Pedogenesis of Vesicular Horizons, Cima Volcanic Field, Mojave Desert, California

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DIVISION S-5—PEDOLOGY

Pedogenesis of Vesicular Horizons, Cima Volcanic Field, Mojave Desert, California

K. Anderson^*^,a, S. Wells^b and R. Graham^c

^a Box 6013, Bilby Research Center, Northern Arizona University, Flagstaff, AZ 86011
^b Desert Research Institute, 2215 Raggio Parkway, Reno, NV 89512
^c Dep. of Environmental Science, University of California, Riverside, CA 92521

* Corresponding author (kirk.anderson{at}nau.edu)

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
Radiocarbon Age Estimates
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

An existing model of desert pavement formation suggests desertpavement clasts rise vertically on an accreting eolian mantleand the underlying vesicular horizon coevolves with pavementformation. Results presented here support this model and providea mechanism whereby eolian material is transported from theground surface to ped interiors, thereby increasing the thicknessof the vesicular horizon underlying desert pavements. Basalticdesert pavements in the Cima Volcanic Field are underlain bya vesicular horizon with strong coarse columnar and strong mediumplaty soil structure. Peds collected from three sites alonga topographic gradient were subsampled into seven ped domainsto quantify physical, chemical, and micromorphological propertieswithin peds and along the topographic transect. Ped interiorshave up to 40% clay and 12% CaCO₃ whereas sediments adheringto ped sides have <7% clay and 2% CaCO₃. Argillans and siltanslining platy surfaces in ped centers and bottoms indicate desertdust is translocated vertically along the macropores betweenpeds and horizontally along platy boundaries to ped interiors.Once soils develop a strong columnar and platy structure, translocationto ped interiors is enhanced. Calibrated radiocarbon ages between5440 and 5045 BP for Av ped centers suggest enhanced dust fluxand pedogenesis occurred during the drier middle Holocene, aninference supported by luminescence dating and correlationswith regional eolian chronologies.

Abbreviations: AMS, accelerated mass spectrometry • BP, before present • EC, electrical conductivity • MRT, mean residence time • TL, thermoluminescence

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
Radiocarbon Age Estimates
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

VESICULAR SOIL HORIZONS commonly underlie desert pavements inthe southwestern USA. The hypothesis that vesicular soils andassociated desert pavements coevolve is supported by soil andstratigraphic field studies (McFadden et al., 1984, 1986; Wells et al., 1985,1987; McDonald, 1994), geochemical and mineralogicalinvestigations (McFadden et al., 1987), and cosmogenic datingprocedures (Wells et al., 1995; Anderson and Wells, 1997). Fine-texturedeolian material accumulating below surface clasts is pedogenicallyaltered into a vesicular horizon. Continued eolian accumulationand pedogenesis leads to cumulic soil development below accretionarydesert pavements. In the California Cima Volcanic Field, fine-textureddesert dust is deposited on rubbly, basalt flow surfaces (Fig. 1). Through processes such as rain splash, surface wash, andtranslocation, dust continually accumulates below basaltic clasts,developing underlying vesicular horizons. Thus, pavement clastshave never been buried as was once assumed, but rather theyrise upwards on a vertically accreting eolian mantle (Wells et al., 1987,1995; McFadden et al., 1987). The processes bywhich dust is incorporated into vesicular horizons that underliedesert pavements are poorly understood. Chemical, physical,and micromorphological data on vesicular soil peds are presentedhere that help identify the processes of dust translocationand CaCO₃ accumulation within vesicular soil peds. Combiningsuch data with age estimates of vesicular horizons providesinsights into the mechanisms and timing of accretionary desertpavement formation.

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Fig. 1. Diagram showing stratigraphic and topographic relationships of Sites I, II, and III discussed in the text. Soil stratigraphy and brief descriptions of vesicular horizons show desert pavements overlying the accretionary eolian mantle. Note the location of the Cima Volcanic Field within the Mojave Desert.

