as to composition" (AGI, Glossary of Geology, 1972). 1 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES bidites it was tacitly assumed, or sometimes argued, that most or all of the pelitic layers represent the normal, pelagic settling, interrupted at times by the instantaneous emplacement of turbidite sands (e.g., Sujkowsky, 1957; Dzulynski, Ksiazkiewicz, and Kuenen, 1959; Gorsline and Emery, 1959; Stanley, 1963). More recent studies of turbidite sequences have also implied that the pelitic layers represent normal, pelagic settling (e.g., Cline, 1970; McBride, 1970; Moore, 1971). However, during the past decade or so the con- viction has been growing that at least a portion of the mud layers in the modern deep sea is de- posited by turbidity currents. Van Straaten (1966, 1967, 1970) recognizes turbiditic mud layers in the southern Adriatic Sea. Van Andel and Komar (1969) document resedimentation by turbidity currents of pelagic oozes in valleys on the flanks of the Mid-Atlantic Ridge. A considerable fraction of the thick, largely muddy wedges forming base-of- slope deposits are also deposited by turbidity cur- rents (Stanley, 1969, 1970). Piper (1973) describes silts and muds of turbiditic origin from the Gulf of Alaska. Evidence that at least part of the pelitic division (e) is turbiditic in origin is provided mainly by the faunal content. Instances have been found in which only the upper part of the pelitic layer contains a relatively high percentage of skeletal remains of pelagic and deep benthonic organisms (Ksiazkie- wicz, 1961; Natland, 1963; van Hinte, 1963; Weid- mann, 1967; Weiler, 1967; Comas, 1968; Davies, 1968; Tanaka, 1970; and others). This upper part of the pelite is, in several of these instances, of a different lithology and color (Ericson, Ewing, and Heezen, 1952; Bornhold and Pilkey, 1971; Huang and Pierce, 1971). Graptolites in the pelite have been shown to be oriented parallel to the sole markings of the underlying turbidite sandstones (Moores, 1969). Textural evidence for turbidite deposition, such as grading in the lower part of the pelitic layer, and grading throughout the entire pelite division, have been found as well (Radomski, 1958, 1960; Piper, 1972; Rupke, 1972; Hall and Stanley, 1973). Other evidence for the turbiditic origin of pelites comes from various statistical analyses of bed-thickness properties (Enos, 1969; Rupke, 1969). In some publications the pelitic division has been regarded as almost entirely turbiditic, with little or no pelagic sediments forming the top part (Nesteroff, 1961; Bouma, 1962; Nesteroff and Heezen, 1963; Rusnak and Nesteroff, 1964). In their reviews of ancient and modern flysch- type sequences, Dzulynski and Smith (1964) and Kuenen (1964) concluded that in flysch-type se- quences the pelites are dominantly turbiditic in origin, and that the truly pelagic parts are insig- nificant in volume. In a number of publications it has simply been assumed that some (lower) parts of the pelitic layers are turbiditic, while other (upper) parts are pelagic, without specification of criteria (Nederlof, 1959; Holtedahl, 1965; Walker, 1967; and others). In recent years, other depositional mechanisms for fine-grained sediments have been proposed, in addition to pelagic settling and turbidity currents. Ewing and Thorndike (1965) observed a nepheloid layer of suspended fine-grained sediment on the continental slope and rise of northeastern America, which may play a role in resedimentation of muds. Similar low-density and gravity-assisted flows carry- ing fine-grained sediments to deep marine environ- ments have been proposed. These can be of permanent nature or can be seasonally reactivated during river flooding or scouring of the outer shelf margin by storms (Moore, 1969; Bartolini and Gehin, 1970; Stanley, Gehin, and Bartolini, 1970; Stanley, Sheng, and Pedraza, 1971; Fleischer, 1972; Huang and Stanley, 1972). Normal bottom currents, in particular geo- strophic contour-following currents (Heezen, Hol- lister, and Rudiman, 1966), are thought to play a role as well in deep-sea sediment transport and deposition. Deposits by these currents, called con- tourites, are described by Wezel and Ryan (1971) and Bouma (1972a, 1972b) in ancient flysch sequences; Bouma (1972a, 1972b) tabulates the dif- ferences between turbidites and contourites. These bottom currents are capable of reworking sands (Hubert, 1964), but are invoked mainly for the transport and deposition of very fine sand and silt. In summary, there is evidence for several depo- sitional mechanisms affecting fine-grained sediments in both modern and ancient deep marine environ- ments. The question, however, of how much of the pelitic layers in turbidite sequences is accumulated by pelagic settling, and how much by turbidity currents, bottom currents, or other depositional mechanisms remains largely a matter of doubt and NUMBER 13 dispute. The present study addresses itself to this question of the origin of mud layers and constitutes an attempt to define, from an analysis of different types of mud, criteria that may indicate a particular mechanism of deposition. This investigation has been carried out using sediment cores from the southern part of the Balearic Abyssal Plain in the western Mediterranean. Recognition of the depositional mechanisms of deep-sea muds is not only of significance for the understanding of deep marine processes of sediment distribution, but is also essential for studies of the chronology and paleoclimatology of deep-sea cores. ACKNOWLEDGMENTS.?We are indebted to the U.S. Navy for providing shiptime and facilities aboard the USNS Lynch on its cruise (LY-II-72) in March-April 1972, and for furnishing the cores and 3.5 kHz records used in this study. In partic- ular, we thank the officers and crew of the Lynch, and scientific personnel including students from Williams College and the University of Illinois for their assistance aboard ship. Mr. Harrison Sheng, Smithsonian Institution, assisted with various lab- oratory analyses. The paper has been critically read by Drs. A. G. Fischer, Princeton University, H. G. Reading, Oxford University, and L.M.J.U. van Straaten, Rijksuniversiteit, Groningen; we appre- ciate their constructive criticisms and suggestions. Funding for this study, part of the ongoing Medi- terranean Basin Project, was provided by the Smithsonian Research Foundation grant (DJS) FY73-430035. This investigation was undertaken while Rupke held a postdoctoral fellowship at the Smithsonian Institution. Geographic and Geologic Setting The Balearic Sea, also referred to as the Algero- Provenc_al Basin, occupies most of the western Mediterranean. It extends from the Ligurian Sea in the northeast and the coast of southern France in the northwest, southward between Corsica- Sardinia and the Balearic Islands, down to the coast of North Africa. Cores examined in this study were collected in the southern part of the Balearic Sea, known as the Algero-Balearic Basin (Figure 1). The present geographic configuration has been explained in terms of rifting, lateral spreading, and rotation of microblocks (Iberia, the Balearic block, and the Corsica-Sardinia block) (Ritsema, 1969; Hsu, 1971; Vogt, Higgs, and Johnson, 1971; Auzende, Bonnin, and Olivet, 1973; Dewey, et al., 1973). In addition to lateral spread- ing, evidence for vertical tectonics has been pre- sented (Bourcart, 1959; Pannekoek, 1969; van Bemmelen, 1969). The Balearic Basin is bounded by narrow shelves, platforms, and continental slopes that, for the most part, exceed 5?. These are in many places incised by submarine canyons (Bourcart, 1959). They border a large, flat basin floor, called the Balearic Abyssal Plain, the largest basin plain in the Mediterranean Sea. The 2600 m bathymetric contour serves to delineate the abyssal plain (Carter et al., 1972). The plain, a depositional feature, forms the surface of a stratified sedimentary fill, of which the thickness is estimated from subbottom profiles at 300 to 450 m (Horn, Ewing, and Ewing, 1972). The total thickness of the Plio-Quaternary uncon- solidated sediment fill reaches to 1200 m in the vicinity of the Rhone Cone (Menard, Smith, and Pratt, 1965; Watson and Johnson, 1969; Ryan et al., 1969). Piston-coring surveys show that the sediment underlying the plain comprises mostly mud with some alternating graded and laminated sands and silts. JOIDES drilling in the Balearic Basin (Leg 13, sites 124, 133, 134) reveals thick deposits of Quaternary and Pliocene age, underlain by a Messinian evaporite sequence (Ryan, Hsu, et al., 1937a,b). For instance, at site 124 situated off the eastern margin of the Balearic rise (Figure 1), a thick sequence of rhythmically bedded sediments has been recovered. Its lower part (200 m), largely of Pliocene age, contains light- and dark-colored marl oozes and sand-silt laminae, which form the bases of the dark oozes. The upper part (160 m), of Quaternary age, contains alternating graded sand- silt layers and marl oozes. Nesteroff (1973) and Nesteroff, Wezel, and Pautot (1973) interpret the lowrer section as contourites, and the upper section as turbidites (cf. Nesteroff et al., 1972). The abyssal plain surface has a slight gradient away from the main source of terrigenous sediment and toward its deepest part (2800 m) lying west of Sardinia. The most important terrigenous sedi- ment source is the river Rhone, the mouth and submarine fan of which are located in the north- western part of the basin (Menard, Smith, and Pratt, 1965; Horn, Ewing, and Ewing, 1972). The SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES 0 SO 100 KM 0?00' 05?00' FIGURE 1.?Locations and numbers of seven cores taken from the Balearic Abyssal Plain (hiring March-April 1972 aboard the USNS Lynch. The isobaths are in meters. The 2600 in isobath delineates the abyssal plain. JOIDES leg 13 site 124 and core 210 of the Swedish Deep-Sea Expedition are also shown. Rhone has been the main source of sediment since the Pliocene foundering of the northern Medi- terranean margin (Bourcart, 1959), and probably earlier. Another important source of fluvial sedi- ments is the North African margin (Leclaire, 1972a, 1972b; Vita-Finzi, 1972); much of these materials bypass the narrow shelf and move downslope, in some cases via canyons, toward the plain surface. To a lesser degree, sediments are also derived from the Iberian Peninsula, the Balearic Platform, and the Strait of Sicily. River input is to a large degree seasonally controlled; late fall to spring rains and snow-melt result in increased discharge during these periods (Semple, 1931). Seasonally shifting wind patterns also modify the volume of aeolian dust transported off the North African margin (Eriksson, 1965). The movement of the upper two water masses [surface and intermediate or Levantine water (Wust, 1960; Lacombe and Tchernia, 1972)] are influential in the movement of fines and planktonic organisms in suspension. Little is known of bottom water flow and velocities (Miller 1972). Bottom photographs made in this region do not indicate evidence of significant bottom current activity. The role of large-scale vertical sinking of surface water in the northern Balearic Sea (Stommel, Voorhis, and Webb, 1971) as a significant mechanism in sediment transport to the basin plain has yet to be evaluated. Earthquakes play an important role in trigger- ing turbidity currents, slumps, and other mass gravity failures along the steep, narrow margin of this region. The area is seismically active (Bara- NUMBER 13 zangi and Dorman, 1969; McKenzie, 1970); a line of earthquake epicenters trends from the Azores to the Strait of Gibraltar eastward across North Africa to Sicily. The Orleansville earthquake of 1954, for instance, triggered a large turbidity current in the southwestern sector of the Algero-Balearic Basin, an occurrence well documented by cable breaks (Heezen and Ewing, 1955; Horn, Ewing, and Ewing, 1972). The structural mobility of the region also affects sedimentation in other ways. Numerous salt dome diapirs (Watson and Johnson, 1969; Ryan et al., 1969) of Messinian age (Ryan et al., 1973) occur across much of the abyssal plain. Salt tectonics has disturbed the Quaternary sediment succession, in- cluding the uppermost Holocene strata in many places, particularly in the vicinity of 2? longitude (Stanley and Diester-Haas, 1973). Elongate salt knolls deflect sediment dispersal along the plain surface and locally act as dams against which strat- ified deposits are ponded (Figure 2). Core Locations During the March-April 1972 cruise of the USNS Lynch (LY-II-72), seven Ewing piston cores were retrieved from the Balearic Abyssal Plain at seven different stations in the Algero-Balearic Basin. The cores are coded from east to west LY-II-7, -8, -8A, -9, -9A, -10, -10A (Figure 1). Stations were selected for deepwater light scattering experiments, and not with a sedimentary basin analysis in mind. The cores, therefore, constitute random sediment samples from the Balearic Abyssal Plain. TABLE 1.?Location, water depth, and length of sexien cores obtained from the Balearic Abyssal Plain on the USNS Lynch March-April 1972 cruise (see Figure 1) Core no. 7 8 8A 9 9A 10 10A iMtitude 38?02.7'N 37?58.8'N 37?56.0'N 37?47.3'N 37?47.0'N 37?31.FN 37?32.0'N Longitude 8?09.2'E 6?11.0'E 5?41.0'E 3?43.0'E 3?00.9'E 1?18.9'E O?33.5'E Water (m) 2588 2719 2712 2674 2676 2655 2628 depth {fm) (1415) (1487) (1483) (1462) (1463) (1452) (1437) Core length (cm) 342 428 382 513 444 445 461 The ship track, along which almost continuous 12 and 3.5 kHz echo-sounding records were ob- tained, extends from the western sector of the Strait of Sicily to the region south of the Balearic Islands and the southeastern coast of Spain in the vicinity of the Mar Menor. This east-west trending line constitutes an almost complete section across the Algero-Balearic Basin, and is oriented approxi- mately at right angles to the main directions of sediment supply (except for cores 7 and 10A). Core location, length, and uncorrected water depth are listed in Table 1. Total core lengths range from 342 to 513 cm; the average core length is 431 cm. The water depth ranges from 2588 to 2719 m. The position of cores 8 to 10A, as indi- cated on echo-sounding records, is shown on Fig- ure 2. Core LY-II-7 was collected on the lower fan sur- face of the Strait of Sicily Fan, just south of a levee bounding the southern margin of the Strait of Sicily Canyon. Core LY-II-8 was retrieved on the almost hori- zontal basin plain surface, while LY-II-8A was cored in a wedge of stratified sediment ponded be- hind an emerged salt dome. Cores LY-II-9, -9A, and -10 were collected in a zone of distinctly stratified sediment between salt domes south of the Balearic block; evidence of salt tectonism such as rim synclines, arching of strata, faults, and grabens occur in the immediate vicinity. Core LY-II-10A was retrieved east of the Maz- zaron Escarpment and just beyond the Mar Menor Fan; the plain surface has a low gradient, and lies in a structurally active region in the westernmost Algero-Balearic Basin. Lithologic Description of Cores GENERAL The seven cores consist predominantly of muddy sediments. Visual examination of split cores shows that much of the core sections appears homoge- neous (Figure 3). Lamont-Doherty cores taken in the same general area have been interpreted as consisting largely of homogeneous mud (Horn, Ewing, and Ewing 1972). In most of the cores, a few sand-silt and silt intercalations stand out as a result of textural and color differences (Figure 3). The cores w7ere initially cut in 2 m sections and s s 3 S x P s . O Q X S NUMBER 13 t 8A-18 10-5 10A-19 9A-7 FIGURE 3?Photographs of split-core sections containing typical successions of turbidite sand-silt layers (8A-18, 10-5) or silt laminae or lamels (10A-19, 9A-7), and two types of mud layers, A(el) and B (ep). Note the absence of clearly visible layer boundaries within the muds. The interpretative column on the left is largely based on X-radiographs of these sections.. The first part of the section numbers refers to a core, the second to a rhythm within a core. o o 3 8-7 10-5 8-20 8A-11 FIGURE 4.?X-radiograph prints and interpretative column of five rhythms of turbidite sand-silt layers or silt laminae, followed by largely homogeneous type A mud (e'), which in turn is followed by type B mud (ep) exhibiting light speckling. The lower part of type A layers can be finely laminated (10-5, 8-20, 10A-15). One rhythm (8A-11) contains no type B layer. In the turbidite sand-silt layer in rhythm 10-5, note current ripple lamination between two co-sets of lower and upper parallel lamination. Also note in type B mud layer two horizons of extra light speckled bands. The distinct horizontal lines in 8-7 and 10-5 are artifacts produced by the joining of two different photographic prints. NUMBER 13 kept in cold storage, split, color logged, photo- graphed, and X-radiographed before sediment samples were taken for detailed analysis. Figures 3 and 4, many of these lithologic bound- aries would go unnoticed without the aid of X-radiographs. X-RADIOGRAPHIC IDENTIFICATION OF MUD LAYERS The X-radiographs of split-core sections reveal that the sand-silt and silt layers exhibit several of the structural characteristics associated with tur- bidites. All layers are base-cutout successions of Bouma divisions, viz., Tu-c-d, Tc_d, or Td (Figure 4). The lowermost graded a-division is never pres- ent. The base of these layers is sharp, and fining- upward grading is macroscopically visible in the split cores. These layers are interpreted as typical turbidite sands or silts. In addition to these turbidite sand-silt layers, the X-radiographs reveal a large number of distinct mud layers, many of which are very difficult to rec- ognize in the split cores (Figure 3). These more subtle layers overlie sand-silt turbidites, or they begin with a dark line on X-radiograph prints, constituting silt laminae (less than 1 cm thick) or lamels (less than 1 mm thick). The lower boundary of the coarser grained lower laminae or lamels is always sharper defined than the upper. Two kinds of mud occur above these layers, as well as on top of the turbidite sand-silt layers. Type A mud, which appears darker, lies directly on top of the coarser layer below. Its lower portion can exhibit delicate lamination. Type B mud appears lighter and is distinguished by light specks; it lies on top of type A mud and precedes the coarser layers (Figure 4). The speckling is produced by interspersed micro- skeletons of foraminifera and pteropods in the mud. The boundary between mud types A and B is often gradual and in some instances blurred by mottling and other evidence of bioturbation. The upper portion of type A mud layers can contain tubes consisting of FeS2 (Figure 18F). Such pyri- tized filaments are reported by Hesse and von Rad (1973) in sediments