The designation of vesicular horizons as Av does not easilyconform to established criteria for horizon nomenclature. Forexample, although vesicular horizons have been designated Avsince at least 1958 (Springer, 1958) and are presently designatedas such in the soils literature (Peterson, 1980; McFadden et al., 1984,1998), the Soil Survey Manual (Soil Survey Staff, 1993)reserves v for plinthite soil horizons. In addition, Avhorizons exhibit complex properties commonly attributed to Bhorizons, such as enrichment in salts, CaCO₃, and translocatedclay, but they also continuously incorporate new parent materialfrom eolian additions, so might be designated as surface C horizons.Nevertheless, to avoid confusion and maintain convention, theAv designation is used here.

Early models of pavement formation focused on the exhumationof clasts by deflation (Springer, 1958; Jessup, 1960; Sharon, 1962;Symmons and Hemming, 1968; Cooke, 1970; Cooke and Warren, 1973;Mabbutt, 1977) or the shrink and swell heave of claststo the ground surface (Springer, 1958; Johnson and Hester, 1972;Mabbutt, 1977). More recently, the association of vesicularsoils with desert pavements on many landforms in the Southwesthas been shown to support an accretionary mechanism of pavementdevelopment (McFadden et al., 1986; McDonald, 1994). The shiftfrom assuming that desert pavements are zones of erosion tothe realization that they can be zones of deposition has causedstudies of landscape development in the Mojave Desert to refocuson dust accumulation and soil formation (McFadden et al., 1987;McDonald et al., 1994; Reheis and Kihl, 1995). Examples of accretionarydesert pavements on basalt flows of the Cima Volcanic Fieldinclude up to 2 m of relatively clast-free, quartz-rich eoliansands between basalt flows and the overlying desert pavements.The uppermost horizon, generally an Av, represents an activelyaccreting physically and chemically complex layer.

Vesicular horizons were recognized by Marbut (1935) to be commonin arid environments. Recently, because of the unique propertiesand stratigraphic position of Av horizons at the ground surface,investigations are focusing on their effects on decreasing infiltrationand increasing runoff, thereby influencing plant-water relationships,soil development, surficial processes, and landscape evolution(Musick, 1973; Wells et al., 1984, 1987; McDonald, 1994). Manyresearchers have investigated the processes of vesicle formation.Springer (1958) reproduced vesicles from sieved Av materialafter only five wet and dry cycles. The original Av propertiesof sieved soils return after 20 to 30 wetting and drying cycles;additional cycles increase the number, size, surface area, sphericity,and continuity of pores (Miller, 1971; Figueira and Stoops, 1983;Figueira, 1984). Evenari et al. (1974) determined thatvesicle formation was influenced by the following: texture,wetting front displacement of soil air, surface sealing by crustsor clasts, air trapped when wet, and thermal expansion of airbubbles. Bouza et al. (1993) found that a high exchangeableNa percentage (>15) is an important vesicle formation factorfor Patagonian soils. Vesicle stability is aided by CaCO₃ (Evenari et al., 1971)and clay coatings (Sullivan and Koppi, 1991).Observations of Av horizons in the Cima Volcanic Field revealstrong columnar and platy soil structure, with individual pedsexhibiting textural and chemical zonation from ped exteriorto ped interior locations. Qualitative field properties includesandy, low-CaCO₃ ped exteriors, and clayey CaCO₃-rich ped interiors(McFadden et al., 1984). Using micromorphic, physical, and chemicalanalyses, Anderson et al. (1994)(this study) observed that verticaland horizontal translocation of fines and solute transport withinthe Av horizon increase the clay and CaCO₃ content of ped interiors.

Radiocarbon Age Estimates

TOP
ABSTRACT
INTRODUCTION
Radiocarbon Age Estimates
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Radiocarbon age estimates based on soil organic matter can bedifficult to interpret, although interpretations can be enhancedusing supporting independent data. Some researchers suggestthat reliable radiocarbon dating of soils is possible (Scharpenseel, 1979;Goh et al., 1977), whereas others rely on the conceptof mean residence time (MRT), where a radiocarbon age on soilorganic matter is the mean age of all the organic C componentsadded to the soil over time. The MRT concept assumes that youngerC is continuously added to the soil, and that older C is lostby processes of decay, translocation, and mineralization. Meanresidence time dates are minimum age estimates; soils are actuallyolder than MRT ages suggest (Birkeland, 1999).

Because of the importance of determining soil age in geomorphic,pedogenic, and archeological settings, radiocarbon dating ofsoils continues to be used by many researchers. Wang et al. (1996)obtained model ages based on the ¹⁴C activity and ratesof younger C additions. Scharpenseel (1979) determined thatcareful consideration of sample selection and analysis of specificorganic matter fractions (humic, fulvic, humin, humic-clay,etc.) could greatly improve interpretation of the radiocarbonage. However, because of the physical and chemical variabilityof soil processes, it remains unclear which humus fraction isthe most representative of the initiation of soil genesis forany particular soil (Stout et al., 1981). Anderson and Wells (1997)reported consistent stratigraphic trends in acceleratormass spectrometry (AMS) radiocarbon ages of vesicular soilson an alluvial fan sequence in the Mojave Desert, suggestingthat an age-dependent signature may be preserved in Av soils.Because of the uncertainties of AMS ages on soil organic matter,conservative interpretations using minimum mean residence timesare useful within the context of supporting data, as discussedbelow.

The objectives of the research presented in this paper are to(i) identify the physical and chemical properties of Av pedsunderlying desert pavements and to (ii) determine the processesactive within the Av horizon that may affect desert pavementformation. Detailed physical, chemical, and micromorphologicalanalyses of Av peds enhance understanding of vesicular ped formationand the influence of Av horizon genesis on the development ofaccretionary desert pavements. Radiocarbon age estimates providepreliminary chronologic control in understanding the timingand rate of Av soil genesis for (i) comparisons with other datedsoils, (ii) correlation with potentially important climaticperiods, and (iii) determining whether Av horizons form duringdiscrete periods of the geologic past, e.g., Pleistocene orHolocene.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
Radiocarbon Age Estimates
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Site Characteristics
The study area is on a basalt flow in the Cima Volcanic Field,in the eastern Mojave Desert, that has been K-Ar dated to 580000± 160000 yr old (Turrin et al., 1984). This flow waschosen for the following reasons:

Previous work provides a reliablepedologic framework (McFadden et al., 1987).
The thick (upto 2 m) eolian sheet and strongly developed columnar-structuredvesicular horizon underlying the desert pavement provides aspectacular example of the accretionary model of desert pavementformation.
Age control for the underlying bedrock providesa maximum agefor soil formation.

The basalt flow is 700 m above sea level and grades <2°to the west. The flow surface lies 10 m above the local baselevel as an erosional remnant (Fig. 1). Vegetation includescreosote bush [Larrea tridentada (Sessé & Moc. exDC.) Coville], brittle bush (Encelia farinosa), mormon tea (Ephedratrifurca), and joshua tree (Yucca brevifolia Engelm.). Meanannual precipitation is between 12 and 25 cm and the mean annualtemperature is 16 to 18°C (National Oceanic and AtomspheiricAdministration [NOAA], 1978, p. 570). The basalt flow overliesPleistocene alluvial fan gravels. A mantle of desert dust overliesthe basalt flow (Fig. 1, Tables 1 and 2). Overlying the soilis a tightly interlocking desert pavement mosaic with millimeter-scaledistances between well-varnished basaltic boulders and cobbles(McFadden et al., 1989). The <5-mm interclast spaces consistof basaltic fragments derived from local salt weathering oflarger clasts and loose quartz-rich sand, silt, and clay eoliandeposits. In some locations a thin, cohesive crust has formed.Pebble to small cobble-size clasts generally rest on the surface,whereas larger cobbles can be embedded in the Av horizon upto several centimeters. Poorly preserved pavement fabric occursin areas where plant growth and animal activity are high. Reliefacross the surface is generally low, except where bedrock highsare exposed or where drainages have incised.

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Table 1. Soil physical properties of Pedon II.

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Table 2. Soil chemical and physical properties of Pedon II.