from the Strait of Otranto. These, readily apparent in X-radiographs, probably result from burrowing organisms. Delicate and sometimes repeated scraping of the wet sediment surface of the split cores is necessary to observe the boundaries of the mud layers identified in X-radiographs. As can be seen from a comparison of core section 10-5 illustrated in VARIATIONS WITHIN CORES Vertical variation within the cores consists of a rhythmic succession of three members, viz., (1) the coarser grained turbidite sand-silt layer, or the silt lamina or lamel, (2) the type A mud layer, and (3) the type B mud layer. A unit consisting of any of the three members is herein called a rhythm. In some rhythms the lower coarser grained member is absent, or the upper type B mud member is missing, or both. In general, four types of rhythmic successions of the three members occur in the cores (Figure 5). sand-silt 1 FIGURE 5.?Four types of rhythmic successions of three member layers (sand-silt, and two types of mud) as found in seven cores from the Balearic Abyssal Plain (see Figure 6). The average thickness of turbidite sand-silt layers is 4.5 cm; of type A mud layers 17.5 cm; and of type B mud layers 10.5 cm. The maximum thickness of type A mud is 47.5 cm, and the mini- mum thickness 1 cm. For type B mud, these values are respectively 53.5 cm and imperceptibly thin. The measuring accuracy varies, but is approxi- mately 0.5 cm for the mud layers and can be 0.1 mm for the sand-silt layers. VARIATIONS BETWEEN CORES The sand-silt or silt members, type A muds, and type B muds are depicted in Figure 6; thickness data are listed in Table 2. The cores contain widely varying numbers of rhythms, viz., from cores LY-II-7 to 10A respectively: 25, 23, 22, 12, 18, 13, and 25. Their average thicknesses vary accordingly (Table 2; Figure 6). 10 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES TABLE 2.?Number, thicknesses (in cm), and thickness statistics of sand-silt turbi- dites (Sa-Si), type A mud layers (interpreted as turbiditic or ef, and type B mud layers (interpreted as hemipelagic or ep), in seven cores (7-10A) from the Balearic Abyssal Plain (the layer succession is listed from left to right, and upward, in each core column) Rhythm No. 26 25 24 23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 Average thickness % of total thickness Sa-Si 0.2 0.2 0.2 0.4 0.3 0.2 0.2 0.2 0.2 0.5 0.3 0.2 0.2 0.1 0.2 1 7 5 10.5 8.5 6 11 3 4 4 5.5 8 5.5 3.5 10 8.5 5 4 3 1 4.5 3 2 2 2 5.5 2 5 37 (eP) 3.5 5 5.5 2 3 9.5 38 15 23 11 9 2.5 44.5 3.5 16 6 6 1.5 8 11 62 Sa-Si 3.5 16 12 10 13 2.5 1 4 8 0.3 3 8.5 10 2.5 6.7 22 8 (e*) 8 14.5 6 11.5 16.5 7.5 8 6.5 10 6.5 14 9.5 17.5 1 10 13 17.5 1.5 1 13 10 7.5 21 10 54 (e-) 2 8.5 6.5 5 1 3.5 3 4.5 14 7 3 8 14.5 5 3 2.5 11 6 24 Sa-Si 7 8 14 5.5 8 0.7 1.5 10.5 0.7 5.5 18 7 0.7 6.7 23 8A (el) 19 13.5 9 13.5 21 12 7.5 9.5 8 12 13 10 10.5 12 10.5 16.5 1 11 11.5 1 1.5 1 10.5 59 (ep) 2.5 3.5 7.5 3 3.5 3.5 9 7.5 3.5 6 5 6 1 4.5 2 4 18 Sa-Si 0.7 0.2 3 0.8 7 26 6.3 7 9 (e*) 11.5 16 17 45 41.5 17 18.5 22 45.5 13 47.5 10.5 25.5 60 (e?) 44.5 18 7.5 5 38 12.5 5 3.5 36 19 33 Sa-Si 4 0.5 2 2 0.4 0.3 0.5 1.4 2 9A (e*) 5 10 9 11 8.5 20.5 45 17 10 4 6 12 21.5 13.5 23 23.5 2 13 14 58 (ep> 16 14.5 25.5 1 23 3 8.5 6.5 17.5 27.5 2.5 2 5.5 4 1 2.5 12 4.5 3 9.5 40 Sa-Si 1.2 11 7.5 9 0.2 4 8.5 2.5 1.5 3 4.6 10 10 (e*) 21 12 11.5 13.5 23.5 35.5 28 24 18.5 10.5 15.5 14 15 18.5 55 (eP) 26 29 1 16 9 4 25.5 23.5 7 5.5 2.5 5 13 35 Sa-Si 2.5 2 5 0.3 0.5 6 33.5 1 2 0.8 0.3 0.4 1 55.2 4.7 12 10A (e?) 5.5 5.5 9 2 11.5 4 15.5 9.5 3 2 1 5 4 9 1.5 12 2.5 3 18 1.5 7 2.5 2 1 4 5.5 31 (ep) 42.5 0.5 11 12.5 53.5 6.5 3.5 2 5.5 4 3.5 7.5 6.5 16 1.5 3 3.5 7.5 1 23 4.5 31 14 11.5 57 The ratios of the three different members change markedly from core to core, across the Algero- Balearic Basin. These changes correlate roughly with water depth. This is schematically represented in Figure 7, where the proportions of the different sediment types (B) are plotted along a bathymetric profile (A) from station 7 to station 10A. In cores at greater depth (8 to 10) the proportion of type A mud is more than 50 percent. In cores at shal- lower depths (7 and 10A) the percentage of type B mud is more than half (Table 2). Another possible correlation is to be noted, viz., between lithology and access to fluvial sediment sources. Cores 8, 8A, 9, and 9A occupy positions north of the important oueds on the margin of North Africa (Figure 1). COLOR OF SEDIMENT The sand-silt turbidites, when terrigenous in composition, are olive gray (5Y 4/1) in color. Bio- clastic layers are yellowish gray (5Y 7/2). Type A mud is light olive gray (5Y 5/2) to dusty yellow (5Y 6/4), whereas type B mud is somewhat lighter in color, namely, light olive gray (5Y 6/1) to yel- lowish gray (5Y 7/2). Color differences have been used to define mud layers (Bornhold and Pilkey, 1971; Davies, 1968; Fleischer, 1972; and others). NUMBER 13 10 A 10 9A 8A 11 2? 5?' n Dating Sample lOpelagic Mud Mud JTurbiditicSand-Silt] 5,000 year Isochrons FIGURE 6.?Distribution of rhythms (numbered on left side of cores) consisting of turbidite sand-silt layers and two kinds of mud layers, type A (interpreted as turbiditic) and type B (interpreted as hemipelagic) in seven cores from the Balearic Abyssal Plain. Spacing between these cores corresponds to the distances between their respective locations. The position and extent of samples for radiocarbon dating and the corresponding ages are indicated. Isochrons are drawn between the cores, based on a calculation of the hemipelagic rate of sedimentation. Note that in core 10 the radiocarbon dates are determined not on type B muds (interpreted as hemipelagic), but on resedimented turbidite sands, causing a dicrepancy between these dates and the ages indicated by the isochrons. However, a comparison of color logs with X- radiography data shows that color is not a reliable boundary criterion. Color changes in the cores often do not coincide with layer boundaries, partic- ularly the boundaries between type A and type B layers. The boundary area can display mottling or can be uniform in color. A distinct color change is present within the type A mud member, some 15 cm below its boundary with type B mud in rhythm 18 of core 8A (Figure 3). Such discrepancies may be the result of burrowing activity. Analysis of Rhythms GENERAL Eight individual rhythms were selected from six of the cores (7, 8, 8A, 9A, 10, 10A) for detailed sampling and analysis. The main purpose of the analysis was to establish and to contrast the prop- erties of mud types A and B in order to gain insight into their mode of origin. The rhythms are labeled by the number of the core and the number of the rhythm within that core. The following rhythms 12 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES 100 100 km B 50- (hemi)pelagic mud 10 A 10 9A 7 FIGURE 7.-?A, An east-west schematic bathymetric profile across the Balearic Abyssal Plain from station 7 to 10A. B, Proportions of total turbidite sand-silt (black), total type A mud (hatched; interpreted as turbiditic), and total type B mud (white; interpreted as hemipelagic). Note the rough correlation between water depth and proportion of turbidite sand-silt-mud. were selected: 7-11, 8-7, 8A-11, 8A-18, 9A-7, 10-5, 10-12, and 10A-19. The rhythms were selected so as to represent variety in terms of spread between the cores, spread within the cores, thickness of the rhythms, thickness of the rhythm members, and type of rhythm. The thickness of the sampled rhythms ranges from 11.5 cm (8A-11) to 49 cm (7-11); the average thickness is 29 cm. The average thickness of type A mud layers is 13 cm and that of type B layers 10 cm (Table 3). All four types of rhythms (Figure 5) are represented. Two have a thick type A mud member (8A-18, 9A-7), and one has a thick type B mud member (7-11) (Table 3). TABLE 3.?Thickness (in cm) of eight individual rhythms of sand-silt inrbidites, type A (eJ) and type B (ei}) muds, which were selected for detailed sampling and analysis Core no. 7 8 8A 8A 9A 10 10 10A Rhythm no. 11 7 11 18 7 5 12 19 Average thickness Sa-Si 0.2 8.5 1.5 14 0 8.5 11 0.5 5.7 A(e') 5 17.5 10 21 21.5 10.5 11.5 9.5 13 B (ep) 44.5 8 0 7.5 5.5 7 1 6.5 10 Toial 49.2 34 11.5 42.5 27 26 23.5 16.5 28.8 ANALYTICAL PROCEDURES Samples were taken from the split-core halves. The sample thickness ranges from 3 to 8 mm. The distance between samples varies from 0.5 to 8 cm. A total of 59 samples has been analyzed. For the sttidy of clay mineralogy, four extra samples were selected. The selection of exact sample points was based on the structural and textural details provided by the X-radiographs of the rhythms. The advantage of this sampling technique is that no subtle changes in sediment structure or texture were overlooked. It also makes possible a more precise correlation between the sedimentary structures of the sediment sections and the results of the textural and compo- sitional analyses. The following analytical procedures were car- ried out on all samples: (1) a grain-size determi- nation by pipette analysis; (2) a determination of carbonate percentage by gravimetric ascarite ab- sorption; (3) a compositional analysis of the sand fraction of all samples by grain-mount counting; (4) a study of the overall composition, and in par- ticular of the clay mineralogy, by X-ray difrractom- etry and peak-height analysis. The results are presented for each rhythm separately (Figures 8-15). Each figure is composed of five columns, the first of which provides the sedimentary structures (Bouma divisions) based on the X-radiographs. In this column the lower mem- n 0> 3 cT rain Size Distrib y?. Q Carbonate Content lomposition of Sand O O CD r-t- 9> o o o Q. Co 7-11 Clay Mineral Ratios 40- 7- 6- 30- 5- 20- 10- 3- 0J 2- 1- 30 6 0 9 0?