Sampling and Analysis
The Av horizon exhibits strong columnar parting to platy soilstructure, allowing cohesive, columnar peds to be sampled individually.Three sample sites were chosen 25-m apart along a 50-m transect.Site II is downslope from Site I and upslope from Site III (Fig. 1).After pavement characteristics were described, pavementclasts were removed, which allowed collection of surface eolianmaterial. Removal of surficial material revealed polygonal pedtops (Hunt et al., 1966; McFadden et al., 1987), ranging inboth diameter and thickness from <1 to >10 cm. The soil atSite II, judged to be similar to the soils at Sites I and III,was described in detail (Soil Survey Staff, 1992, 1993); itis a Typic Natrargid consisting of Avt-Btvk-Btk-Bk-Bky1-Bky2horizons (Fig. 1, Tables 1 and 2). The Av horizon has the followingcharacteristics: 10YR hue, high value, and low chroma, reflectingthe low organic matter content and slight oxidation; high siltand clay content; columnar and platy soil structure; horizonthickness between 5 and 10 cm; and numerous vesicular and channelpores. Ten to 12 peds from each site were collected and storedseparately.

In the laboratory, ped domains were defined according to macroscopiccharacteristics such as Munsell color, texture, carbonate nodules,and soil structure. Peds were subsampled according to the defineddomains to quantify physical and chemical variations withinpeds (Fig. 2) . Based on variations in soil properties, thefollowing seven distinct ped domains were identified and sampled:(1) material adhering to ped tops, (2) material adhering toped sides, (3) ped top, (4) ped center, (5) ped bottom, (6)ped upper side, and (7) ped lower side (Fig. 2). Material adheringto ped surfaces (Domains 1 and 2) is generally <3 mm thick.Other sampled domains are generally between 1 and 3 cm thick,according to ped size. Subsampled ped domains from single pedsprovided too little material for subsequent laboratory analysis.Therefore, analyzed samples consisted of combined material fromsubsampled domains of several peds from each separate site.The exception to this was subsampling for the accelerator massspectrometry radiocarbon analysis, which was performed on thecenter domain of two individual peds.

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Fig. 2. Cross-section of ped interior showing vesicles, platy structure, and sampling strategy for Av peds, including subsampled Domains 1 through 7.

Particle size was determined by pipette analysis, after removalof salts and carbonate by sodium acetate digestion (Gee and Bauder, 1982).Calcium carbonate weight percentage was determinedby the manometric method (Nelson, 1982). Electrical conductivitywas measured on saturation extracts following Rhoades (1982).Soil pH was measured using a 1:1 ratio of soil/water paste.Large-format thin-sections (2 by 3 cm) were made on verticalsections of Av peds.

Bulk soil samples for AMS radiocarbon age determination werecollected from ped centers at Sites I and II. Ped centers weresampled after trimming ped tops and sides until the center domainremained. Pretreatment for both samples included four steps:removal of macroscopic roots, acid washes in hot HCl to removeinorganic carbonates, alkali washes in NaOH to remove secondaryorganic acids, and final acid wash to neutralize the sample.These treatments were designed to remove the acid and alkali-solublefraction, leaving the alkali-insoluble organic fraction forage determination. Pretreatment and analysis were performedby Beta Analytic, Inc. (Florida).

RESULTS

TOP
ABSTRACT
INTRODUCTION
Radiocarbon Age Estimates
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Micromorphology
Micromorphic analysis focused on properties of vesicles andchannel pores, cutans, and carbonate accumulations. Evidenceof plant and animal activity can be seen in thin sections, althoughrootlets, obvious animal burrows, and identifiable plant andanimal remains are rare. Spherical vesicles occur in the sandyloam material that occupies exterior positions of ped tops andsides. Vesicles are not lined with clay or carbonate but arebounded by sand grains. Interior positions of ped tops, pedsides, and ped centers are dominated by irregularly shaped vesicles,compressed vertically and elongated horizontally. Many vesiclesin these domains have subrounded to angular borders.

Channel pores are absent from exterior positions of ped topsand ped sides. Interior positions of ped tops, sides, and centershave interconnected channel pores, but they are commonly filledwith sediment. In the lower positions of ped centers, ped lowersides, and ped bottoms, channel pores are common. Channel poresare often connected to the macropores between ped faces, forminga continuous conduit from the ground surface to interior peddomains. Channel pores in ped bottoms can be interconnectedto a great extent, forming platy soil structure. Argillans andsiltans commonly line the lower surfaces of platy structure,whereas the upper surfaces may have a coating of CaCO₃, calledcalcitans (Fig. 3) .

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Fig. 3. (a) Photomicrograph of Av ped, with argillans indicating lateral translocation of dust to ped interiors. (b) Line drawing identifying major micromorphological features seen in Fig. 4a. See text for details.