/oO 30 60?/o 0 30 60 90% \i i 00 o 5 w o rr o" 1 \ w\ \ oo CD cn VCD FIGURIS 8-15?Diagrammatic summaries of the sedimentary structures and textural and com- positional properties of eight rhythms from six cores from the Balearic Abyssal Plain. The coarse-grained material in the top part of rhythm 8A-11 may be due to burrowing from above rather than representing a separate type B mud layer. Sample numbers marked with "a" and "b" were used only in the study of clay mineralogy. 14 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES n co 30- 20- 10- O- omposition of Sand TJ ? o o <* C Grain Size Distrib Clay Mineral Ratios Carbonate Content Mica3-.-.-.piants 30 6 0 9 0%0 30 60% 0 JO 60 90% FIGURE 9. ber of each rhythm (turbidite sand-silt layer or silt lamina) is indicated by Bouma divisions b, c, and d, while in anticipation of their genetic inter- pretation the middle (type A mud) and upper member (type B mud) are indicated by e1 and e" respectively. In the three following columns, sample points have been connected by straight lines, except where they lie on both sides of the mud A-B bound- ary. Where in X-radiographs this boundary is clearly denned, the lines are extrapolated from above and below and display the changes of texture and composition in the boundary region. NUMBER 13 15 GRAIN-SIZE DISTRIBUTION The grain-size distribution of the eight rhythms has been determined by pipette analysis. Measure- ments were taken at 1 phi intervals, between 4 phi and 9 phi (63 and 2 microns respectively). Type A mud contains less than 1 percent sand; thus, no size analysis of the coarser than 4 phi fraction was made. The terms "sand," "silt," and "clay" are used as grain-size terms without any compositional connotation. The results are grouped and plotted in two different ways. (1) The percentages of sand (larger than 63 micron), silt, and clay (smaller than 2 micron) (Table 4) are plotted against sample point positions within rhythms (Figures 8-15). These percentages also are plotted for all samples on a ternary sand-silt-clay diagram (Figure 16). (2) The data are plotted as cumulative curves to show grain-size distribution on logarithmic prob- ability paper (Figure 17). AD 1.?The coarse-grained, sand-silt turbidites in rhythms 8-7 (Figure 9), 8A-18 (Figure 11), 10-5 (Figure 13), and 10-12 (Figure 14) exhibit distinct fining-upward grading. The grading is reflected by an upward decrease of sand-size material and an increase in silt- and clay-size particles. Eriksson (1965), in an extremely detailed exami- nation of core 210 of the Swedish Deep-Sea Expedi- tion, located approximately 20 km to the west of core 10 of this study (Figure 1), found two types of sand-silt turbidites. One type, with a high percentage of bioclastic material, is distinctly graded. The second type, with a high percentage of terrigenous material, has less developed grading. However, this difference between the sand-silt tur- TABLE 4.?Percentages of sand-, silt-, and rhythms analyzed (samples are identified sample number, respectively) clay-size material in samples from eight by core number, rhythm number, and Sample no. 7-11-1 2 3 4 5 6 7 8 8-7-1 2 3 4 5 6 7 8 9 8A-11-1 2 3 4 5 8A-18-1 2 3 4 5 6 7 8 Sand 3 1 5 6 4 5 6 7 55 32 13 1 - - - 11 16 2 - - - 1 77 41 40 4 2 - - - Silt 52 46 43 42 46 43 43 49 39 62 68 54 51 41 40 38 31 76 55 38 34 47 18 53 54 89 75 69 46 38 Clay 45 53 52 52 50 52 51 44 6 6 19 45 49 59 60 51 53 22 45 62 66 52 5 6 6 7 23 31 54 62 Sample no. 8A-18-9 10 11 9A-7-1 2 3 4 5 6 7 10-5-1 2 3 4 5 6 9 10-12-1 2 3 4 5 6 7 10A-19-1 2 3 4 5 Sand 1 12 13 - - 1 - - 6 9 71 35 26 3 - - 8 69 39 25 9 - - 9 1 - - 6 11 Silt 42 33 30 59 51 52 47 41 45 43 23 53 57 82 51 36 45 18 51 52 77 41 34 36 63 46 43 43 44 Clay 57 55 57 41 49 47 53 59 49 48 6 12 17 15 49 64 47 13 10 23 14 59 66 55 36 54 57 51 45 16 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES Composition of Sand Clay Mineral Ratios Grain Size Distrib Carbonate Content 30 60 9 0%0 30 60?/. CD CD CD FIGURE 10. bidites of largely terrigenous rhythms (8-7 and 8A- 18) and largely bioclastic rhythms (10-5 and 10-12) is not observed. Interestingly, the upper laminated division d shows a marked increase in the proportion of silt- size material. In the instance of rhythm 10-12, there is even a decrease in clay from the current ripple division c to division d. Type A mud layers show a distinct fining-upward grading as well. The grading consists of an upward decrease of silt and an increase of clay. The shift in the silt-clay proportion can amount to as much as 20 percent. Most importantly, the grading of type A mud layers follows in regular fashion the grading of the underlying sand-silt turbidites or silt laminae. The sand-size fraction of type A mud is too low (less than 1 percent) to be plotted in the figures. Type B mud layers exhibit no grading or, if any- thing, a slight coarsening-upward grading. A distinct granulometric difference exists be- tween type A and type B mud layers. The former contain, little, if any, sand, maximally 0.62 percent, with an average of 0.2 percent. The latter, how- ever, contain a sizable amount of sand-grade mate- rial, maximally 16 percent, minimally 4 percent, with an average of 8 percent (Table 4; Figures 8-15). This sand is not graded as is that of the turbidite sand layers. In addition, type B mud lay- ers show a lower amount of clay and, in some instances, an increase in silt content, as compared to the underlying uppermost part of type A mud layers. The granulometric change across the boundary between type A and type B mud members can be sharp. Where the change is not abrupt, the bound- ary area is mottled and can show other signs of bioturbation. The absence of a systematic, fining-upward grading in type B mud layers is shown and under- scored by rhythm 7-11, in which type B mud is sampled over a thickness of 44.5 cm (Figure 8). The grain-size characteristics of mud types A and B are difficult to compare with Eriksson's analysis of the fine-grained layers in core 210. Eriksson divides the fine-grained layers in several groups, based on the type of material present and particularly on what he interprets as wind-borne components. However, in the diagrammatic repre- sentation of his results, several rhythms as found in our cores can be recognized. Grading in mud layers following on top of sand-silt turbidites or silt laminae occurs. Also, on top of graded mud layers, muds with a higher sand percentage are NUMBER 13 17 OCD 40- 30- 20- 10 0- 3 CD z o 11- 10- 9b- 9a- 9- 7 ? 6- 5- 4- n _ 2- 1- d c omposition of Sand Grain Size Distrib. Carbonate Content 8A-18 Clay Mineral Ratios Ul 00 >o 7^ CO o .IU| OJ U1 >o o lorite 00 Ul 00 >o orr o r-t- Afr\ >o 1 1 r-t- CD ? 1 / 00 Ul 00 CO o ini r-t- cp^ CDUl >o i?i ? r-t- CD- 10 6 0 -9 0o/<,0 60% 0 30 60 90% FIGURE 11. 18 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES 5CD Grain Size Distrib 20- 10- 0J 4- 3- 2- 1- cn n Carbonate Content 9A-7 Clay Mineral Ratios 0 30 6 0 9 0%0 60% 0 omposition of Sand CO CO CO ijl Ol 01 i co oo oo FIGURE 12. indicated (cf., Eriksson, 1965, pi. 6, between depths of 484 and 443.5 cm in core 210). The sand-silt-clay proportions of all 59 samples are plotted in a ternary diagram (Figure 16). A textural classification of the different rhythm mem- bers can be made, using the textural designations proposed by Folk (1961). The turbidite sand-silt layers, comprising the largest textural variety, in- clude silt, sandy silt, silty sand, and, in one instance, muddy sand. The type A mud layers classify strictly as mud. The type B mud layers can be mud or sandy mud. The diagram also shows differences in sorting be- tween the three rhythm members. The turbidite sand-silt layers are the least sorted, whereas type A mud is the best sorted. Importantly, the diagram illustrates that the three rhythm members, defined primarily from X-radiographs, can also be recog- nized on the basis of textural analysis. AD 2.?The cumulative grain-size curves (Figure 17) show even more distinctly the grading in the sand-silt turbidites. The lower, coarser grained part of the sand-silt layers exhibits coarse tail grading (the coarsest percentiles of the size distribution NUMBER 13 19 10- 0J "O CD zo 5- 4- 3- 2- 1- Grain Size Distrib o CD Carbonate Content Composition of Sand in -" n Co 3 CD ~D_ 20- 10- 0- 7- 6a- 6- 5- 4- 3- 2- 1- < ? lam b Gram Size Distrib Carbonate Content Composition of Sand O O(D CO Co(Q n' ~O CD iMica 10-5 Clay Mineral Ratios ui CJI en W0DC0 >? >o>o n ^ T^ 30 60 9 0%0 30 60% 0 30 60 90% FIGURE 14. detailed in Table 5 and depicted in Figures 8-15. The turbidite sand-silt layers have the highest average carbonate content (40 percent) and the widest spread of values (from 21 to 74 percent). The overlying type A mud layers have the lowest average carbonate content (28 percent) and an intermediate spread (from 16 to 39 percent). The type B mud layers on top have an intermediate average carbonate content (35 percent) and the narrowest spread (from 26 to 46 percent). In general, the carbonate content decreases with decreasing grain size. Within the sand-silt turbid- ites the carbonate percentage shows an upward decrease. In some of the type A mud layers, for example those of rhythm 9A-7 and 10-12, the car- bonate content shows also an upward decrease by as much as 6 percent. As such, the A muds are not only texturally graded, but also compositionally. This compositional grading follows that of the underlying sand-silt turbidites. The continuity from sand-silt turbidites to type A mud layers above them is illustrated by the fact that where the former are low in carbonate content the latter are proportionally low as well (8-7, 8A-18), and the reverse (10-5, 10-12). The car- bonate content of the type B mud layers above NUMBER 13 21 =;(/) Co n E. 3 3 CD T3_ CD 20- 10- 0J o i? 5- 4- 3- 2- 1- Carbonate Content Grain Size Distrib Composition of Sand 10-12 Clay Mineral Ratios ui en en U) 00 00 30 60 90% these does not change and is independent of that of the underlying rhythm members. The carbonate content of the type B layers is relatively constant. An abrupt change occurs across the boundary, where the underlying type A muds have a low carbonate content. The carbonate materials are almost entirely biogenic in origin (see following section). Based on the carbonate content as an indication of the amount of biogenic components, the sand-silt tur- bidites fall into two classes, terrigenous (8-7, 8A-18) and biogenic (10-5, 10-12). The type A muds can be clayey muds (8-7, 8A-11, 8A-15) or marl muds (10-5, 10-12, 10A-19). The type A muds of rhythm 7-11 and 9A-7 are somewhat inter- mediate between terrigenous and biogenic types. Type B muds classify as marl oozes. Classification as used here follows that of the Initial Reports of the Deep Sea Drilling Project (Ryan, Hsu, et al., 1973c), and is modified after Olausson (1960). Although only a few rhythms have been exam- ined, it appears that the carbonate admixture of the sand-silt turbidites and the type A muds increases toward the west across the Balearic Abyssal Plain, i.e., from core 8 across the Balearic Abyssal Plain to core 10 and 10A. COMPOSITION OF THE SAND FRACTION The larger than 63-micron fraction was obtained for all samples by wet sieving. Grain mounts were prepared for identification of the constituents and for determination of their relative frequencies. Relative frequencies were determined by counting 22 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES 300 to 400 grains per mount. Due to the very small percentage of sand-grade material in the samples from type A mud layers, no technique of point counting could be practiced. Instead, all grains per unit area were counted. As a result, bioclastic par- ticles of large size (e.g., pteropod shells of low effective density) are relatively underrepresented as compared to smaller particles (e.g., quartz grains of high effective density). Constituents were counted and grouped in the following classes: terrigenous (mica and other, in- cluding quartz), bioclastic remains (pelagic forams, benthonic forams, pteropods, and other), plant fragments, and other (including ostracode valves, sponge spicules, unidentifiable fragments, etc.). The results are given in Table 6 and Figures 8-15, 18, and 19. TABLE 5.?Carbonate percentages for samples from eight rhythms studied (samples are identified by core number, rhythm number, and sample number, respectively) Sample no. 7-11-1 2 3 4 5 6 7 8 8-7-1 2 3 4 5 6 7 8 9 8A-11-1 2 3 4 5 8A-18-1 2 3 4 5 6 7 8 CaCO3 % 28 25 28 28 26 28 28 29 33 24 25 21 22 21 22 40 46 25 22 20 22 22 38 23 25 22 21 18 16 17 Sample no. 8A-18-9 10 11 9A-7-1 2 3 4 5 6 7 10-5-1 2 3 4 5 6 7 10-I2-I 2 3 4 5 6 7 10A-19-1 2 3 4 5 CaCOs % 18 35 36 39 37 38 33 32 32 37 74 55 50 49 39 37 38 60 - _ 43 38 35 43 39 38 38 35 43 The widest variety of constituents occurs in the turbidite sand-silt layers. The terrigenous compo- nents are mainly quartz, mica, and feldspars. A wide spectrum of foram tests, both pelagic and benthonic, is represented by their microskeletal remains. Other organic remains include those of pteropods, crinoids, ostracods, sponges, and plants. A few siliceous remains from radiolarians and dia- toms also occur. Glauconite is present as well. This association of microfossil and other organic remains is typical for resedimented deposits con- taining biogenic remains from various environ- ments (terrestrial, neritic benthonic, bathyal or abyssal benthonic, and pelagic) (Parker, 1958). The constituents are very poorly sorted, and the shelly remains commonly are broken (Figure 18A,C). The constituents of type A mud layers are largely the same as those of the underlying sand-silt tur- bidites; the individual specimens of each constit- uent, however, are markedly smaller on the average in the type A mud layers. In the top part of these layers, large Orbulina specimens can be found. Their sizes are quite uniform (well sorted), and the foram tests are only slightly larger than the quartz grains. Fecal pellets and remnants of pyritized burrow tubes occur in type A layers as well, particularly near the boundary with the overlying type B layers. Type B layers can contain quartz, mica, and feldspar, though in small proportions. The organic remains show less variety. Skeletons of pelagic forams and pteropods form the main constituents. Among the rest are sponge spicules, radiolarian, diatomaceous, and crinoid fragments. The spread of particle sizes is wide (very poor sorting) (Figure 18B,D). The quartz grains in the three types of layers often are of the so-called desert type, i.e., rounded and stained, or frosted (Eriksson 1965). In the turbidite sand-silt layers, concentrations of different constituents are associated with specific sedimentary structures (Figures 8-15). For example, the mica flakes and plant fragments occur most frequently in the d-division. This indicates that the relative frequencies of the components are deter- mined to a large degree by their hydrodynamic properties. Vertical sorting appears to have taken place according to the effective densities of the components. Light, large, nonspherically (oblately) shaped particles are therefore concentrated in the NUMBER 13 SAND 5(5) : sand(sandy) Z(z) : silt(silty) M(m): mucKmuddy) ? turbidite sand-silt ? turbidite mud (hemi)pelagic mud mixed CLAY SILT FIGURE 16.?Ternary diagram in which are plotted the sand-silt-clay proportions of all samples of eight studied rhythms. Different symbols show turbidite sand-silt layers, type A mud layers (interpreted as turbiditic), and type B mud layers (interpreted as hemipelagic). The mixed samples are from boundary regions between two rhythm members. d-division, while smaller, but spherical, particles of higher effective densities occur in the lower structural divisions. This phenomenon of vertical sorting of different components according to their hydrodynamic prop- erties continues without a break from the turbid- ite silt layers into the type A mud layers. Mica flakes and plant fragments remain relatively fre- quent in the lower part of type A muds. In the upper half of these layers, tests of pelagic forams occur in high relative frequency. The forams exhibit a small size range (well sorted) (Figure 18E), and the size of the few associated quartz grains is consistently somewhat smaller. An abrupt change in relative proportions occurs across the boundary into type B muds (Figure 19). The constituents are mainly remains of pelagic forams and pteropods (Figure 18B.,D). Mica and a few other terrigenous particles are present as well. The mica content increases somewhat, as do the pteropod shells. Pelagic foram tests, on the other hand, decrease relatively. Plant fragments are virtually absent (Figure 19). Within the type B mud layers no systematic change in proportions or constituents occurs, and apparently no hydro- dynamic sorting effective on the sea floor has influenced their sand composition. The compo- nents are of widely varying sizes (very poorly sorted) (Figure 18B,D). The composition of sand-grade material in terrigenous sand-silt turbidites and type A mud layers differs from sands in bioclastic layers in that the former have significant proportions of plant remains and a higher proportion of terrigenous 24 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES C u ?