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Fig. 4. Hypothesized phases of eolian accumulation and vesicular soil formation emphasizing the influence of pedogenic processes on lifting clasts and consequent formation of accretionary desert pavements. Size of largest clast shown is $~$ 20 cm.

Physical and Chemical Analysis
Macroscopically delineated domains within peds provide a basisfor interpreting genetic processes from measured physical andchemical properties. General trends in particle-size distributionshow that materials adhering to ped tops and sides have thelowest clay content, whereas ped centers have the highest (Table 3).Material adhering to ped tops and ped faces (Domains 1 and2) consistently have the coarsest texture, sandy loam, with2 to 7% clay. Ped top (Domain 3) textures range from silt loamto loam, having 19% clay and 45 to 50% silt, the highest siltconcentration within the ped. Ped center textures range fromloam to clay, with the highest clay (27 to 40%) and silt plusclay (70 to 71%) concentrations. Ped bottom textures are loamto clay loam, with generally the second highest clay concentrations.Upper-side textures are loam, with consistently low clay andhigh silt concentrations. Lower-side textures are clay loamand loam, illustrating an increase in clay concentration comparedwith upper sides.

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Table 3. Properties of subsampled vesicular horizon peds, Cima Volcanic Field.

The CaCO₃ content was determined for 18 subsamples, althoughthis was not determined for material adhering to ped faces (Domain2) because of small sample recovery (Table 3). The general trendis that material adhering to ped tops has the lowest CaCO₃ contentand ped centers have the highest. Materials adhering to pedtops (Domain 1) have a CaCO₃ content ranging from 0.4 to 1.5%,and ped tops (Domain 3) range from 3.0 to 5.5%. Ped centershave a CaCO₃ content ranging from 6.0 to 12.1%, and those ofped bottoms are nearly as high, ranging from 6.1 to 8.6%. Upperand lower ped sides have similar CaCO₃ contents, with the lowestbeing 1.1% and the highest 3.3%.

Trends in particle-size distribution and CaCO₃ content alsooccur along the topographic transect, from Site I to Site III.The silt + clay content for material adhering to ped tops increasesfrom 34% at the upper site (Site I) to 40% at the lower site(Site III). Similarly, the silt + clay content of material adheringto ped faces increases from 40 to 45% and the clay content forped centers increases from 27 to 40% between Site I and SiteIII. An increase in CaCO₃ content in downslope positions isnoted for some peds in Domains 1, 3, and 4.

The results of pH and electrical conductivity (EC) analysisindicate alkaline and saline conditions (Table 3); the pH valuesare 9.2 or greater. No noticeable pattern in pH values occurredwithin peds or along the topographic transect. The EC valuesindicate saline conditions (EC > 4 dS m^-1) for many of the subsampleddomains. Electrical conductivity of <2 dS m^-1 occurs at allsites for material adhering to ped tops. The highest EC, 9.4dS m^-1, is in the ped center of the lowest topographic position,Site III.

Radiocarbon Ages
Accelerator mass spectrometry radiocarbon analysis of fine-grainedbulk soil samples from two subsampled ped centers provides similarage determinations. Conventional, uncalibrated radiocarbon agesare 4530 ± 50 BP (Beta-93902) at Site I, and 4570 ±50 BP (Beta-91527) at Site II, 25 m apart. The two sigma (95%probability) tree-ring calibrated radiocarbon age estimate fromSite I ranges from 5315 to 4995 years before present (BP), whereasthe age from Site II ranges from 5440 to 5045 years BP. Thecalibrated radiocarbon ages, interpreted as MRTs, are comparablewith a 5000 ± 1000 BP thermoluminescence age obtainedfrom an Av horizon from a similar-aged basalt flow nearby (McFadden et al., 1998).They are also useful for discussing relationshipswith regional climatic (Spaulding, 1991) and eolian chronologies(Clarke, 1994).

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
Radiocarbon Age Estimates
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Interpretation of Processes
The micromorphic characteristics of Av peds suggest that poreshape and continuity control the movement of material to pedinteriors. Pore shapes include a variety of nonmatrix and interstructuralpores (Soil Survey Staff, 1993). Nonmatrix pores occur as manyvery fine to medium (<0.5–5 mm) and occasionally coarseto very coarse (5–10 mm) elliptical and channel shapes.Elliptical pores may coalesce to form interconnected channels,which in turn may coalesce laterally to create platy soil structure.Platy structure in the center and bottom of columnar peds formsconduits connected to interstructural macropores between thecolumnar peds (Sullivan and Koppi, 1991). Interstructural poresare generally <0.5 cm wide and <10 cm long. Continuousconduits between interstructural macropores, and the channelsand platy structure within the columnar peds, allow movementof sediment and water from the ground surface to ped interiors(Anderson et al., 1994). Incorporation of fine material withinthe ped probably occurs in two ways: transport in suspensionby flowing water and matric suction. Flowing water transportsthe fines down vertical boundaries between peds and inward alongthe horizontal platy boundaries where clays accumulate as layeredargillans. Further evidence for the transport of coarser materialoccurs in the form of microbedding, where millimeter-size channelscontain deposits fining upward from sand to silt size. Matricsuction draws water, solutes, and colloids to ped interiorsand, as evapotranspiration dries the soil, CaCO₃ precipitatesand clay remains. Anderson et al. (1994) indicated that sedimentmovement may be enhanced by the dispersive properties at thesoil surface under high Na concentrations, and the flocculatingproperties of ped interiors and bottoms because of higher CaCO₃concentrations.

Peds contain two domains of low clay and CaCO₃ content and fivedomains of higher clay and CaCO₃. Domains 1 and 2 have consistentlylower clay and CaCO₃, and higher sand and silt content thanthe other domains. Ped centers have higher clay and CaCO₃ contentsthan all other ped domains, with up to 15 times the CaCO₃ concentrationof exterior domains. Also, micromorphic investigations showargillans and calcitans lining horizontal channels and platystructural features in the lower portions of ped centers. Numerousirregular argillaceous and skeletal glaebules, and sand-filledgranotubules in the upper portions of ped centers, indicatethat this domain is relatively inactive with regard to the lateraltranslocation of sediment. Pedotubules filled with sandy materialsuggest that as upper ped centers become filled with sediment,the active zone of translocation shifts to lower ped domains,such as ped bottoms, where platy structures dominate.

Ped bottom domains have calcitans and layered argillans thatrepresent distinct episodes of lateral clay translocation. Finingupward microbedding of silt and sand in ped bottoms indicateslateral sediment transport by suspension along the platy structure,which represents the active domain of lateral clay, silt, andsand translocation (see Fig. 3). Particle-size distribution,CaCO₃ content, and micromorphology of Av peds indicate thatsoluble and easily translocated constituents are preferentiallyremoved from the outer two domains, consequently accumulatingin the ped center, upper-side, lower-side, and bottom domains.

From a landscape-scale perspective, the CaCO₃ and clay datamay provide insights into processes involved in the progressivereduction of relief on desert pavement surfaces. Incipient desertpavement landscapes have high constructional relief becauseof irregular topography inherited during initial emplacement,whereas mature pavement landscapes (middle to early Holoceneand late Pleistocene) have reduced constructional relief (Wells et al., 1984;Bull, 1991). As pavements develop, topographichighs are reduced by salt weathering, rain splash, and colluviation,and topographic lows are filled with slopewash colluvial andeolian material. A measurable increase in both fines and CaCO₃occurs from Site I to Site III (see Fig. 1). Site III, at thetopographically lowest position, has consistently higher siltand clay contents for many ped domains, and clayey, CaCO₃-richped centers. Processes related to eolian deposition, surfacetransport of fines via overland flow, and subsurface transportof solutes to lower topographic positions may be responsiblefor the observed increases. The amount of clay and CaCO₃ incorporatedinto the topographically lower soils may increase the volumeof material in these positions at a greater rate than slightlyhigher positions, thereby aiding in relief reduction of increasinglyolder desert pavement surfaces.