_ Z3 E u _ 95 _ 84 _ 75 _ 50 _ 25 _ 16 _ 5 9A-7 99-98 ?I 1 1 1 1 1?QO63 0012 0D04 mm 0031 0.008 QD02 Sand-Silt Mud Turbiditic (Hemi)pelagic Mud 002 6 7 8 9 Diameter in 0 Units FIGURE 17.?Cumulative grain-size curves for all samples from the eight studied rhythms. Dif- ferent lines are used for samples from turbidite sand-silt layers, type A mud layers (interpreted as turbiditic), and type B muds (interpreted as hcmipelagic). Sample numbers arc indicated on the curves. NUMBER 13 25 FIGURE 18.?Photomicrographs of the coarser than 63 micron fraction of turbidite sand layers (A, C), and type B mud layers (B, D). The corresponding sample numbers from A to D are: 8-7-1, 8-7-9, 10-5-1, and 10-5-7. E = forams in sample 10-5-6. F = pyritized filament in sample 9A-7-4. The white lines (on background) form squares that measure 3.7 by 3.7 mm. 26 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES TABLE 6.?Percentages of the different components, comprising the sand-size fraction of eight rhythms studied (samples are identified by core number, rhythm number, and sample number, respectively) Sample no. 7-11-1 2 3 4 5 6 7 8 8-7-1 2 3 4 5 6 7 8 9 8A-11-1 2 3 4 5 8A-18-1 2 3 4 5 8A-18-6 7 8 9 10 11 9A-7-1 2 3 4 5 6 7 10-5-1 2 3 4 5 6 7 10-12-1 2 3 Terrigenous Mica 8 12 7 8 4 5 5 9 80 73 45 6 30 71 7 - 1 16 10 3 3 8 - - 16 33 31 36 6 - - - - 30 10 - - - * - 5 4 11 24 2 - 5 4 6 6 Other 25 23 25 13 8 11 13 24 5 6 15 44 24 4 - - - 4 5 61 15 2 83 82 65 41 13 6 34 8 5 3 3 7 43 48 30 29 22 24 18 11 5 1 32 4 13 19 2 1 Pelagic forams 43 50 29 37 48 54 43 48 11 13 21 17 16 14 89 35 38 41 53 25 74 84 6 9 10 14 21 21 50 89 93 53 45 42 43 47 68 70 54 51 53 58 70 57 51 90 55 60 63 62 Benthonic forams 3 2 1 1 1 1 1 _ - - - - - - - 2 2 7 1 - - - 1 - - - - - - - - 1 1 1 1 - - - - - 2 3 2 _ 1 - 1 - 2 3 Pteropods 1 1 27 34 33 24 28 15 3 3 6 - - 1 1 55 54 13 3 - - 4 2 2 2 2 2 - - - - 32 40 5 2 _ _ _ 18 19 4 9 4 4 1 3 22 13 19 20 Plants - - - - - - - - - - 12 30 29 5 1 - - 8 26 7 7 1 - - - - 15 19 - - - - - 8 - - - - - - - - - - - - _ - - _ Other 20 12 11 7 6 5 10 4 1 5 1 3 1 5 2 8 5 11 2 4 1 1 8 7 7 10 18 18 10 3 2 11 11 7 1 5 2 1 6 6 18 15 8 14 13 3 4 4 8 8 NUMBER 13 27 TABLE 6.?Continued Sample no. 4 5 6 7 10A-19-1 2 3 4 5 Terrigenous Mica 20 14 - - 8 4 1 4 3 Other 6 6 3 3 1 13 22 10 9 Pelagic forams 57 67 94 93 54 51 59 54 53 Benthonic forams 1 1 - - 1 1 1 1 - Pteropods Plants 5 6 - - - - 1 1 1 20 22 Other 11 6 3 4 35 30 16 11 13 constituents such as quartz and mica. The virtual absence of plant remains in bioclastic turbidites in the Caribbean has been reported by Rusnak and Nesteroff (1964). Figure 19 summarizes the average relative fre- quencies of the sand constituents as distributed through the eight terrigenous and bioclastic rhythms examined in this study. The boundary between the lower coarse-grained member and type A mud is markedly different from the one between o ^O 02Z> ep d c b ABSOLUTE % 3= OF SAND V i TERRIGENOUS OTHER P""^^^^^^^^^BBi^^^^^^| m MICA I 1 BIOGENOUS PLANT REMAINS iV PTEROPODS H^H| o p I o BENTHONIC FORAMS 0 30 60% FIGURE 19.?Summary diagram showing the relative fre- quencies of the major constituents in the sand-size fraction of the eight rhythms studied. The columns for mica and plant fragments are typical for terrigenous turbidites and type A muds (interpreted as turbiditic, or e*). mud types A and B. Across the former boundary, a continuity of components and their gradually changing proportions is noted. Across the latter an abrupt change occurs, most clearly indicated by a small increase in mica, a decrease in pelagic foram tests, and an increase in pteropod shells. It should be emphasized that these changes as schematically depicted are changes in relative frequencies, not necessarily in absolute numbers. For example, the relative frequency of pelagic foram tests is shown to decrease, although the absolute number, in fact, increases due to the much higher percentage of sand (indicated in the second column of Figure 19). In contrast, Weidmann (1967) in a similar diagram schematically illus- trates a relative increase in pelagic foram tests in the top layer. An absolute increase in the number of foram and pteropod remains in the top part of fine- grained layers following turbidite sand-silt layers has also been described by Nesteroff (1961), Nesteroff and Heezen (1963), and Rusnak and Nesteroff (1964). CLAY MINERALOGY The samples were mineralogically analyzed by X-ray diffractometry. The instrument used was a Noralco (Philips) unit, with Cu K-alpha radiation and Ni filter. Slides were prepared from grain-size fractions separated by the pipette method. Both the finer than 4 phi and the finer than 9 phi fractions were used. Some slides were glycolated (overnight in glycol vapor). The minerals present are: quartz, calcite, dolo- mite, kaolinite, chlorite, illite, plagioclase, K- 28 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES feldspar, and montmorillonite (not always in this order of relative abundance). The latter mineral forms no distinct peak. In the finer than 9 phi fraction the dolomite is absent and feldspars in most instances are not observed. These minerals are present in all rhythms but in varying proportions. The major clay minerals are illite, chlorite, and kaolinite; montmorillonite, detected by glycolation, is present in minor quantities. This confirms earlier studies of clay mineralogy in the western Mediter- ranean by Nesteroff, Sabatier, and Heezen (1965). A study of the relative abundances of the three clay minerals was made by an analysis of peak heights. The peaks used are for illite: d-4.95, for chlorite: cl-3.53, and for kaolinite: d-3.58. All samples exhibit these peaks quite distinctly, and TABLE 7.?Peak-height ratios of C (chlorite, d-3.53 A), I (illite, d-4.95 A), and K (kaolinite, d-3.58 A), for samples from eight rhythms analyzed (sam- ples are identified by core number, rhythm number, and sample number, respectively) Sample no. 7-11-1 2 3 4 5 6 7 8 8-7-1 2 3 4 5 6 7 8 9 8A-11-1 2 3 4 5 8A-18-1 2 3 4 5 6 7 C/I 1.0 1.1 1.1 1.1 0.8 1.3 0.9 1.0 2.0 2.2 1.4 2.2 1.8 1.4 1.4 1.6 1.4 1.6 1.6 1.8 1.5 1.5 1.5 1.9 1.8 1.7 1.9 2.6 2.5 K/I 2.5 3.3 2.3 2.3 2.4 3.1 2.4 1.8 2.7 2.7 2.1 2.6 2.2 1.8 2.5 1.6 2.1 2.1 2.1 2.4 2.0 2.2 2.4 2.4 2.3 2.8 2.7 3.3 3.9 K/C 2.6 3.0 2.1 2.1 2.9 2.5 2.6 1.8 1.4 1.2 1.5 1.1 1.3 1.3 1.7 1.0 1.5 1.3 1.3 .3 1.3 .5 .6 1.3 1.3 1.7 1.4 1.3 1.6 Sample no. 8A-18-8 9 9a 9b 10 11 9A-1-1 2 3 4 5 5a 6 7 10-5-4 5 6 6a 7 10-12-4 5 6 7 10A-19-1 2 3 4 5 C/I 2.2 2.1 2.3 1.0 1.1 1.1 0.6 0.6 0.6 0.7 0.7 I.I 1.7 1.2 1.0 0.8 0.8 1.1 0.9 0.9 0.9 1.0 1.1 0.9 1.0 0.9 0.7 1.2 K/I 3.3 3.2 3.1 2.0 2.3 2.4 0.7 0.6 0.5 0.6 0.5 1.1 2.9 1.2 0.8 0.7 0.6 1.1 0.8 0.7 0.7 0.9 1.5 0.8 0.8 0.7 0.7 0.8 K/C 1.5 1.5 1.4 2.0 2.1 2.3 1.1 1.0 1.0 0.9 0.8 1.1 1.6 0.9 0.9 0.8 0.8 1.1 0.9 0.8 0.8 0.9 1.4 1.0 0.8 0.8 1.0 0.7 the kaolinite and chlorite peaks can be easily dis- tinguished with a rotation of one-half degree (2 theta) per minute (Figure 20). The results are listed in Table 7. The peak-height ratios have been plotted against the sample points for each rhythm (Figures 8-15). The ratios are, in most instances, different for the type A and type B muds of a particular rhythm. A sharp break in the curves of the clay-mineral ratios can occur at the boundary between the two kinds of mud. This mineralogical change is particularly no- ticeable in rhythms 8A-18 and 9A-7. Extra samples were taken as near to the boundary as possible to verify the abruptness of the change (samples marked by a or b). The change in illite, kaolinite, and chlorite peaks between the two samples on either side of the boundary of rhythm 9A-7 is illustrated in Figure 20. The change of clay ratios from type A into type B muds is most pronounced where the A muds are terrigenous (8-7, 8A-18, 9A-7) and less so where they are bioclastic (10-5, 10-12, 10A-19). The clay- mineral suites of terrigenous A mud, bioclastic A mud, and of type B mud show each a rough uniformity. The proportion of clay minerals is different in each mud type. Discussion TYPES OF DEPOSITIONAL MECHANISMS There is evidence for several depositional mechanisms operating in the abyssal environment of the western Mediterranean: 1. Normal, pelagic settling of terrigenous par- ticles introduced by rivers and wind, and of marine microskeietons. Fine-grained sediment lay- ers in cores from the Algero-Balearic Basin have been attributed to this process (Eriksson, 1965; Leclaire, 1972a, 1972b). 2. Turbidity currents transporting dominantly terrigenous materials from shallower environments onto the abyssal plain. Coarse-grained turbidites have been identified in a number of cores from the Balearic Abyssal Plain (Horn, Ewing, and Ewing, 1972). 3. Normal bottom currents of various types, eroding, transporting, and redistributing sediments on the sea floor. The lower section of the Balearic Basin fill, as recovered at JOIDES drilling site 124, NUMBER 13 29 FIGURE 20.?Peaks from X-ray diffractograms of 4.95 A illite (I), 3.58 A kaolinite (K), and 3.53 A chlorite, illustrating sharpness of peaks and change in peak-height ratios from sample 9A-7-5 (type A mud) to 9A-7-6 (type B mud). is attributed to the redepositing activity of contour- type currents ( Nesteroff, 1973). Strong bottom water movement is noted in shallow straits at the basin margin (Strait of Sicily and Gibraltar region; Lacombe, 1971; Kelling and Stanley, 1972a,b). On the other hand there is little direct evidence available in support of well-defined bottom cur- rents, although physical oceanographic data suggest the westerly movement of potentially active but transient bottom currents in the region off North Africa and the Balearic-southeastern Iberian plat- form (Miller, 1972). 4. Certain types of low density, gravity-assisted currents transporting largely terrigenous clay-size particles down the continental slope-rise. Muds in the Alboran Sea are attributed to this mechanism (Bartolini and Gehin, 1970; Stanley, Gehin, and Bartolini, 1970; Huang and Stanley, 1972). 