Ages of Av Peds
The processes of soil organic matter turnover and the subsequentaddition of younger C to the soil system do not conform to thebasic assumption that "carbon isotopic ratios have not beenaltered except by ¹⁴C decay since the sampled material ceasedto be an active part of the carbon reservoir" (Taylor, 1987).Because surface soils are an active part of the C reservoir,that is, younger C continues to be added to the soil duringpedogenesis, they are very difficult to interpret. Radiocarbonages on soils result from a mixture of material being addeddaily to fractions already in the soil, perhaps for thousandsof years (Birkeland, 1999). Ages determined by bulk soil radiocarbonanalysis are the average ages of all organic constituents inthe soil, excluding those removed through pretreatment processes.In this context, MRTs do not represent steady-state systemsbecause (i) the rates of additions and removals from the soilsystem may exhibit considerable temporal variation, and (ii)organic matter steady states are not attained in desert soilsfor a very long time (perhaps 300000 yr) because of the relativelyslow rates of organic matter additions and removals (Wang et al., 1996).Although such age determinations can be problematic(Stout et al., 1981), limited interpretations can be made usingMRTs as minimum ages (Martel and Paul, 1974; Goh et al., 1977;Scharpenseel, 1979). Some researchers think that specific organicfractions can provide reliable oldest ages, and therefore theclosest to the inception of soil genesis (Goh et al., 1977;Holliday et al., 1985), while others have determined that resultsare neither repeatable nor predictable from one soil to another(Gilet-Blein et al., 1980).

Most studies of soil radiocarbon ages identify the potentialsource of young organic C as continued growth and decay of insitu organic matter; few studies have attempted to account fororganic matter additions from eolian sources, even though Reheis and Kihl (1995)measured up to 23.5% organic matter from dusttraps in the Cima Volcanic Field and 45% in other portions ofthe Mojave Desert. Given that Av soils in the Cima VolcanicField have eolian origins (McFadden et al., 1984, 1987, 1998),and that >20% of desert dust consists of organic matter, itmust be assumed that a significant portion of organic matteradded to desert soils is from eolian sources. Therefore, radiocarbonages determined on any soil fraction must take this into account.Although the origin of organic C for bulk AMS analysis of thesampled Av peds remains unclear and only speculative, the possiblesources, and interpretations, must attempt to explain the contributionsfrom both in situ organic matter production and eolian additions.

A conservative interpretation of the AMS ages of Av peds canbe made by comparing them with (i) an independent thermoluminescence(TL) age on Av soils, (ii) regional eolian activity, and (iii)periods of regional aridity. Preliminary inferences can thusbe made regarding increased aridity, eolian activity, and enhancedvesicular soil formation during the middle Holocene.

Because the radiocarbon ages are interpreted as minimum ageestimates, Av soil genesis probably began sometime prior tothe 5440 to 4995 BP period. The 5000 ± 1000 BP TL ageon quartz sands from an Av soil ped on a nearby 560 ka basaltflow (McFadden et al., 1998) supports these ages. The TL ageon eolian quartz sand suggests an influx of eolian materialonto the basalt flows in the Cima Volcanic Field during themiddle Holocene, influencing vesicular soil formation by addingeolian fines to the developing Av horizon. Considering the organicmatter data from Reheis et al. (1995) discussed above, it ispossible that increased amounts of eolian organic matter werealso added to the soil system during this time. This might explainthe correspondence between AMS and TL dating methods. Resultingages from both methods could be interpreted as MRTs, given thedynamic processes active in the Av horizons, where organic matterand quartz grains are introduced to ped centers by the processesdescribed earlier. Perhaps enough eolian organic matter wasadded during this time to lower the MRT age towards the $~$ 5000-BPperiod.

The AMS and TL ages correspond to middle Holocene eolian activityat Silver Lake playa, 20 km upwind from the Cima Volcanic Field,where an eolian deposit is bracketed by 8350- and 3620-BP radiocarbonages (Wells et al., 1989). Eolian deposits at the Kelso sanddunes, 10 km south of the project area, have been dated usingoptically stimulated luminescence to between 8420 and 3500 BP(Clarke, 1994). Spaulding (1991), using packrat midden data,suggested that a period of increased aridity occurred between $~$ 8000 and 4000 BP in portions of the Mojave Desert.