30 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES MUD DEPOSITION?GENERAL Nesteroff (1961; also Nesteroff and Heezen, 1963; and Rusnak and Nesteroff, 1964) describes the typical sequence of structures in oceanic turbidites, and the distribution of foram and pteropod skele- tons in these. His typical sequence ("sequence type") is quite similar to the type 1 rhythm of this study: a sand-silt layer is followed by a mud layer contain- ing very little sand-grade material, which in turn is followed by a layer of mud with a high concen- tration of foram test and pteropod shell material. The explanation offered is that the entire sequence formed by a turbidity current, the tail of which carried skeletal material of extremely low effective densities that became incorporated in the upper part of the deposit. Pelagic sediments are thought to have been eroded by turbidity currents. Kuenen (1964) interprets the upper layer of shell material as winnowed concentrates from a pelagic stratum by the turbidity current that deposited the covering turbidite, though in some instances it may repre- sent the pelagic stratum. From the foregoing analysis, however, it appears that type A and B mud layers formed from dif- ferent depositional mechanisms. The break in tex- ture and composition across the boundary between them excludes the explanation of continuous depo- sition from a turbidity current for both mud layers combined. Also the relatively high clay content and the poor sorting of the B muds exclude winnowing bottom currents as a mechanism. TURBIDITIC MUD DEPOSITION?TYPE A MUDS The assemblage of characteristics of the type A mud layers can be best explained by deposition from turbidity currents. The following features support this interpretation. STRUCTURAL.?On X-radiographs the lower por- tion of several type A mud layers exhibits delicate lamination (8A-11, 8A-18, 10-5, 10-12). As such, a structural continuity exists from the upper lami- nated d-division into type A mud layers (Figure 4). Normal pelagic settling does not produce lami- nation due to the continuous organogenic dis- turbance of the slowly accumulating particles. Laminations can form in stagnant water of which the lower portion has become anaerobic (van Straaten, 1967). The presence of benthonic life, however, is evident from burrow tubes. Bottom photographs also show that the modern plain sur- face is affected by the activity of animals (Heezen and Hollister, 1971). TEXTURAL.?Type A mud layers show distribu- tion grading following the coarse tail grading of the lower part of the sand-silt turbidites where these are present. Experiments indicate that coarse tail grading is produced by high density turbidity currents, whereas distribution grading results from relatively dilute flows (Middleton, 1967). Also, the sorting of type A muds is better developed than that of type B mud layers, which can be interpreted as the effect of hydrodynamic selection during cur- rent transportation. The fact that type A muds are poorly sorted nevertheless excludes normal bottom currents as depositional mechanism. Contourites, for example, exhibit good to very good sorting (Bouma, 1972a, 1972b). COMPOSITIONAL.?The carbonate content of some type A mud layers shows an upward decrease and, as such, a compositional grading which follows that of the underlying sand-silt turbidites where present. The overall carbonate content of type A muds varies with that of the underlying turbidite sand-silt layers. Such compositional grading as indicated by the carbonate content is documented as well for very thick turbidite marlstone layers following on top of very thick turbidite calcarenites in the Eocene frysch of the southwestern Pyrenees (Rupke, 1972). The individual components of the sand-grade fraction, in particular the mica and the plant particles, are concentrated in the upper d-division of the turbidite sand-silt layers and in the lower portion of the type A muds. This continuity of composition cannot be attributed to biogenic ho- mogenization of the boundary area, otherwise the delicate lamination would have been obliterated. In general, structural, textural, and composi- tional continuity from the sand-silt turbidites into the type A mud layers suggests that they formed from a single turbidity current. The genetic con- nection between coarse-grained turbidites and their overlying type A muds excludes permanent or semipermanent low-density suspension currents as the depositional mechanism of the type A muds, and indicates emplacement by the tail of a normal, high-density turbidity current (Kuenen, 1967). In short, type A muds are the turbiditic portion of the NUMBER 13 31 pelitic e-division, symbolized as ex (Figures 8-15). Where only thin silt laminae or lamels form the beginning of a rhythm, the type A mud layers are likely to be the distal portion of a turbidite body, deposited by the slowly moving, or ponded, less dense tail of a normal, high-density turbidity cur- rent. Such layers can be designated as mud turbidites. However, the depositional mechanism for mud turbidites can also be an originally low- density turbidity current, triggered, for example, by stirred up fine sediment on the shelf-break during storms (Stanley, 1969, 1970). Further evidence for deposition by gravity- propelled density currents of type A muds, rather than by normal pelagic settling, comes from the fact that the proportion of type A mud, as well as that of turbidite sand-silt, is higher in the cores from greater water depth (Figure 6). This is to be expected where turbidity currents seek the lowest parts of the basin plain. In contrast, the propor- tions of type B muds show an inverse relationship with the water depth of the cores. HEMIPELAGIC3 MUD DEPOSITION?-TYPE B MUDS The properties of type B mud layers fit best the depositional process of pelagic settling. Evidence for this comes from the following observations. STRUCTURAL.?All type B mud layers lack any kind of primary sedimentary structure, including fine lamination. Pelagic deepwater deposits do not become laminated due to the fact that the slowly accumulating particles are constantly being rear- ranged by benthonic organisms. Accordingly, burrowing structures are present in type B muds. TEXTURAL.?Type B muds exhibit no systematic changes in grain-size distribution. In addition, the grain-size distribution of all type B layers is vir- 3 We have opted for the term "hcmipclagic," as opposed to "pelagic," in describing the type B (ep) muds. Pelagic sedi- ments have been defined as "Deep-sea sediments without ter- rigenous material; they are either inorganic red clay or organic ooze" (AGI Glossary of Geology, 1972). Hemipelagic sediments are defined as "Deep-sea sediments containing a small amount of terrigenous material as well as remains of pelagic organisms" (AGI Glossary of Geology, 1972). Authors differ on the amount and si/e of terrigenous matter. Kuenen (1950) defines hemipelagic sediments as those with mainly pelagic but little terrigenous matter, while Kukal (1971) defines these as containing more than 20 percent of terrige- nous material of silt and sand grade. tually uniform throughout the basin area examined and is constant through time as well. This uniform- ity of type B mud layers is a typical feature of pelagic deposition and cannot be explained by other depositional processes. The high clay content and very poor sorting of the type B muds excludes any normal bottom current emplacement. COMPOSITIONAL.?The composition of the type B muds is typical of autochthonous deepwater ac- cumulations. The components of the coarser frac- tion are mainly from pelagic organisms, dominantly forams and pteropods. The shelly remains are largely unbroken and unworn, even the delicate pteropod skeletons. In addition, the composition of type B layers varies little from one to the other, unlike type A muds. The interpretation of type B muds as hemi- pelagic deposits is significantly strengthened by an analysis of radiocarbon dates determined on their carbonate sands. In summary, type B muds con- stitute the hemipelagic upper part of the pelitic 41,000 Carbonate sand sieved from Hemipelagic mud Hemipelagic mud Hemipelagic mud Hemipelagic mud Hemipelagic mud Hemipelagic mud Hemipelagic mud Turbidite sand Turbidite sand Hemipelagic mud Hemipelagic mud Hemipelagic mud NUMBER 13 I I ? ? AGE in 10 years 8 12 16 J 1 1 I I I I I I I I I 100 ? 200- 300 TOTAL SEDIMENT THICKNESS A THICKNESS OF (HEMI)PELAGIC LAYERS ONLY 400 ? FIGURK 21.?Graph of ten radiocarbon dates from carbonate sands of hemipelagic (type B mud) layers versus (1) total depth in the core of the respective layers (solid line), and (2) the com- bined thicknesses of hemipelagic mud layers only, omitting the turbiditic sections (dashed line). mud, silt, and sand-turbidite layers distributed irregularly throughout the cores examined (Figure 6). The virtually perfect correlation for the hemi- pelagic layers only is in accordance with a continuous pelagic settling process. The sedimen- tation rate for these layers is almost exactly the same in all cores throughout the Abyssal Plain. In contrast, the total sedimentation rate differs markedly from core to core. The following sedimentation rates are inferred from the plots in Figure 21: total sediment thick- ness, 23 cm/1000 years (this value is only an SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES average for all cores combined); hemipelagic sediment thickness, 10 cm/1000 years (virtually a constant value in all cores, confirming the inter- pretation of their hemipelagic origin). These rates correspond to 230 Bubnoff units and 100 B respec- tively (Fischer 1969). The core-to-core variation in sedimentation rates is illustrated in Figure 6, where 5000-year isochrons are drawn between the cores. These isochrons have been calculated based on the sedimentation rate for the hemipelagic lay- ers of 10 cm/1000 years. In core 10, the ages of the turbidite carbonates are much older than those indicated by the iso- chrons. This fits the theory that the sampled layers include much older materials that were redeposited by turbidity currents. By interpolation between the two turbidite dates, it is possible to calculate the following sedimentation rates: for the total sediment thickness, 33 cm/1000 years (331 B), and for the pelagic layers, 10 cm/1000 years (104 B). The latter value approximates the pelagic rate as determined from the other samples (Figure 21). The almost perfect correlation between age and depth (thickness) of the hemipelagic layers indi- cates that no significant erosion of these layers by bottom or turbidity currents has occurred. Little or no erosion by the turbidity currents is to be expected in a distal setting where the majority of the turbidity currents deposit mud turbidites. The negative intercept in the regression lines in Figure 21 could imply a reduction in sedimen- tation rate during the past several thousand years. Another possible explanation, however, is com- paction: with increasing depth, the compaction increases and the age-depth relationship changes from a straight to a curved line. In any case, it is known that total sedimentation rate in the western Mediterranean has not been constant during much of Quaternary time, due in large part to climatic and eustatic changes affecting the circum- Mediterranean region (Mars, 1963). Rates have decreased considerably since the end of the Pleistocene (Bartolini and Gehin, 1970; Leclaire, 1972a; Huang, Stanley, and Stuckenrath, 1972). The isochrons in Figure 6 show that, except for cores 8 and 8A, all cores extend backward from the postglacial (11,000 B.P., Leclaire, 1972a) into the Late Wiirm. Cores 8 and 8A, lying at the greatest water depths, display the highest overall sedimentation rate. The area which they occupy probably has had a greater access to sediments derived from the important oueds (Soummam, el Kebir, etc.) on the eastern Algerian margin; turbidity currents redeposit these materials down- slope, as they flow toward the deepest basin plain off western Sardinia. Turbidity currents have been triggered by earthquakes (Heezen and Ewing, 1955) and perhaps also by storms and phases of high-river discharge, as in the northern Balearic Basin (Gennesseaux, Guibout, and Lacombe, 1971). Although cores 7, 10, and 10A lie closer to the base of fans, the relatively low proportion of sand and mud turbidites suggest that they probably occupy sectors of the sea floor somewhat more shielded from sediment sources by topographic features such as levees (Figure 1). Other studies indicate that the average sedimen- tation rate for the upper 300 m of section (lower Pliocene-Pleistocene) at JOIDES site 124 is 9 cm/1000 years, and that of the Quaternary section at site 133 exceeds 13 cm/1000 years (Ryan, Hsu, et al., 1973b). Rates of 12 to 100 cm/1000 years are calculated for deposits at the base of the slope off Algeria (Leclaire, 1972a). However, the sedi- mentation rates of our study are of the same order of magnitude as those calculated by others for the Late Pleistocene-Holocene in the western Mediter- ranean in its deep parts. Gennesseaux and Thommeret (1968) calculate rates of 30 cm/1000 years in the northern part of the Balearic Basin. Eriksson (1965) puts the total sedimentation rate of core 210 southeast of our core 10A at 35 cm/1000 years, and he estimates the pelagic rate at between 14 cm to 29 cm/1000 years. The latter values are higher than ours, however, inasmuch as Eriksson was unable to make a precise distinc- tion between turbiditic and pelagic mud layers, and he included part of the former for his pelagic rate calculations. In the neighboring Alboran Sea, Vergnaud-Grazzini and Bartolini (1970) calculate rates of 26 to 30 cm/1000 years and Huang and Stanley (1972) calculate a rate of sedimentation during the past 10,000 years of 30 to 40 cm/1000 years in the basin plain and about 20 cm/1000 years on slopes. These somewhat higher rates reflect the closer proximity to the North African and Iberian Margin and greater access to sediments transported by turbidity currents and gravity- assisted flows; these studies also disregard the dis- NUMBER 13 35 tinction between turbiditic and pelagic muds. The frequency of turbidity currents has been calculated on the basis of radiocarbon ages and the isochrons computed with the aid of these. The average frequency is 3 turbidity currents per 2000 years; the turbidity current frequency differs greatly from core to core across the Algero-Balearic Basin. From core 7 to core 10A these frequencies number as follows: 12, 30, 30, 8, 18, 9, and 12 per 12,000 years. The average frequency of 3 turbidity currents per 2000 years applies to the seven local- ities examined within the Abyssal Plain. It should be pointed out that single turbidites were not correlated between cores, and it is unlikely that their individual beds extend over most of the basin floor covered by the cores. Thus, the 3 turbidites per 2000 years reflect different turbidity currents at widely separated core localities. In other words, the basin plain as a whole received considerably more than 3 incursions per 2000 years. In other basins, such as the middle of the San Pedro and Santa Monica basins off California, the frequency of turbidity currents is estimated at 1 every 400 years (Gorsline and Emery, 1959). Most other frequency estimates are significantly lower. In the Bahamas region, for instance, the frequency varies from 1 per 500 years to 1 per 10,000 years in the Tongue of the Ocean (Rusnak and Nesteroff, 1964), and I per 3000 to 6000 years in the Columbus Basin (Bornhold and Pilkey, 1971). Estimates for ancient flysch occurrences are 1 turbidite per 2000 years (Moore, 1971), or per 4000 years (Sujkowski, 1957). The much higher average turbidity current frequency in the Algero- Balearic Basin (more than 3 incursions per 2000 years) is in part based on the fact that mud turbi- dites can be recognized in this study. Conclusions 1. Sediment cores from the Algero-Balearic Abyssal Plain, western Mediterranean, contain large sections of mud, seemingly homogeneous. Use of X-radiographs of split cores enables the distinction between two different types of mud, and the recognition of a large number of mud layers, alternating in a regular fashion. 2. The color of the sediment is not a reliable criterion to distinguish between different mud layers and to determine their boundaries. 3. Structural, textural, and compositional prop- erties of the two mud types indicate that one type is deposited by turbidity currents, and the other by pelagic settling. Incidental reworking of hemi- pelagic muds by bottom currents has occurred. 4. Among the many properties of the turbiditic muds, the most characteristic are: structural, textural, and compositional continuity between underlying sand-silt turbidites and the muds, grading within the mud layers, and a very small amount of sand-size material (^ 1 percent). 5. The most distinctive properties of the hemi- pelagic muds are: they are entirely unlaminated, display exclusively burrow structures, a sizable amount of sand-size material is present (an aver- age of 8 percent), the coarse components are domi- nantly made up of pelagic foram tests and pteropod shells, their grain-size distribution is nearly normal with a median around 9 phi, they are very poorly sorted, and in general their properties are virtually uniform between muds from different sediment depths and core locations. 6. The boundary between the two mud types is most distinctly marked by changes in the amount of sand-grade material, the proportion of remains of pteropods and pelagic forams, and the propor- tion of mica. 7. When the mud turbidite is markedly ter- rigenous in composition, the ratios of illite, chlorite, and kaolinite differ between a turbiditic mud and the overlying hemipelagic mud. This observation is of consequence to studies of paleoclimatological change based on clay mineralogy. 8. The distinction between turbiditic and hemi- pelagic muds in the cores enables an accurate estimate of pelagic sedimentation rate from radio- carbon dates on pelagic carbonate sands. During the past 16,000 years this rate has been 10 cm/1000 years. 9. This distinction coupled with the radiocarbon dates also makes possible an accurate estimate of the frequency of turbidity current incursions in the Balearic Basin. The average frequency for the past 20,000 years or so has been 3 incursions per 2000 years in a particular core locality. The number for the basin as a whole should be higher. 10. The seven analyzed cores from across the southern Balearic Abyssal Plain show a facies of alternating sand-silt and silt turbidites, mud turbi- dites (locally more than half of the core section), 36 SMITHSONIAN CONTRIBUTIONS TO THE EARTH SCIENCES and hemipelagic muds (more than half in some cores). The two mud types have as yet not been dis- tinguished to this degree in ancient deep marine successions. Largely shaly or marly flysch facies are known, and these may bear some analogies with the muddy turbiditic-hemipelagic sequences of the southern Balearic Abyssal Plain examined in this study. Comparison of similar ancient and modern deepwater, mud-rich deposits warrants further analysis. Literature Cited Amende, J. M., J. Bonnin, and J. L. Olivet 1973. The Origin of the Western Mediterranean Basin. Journal of tlie Geological Society of London, 129: 607-620. Barazangi, M., and J. Dorman 1969. World Seismicity Maps Compiled from ESSA Coast and Geodetic Survey Epicenter Data 1961-1967. 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