The correspondence between AMS and TL dated Av horizons, withperiods of increased eolian activity and regional aridity, suggeststhat the Av horizons investigated in this study may, in part,be influenced by a middle Holocene increase in eolian sedimentand organic matter mobilization, deposition, and incorporationinto surface Av soils. Wells et al. (1984)(1987) and McFadden et al. (1984)( 1986) have suggested that desiccation of SilverLake at the end of the Pleistocene dramatically increased thesupply of dust to the Cima Volcanic Field, greatly affectingsoil genesis and clast fracturing by increasing the amount ofsalt-rich eolian fines. They postulated that Av horizon developmenton the basalt flows in the Cima Volcanic Field may have beeninitiated or enhanced during the Pleistocene to Holocene transitionand its increased eolian activity. The results from chemical,physical, and chronologic analyses presented above suggest thatthe middle Holocene may also have been a time of increased eoliandeposition, affecting pedogenic development of the already formedAv horizon, with a corresponding influence on desert pavementformation.

Implications for Desert Pavement Formation
The processes of sediment incorporation below desert pavementon well-developed soils include clay and CaCO₃ accumulationin the upper several centimeters of the vesicular soil, causinghorizon thickening and vertical accretion. Pavement clasts abovethis accreting Av horizon ride upward as material below continuesto accumulate. Translocation and subsequent storage of eolianfines and salts in ped interiors provides a mechanism for cumulicsoil development below pavement clasts, whereby material isadded to the soil via lateral macropore conduits.

The initial phase of the process of eolian accumulation andpavement development remains speculative, but is probably influencedby adhesion and surface tension forces as water and sedimentact to form laminar surface crusts that adhere to clast bottoms(Fig. 4) . A second phase includes continued eolian influxand CaCO₃ accumulation, allowing formation of incipient vesiclesand pedogenic alteration. When soil properties reach certainphysical and chemical thresholds—based largely on claytype and amount, and salt and Na concentration—shrinkingand swelling processes may enhance clast lifting. A criticalthird phase of development is related to the formation of well-definedsoil structure by shrink-swell activity, where vertical poresbetween columnar peds are connected to platy structure at pedbottoms. When this phase is attained, further eolian materialcan be added to both the ped tops and ped interior positions.

An increase in clay and CaCO₃ in Av horizons in topographiclows suggests that rates of cumulic soil development and associatedpavement-clast lifting are accelerated in lower topographicpositions, increasing the rate of relief reduction. In addition,as Av horizons continue to accumulate material, underlying soilhorizons continue to develop as well, although the relationsbetween Av genesis and subsoil development remain poorly understood.McFadden et al. (1987) found evidence that subsoil Btvk morphologiessupport the idea of the transformation of Av's to B horizons.However, increasing Av thickness with time on alluvial fan chronosequencesseem to indicate rather long periods of Av stability and continueddevelopment (Anderson, 1999; McDonald, 1994). McDonald (1994)finds evidence that the Av horizon may, in fact, also rise verticallyas material accumulates below both the pavement clasts and theexisting Av layer.

Organic matter is continuously added to the soil by both insitu processes and eolian deposition. Preliminary interpretationsof radiocarbon age estimates, and correlation with regionalchronologies, suggest that the middle Holocene was a periodof increased additions of datable material to the soil, notablyquartz sand and organic C. Such an increase may provide enoughmaterial to cause a decrease of the mean residence time AMSand TL age-estimates, moving towards concordant chronologies.These concordant AMS and TL ages on Av peds correspond to aperiod of increased aridity and eolian activity throughout theMojave Desert during the middle Holocene, with important influenceson Av soil genesis and desert pavement development.

ACKNOWLEDGMENTS

This project was supported in part by National Science Foundationgrant EAR-9205696, Geological Society of America student researchgrant, Institutional Proposal Assistance grant from the DesertResearch Institute, Reno; Los Alamos National Laboratory, Universityof California Riverside, California State University DesertStudies Center, Zzyzx. I thank Diana Anderson and Yvonne Woodfor field assistance; Eric McDonald and Les McFadden for veryhelpful discussions on desert pavement formation processes;and Louella Holter, Bilby Research Center, Northern ArizonaUniversity for assistance in preparing this manuscript. We alsothank two anonymous reviewers for their helpful comments.

Received for publication February 9, 2001.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
Radiocarbon Age Estimates
MATERIALS AND METHODS
RESULTS
DISCUSSION
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