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  • Alwash, M. A., S. M. S. Zaidi, and U. Terhalle (1986), Description of arid geomorphic features using Landsat-TM data and ground truth information (Wadi-Fatima, Kingdom of Saudi-Arabia), Catena, 13(3), 277293.
  • An, P., W. M. Moon, and A. Rencz (1991), Application of fuzzy set theory for integration of geological, geophysical and remote sensing data, Can. J. Explor. Geophys., 27, 111.
  • Bacon, S. N., E. V. McDonald, T. G. Caldwell, and G. K. Dalldorf (2010a), Timing and distribution of alluvial fan sedimentation in response to strengthening of late Holocene ENSO variability in the Sonoran Desert, southwestern Arizona, USA, Quat. Res., 73(3), 425438.
  • Bacon, S. N., E. V. McDonald, G. K. Dalldorf, S. E. Baker, D. E. Sabol Jr., T. B. Minor, S. D. Bassett, S. R. MacCabe, and T. F. Bullard (2010b), Predictive soil maps based on geomorphic mapping, remote sensing, and soil databases in the desert southwest, in Digital Soil Mapping: Bridging Research, Production, and Environmental Application, edited by J. L. Boettinger, D. W. Lowell, and A. C. Moore, Springer, pp. 411421, Netherlands.
  • Beratan, K. K., and R. Anderson (1998), The use of Landsat Thematic Mapper data for mapping and correlation of Quaternary geomorphic surfaces in the southern Whipple Mountains, California, Int. J. Remote Sens., 19(12), 23452359.
  • Bierman, P. R., A. R. Gillespie, and M. W. Caffee (1995), Cosmogenic ages for earthquake recurrence intervals and debris flow fan deposition, Owens Valley, California, Science, 270(5235), 447450.
  • Birkeland, P. W. (1999), Soils and Geomorphology, pp. 448, Oxford Univ. Press, New York.
  • Blackwelder, E. (1931), Desert plains, J. Geol., 39, 465484.
  • Bonham-Carter, G. F. (1994), Geographic information systems for geoscientists: Modeling with GIS, in Computer Methods in Geosciences, 10, 398 pp., Elsevier Butterworth-Heinemann, Burlington, MA.
  • Booth, A. M., J. J. Roering, and J. T. Perron (2009), Automated landslide mapping using spectral analysis and high-resolution topographic data: Puget Sound lowlands, Washington, and Portland Hills, Oregon, Geomorphology, 109(3-4), 132147.
  • Bull, W. B. (1977), The alluvial fan environment, Prog. Phys. Geogr., 1, 222270.
  • Bull, W. B. (1984), Tectonic geomorphology, J. Geol. Educ., 32(5), 310324.
  • Bull, W. B. (1991), Geomorphic Responses to Climatic Change, pp. 326, Oxford Univ. Press, New York.
  • Bull, W. B. (2008), Tectonic Geomorphology of Mountains: A New Approach to Paleoseismology, pp. 316, Blackwell Publishing, Malden, USA.
  • Caldwell, T. G., M. H. Young, J. T. Zhu, and E. V. McDonald (2008), Spatial structure of hydraulic properties from canopy to interspace in the Mojave Desert, Geophys. Res. Lett., 35 L19406, doi:10.1029/2008GL035095.
  • Christenson, G. E., and C. Purcell (1985), Correlation and age of Quaternary alluvial-fan sequences, Basin and Range province, southwestern United States, in Soils and Quaternary Geology of the Southwestern United States, Geological Society of America Special Papers, vol. 203, pp. 115122, The Geollogical Society of America, Boulder, Colorado.
  • Chung, C. F., and A. G. Fabbri (2001), Prediction models for landslide hazard using fuzzy set approach, in Geomorphology and Environmental Impact Assessment, edited by M. Marchetti and V. Rivas, pp. 3147, A.A. Balkema, Rotterdam.
  • Colman, S. M., and K. L. Pierce (1986), Glacial sequence near McCall, Idaho: Weathering rinds, soil development, morphology, and other relative-age criteria, Quat. Res., 25(1), 2542.
  • Crouvi, O., E. Ben-Dor, M. Beyth, D. Avigad, and R. Amit (2006), Quantitative mapping of arid alluvial fan surfaces using field spectrometer and hyperspectral remote sensing, Remote Sens. Environ., 104(1), 103117.
  • Davis, W. M. (1905), The geographical cycle in an arid climate, J. Geol., 13, 381407.
  • Denny, C. S. (1965), Alluvial Fans in the Death Valley Region, California and Nevada, U.S. Geological Survey Professional Paper 466, pp. 62, US Government Printing Office, Washington.
  • Farr, T. G., and O. A. Chadwick (1996), Geomorphic processes and remote sensing signatures of alluvial fans in the Kun Lun Mountains, China, J. Geophys. Res., 101(E10), 23,09123,100.
  • Frankel, K. L., and J. F. Dolan (2007), Characterizing arid region alluvial fan surface roughness with airborne laser swath mapping digital topographic data, J. Geophys. Res., 112, F02025, doi:10.1029/2006JF000644.
  • Gilbert, G. K. (1877), Geology of the Henry Mountains (Utah), in U.S. Geographical and Geological Survey of the Rocky Mountain Region, pp. 93144, U.S. Gov. Printing Off, Washington, D. C.
  • Gillespie, A. R., A. B. Kahle, and F. D. Palluconi (1984), Mapping alluvial fans in Death Valley, California, using multichannel thermal infrared images, Geophys. Res. Lett., 11(11), 11531156.
  • Guthrie, R. H., and S. G. Evans (2007), Work, persistence, and formative events: The geomorphic impact of landslides, Geomorphology, 88(3-4), 266275.
  • Hurst, M. D., S. M. Mudd, K. Yoo, M. Attal, and R. Walcott (2013), Influence of lithology on hillslope morphology and response to tectonic forcing in the northern Sierra Nevada of California, J. Geophys. Res. Earth Surf., 118, 832851, doi:10.1002/jgrf.20049.
  • Kierein-Young, K. S. (1997), The integration of optical and radar data to characterize mineralogy and morphology of surfaces in Death Valley, California, USA, Int. J. Remote Sens., 18(7), 15171541.
  • Lashlee, D., F. Briuer, W. Murphy, and E. V. McDonald (2002), Geomorphic mapping enhances cultural resource management at the US Army Yuma Proving Ground, Arizona, USA, Arid Land Res. Manage., 16(3), 213229.
  • Lubetkin, L. K. C., and M. M. Clark (1988), Late Quaternary activity along the Lone Pine fault, eastern California, Geol. Soc. Am. Bull., 100(5), 755766.
  • Matmon, A., D. P. Schwartz, R. Finkel, S. Clemmens, and T. Hanks (2005), Dating offset fans along the Mojave section of the San Andreas fault using cosmogenic Al-26 and Be-10, Geol. Soc. Am. Bull., 117(5-6), 795807.
  • Matmon, A., K. Nichols, and R. Finkel (2006), Isotopic insights into smoothening of abandoned fan surfaces, southern California, Quat. Res., 66(1), 109118.
  • McAuliffe, J. R., and E. V. McDonald (2006), Holocene environmental change and vegetation contraction in the Sonoran Desert, Quat. Res., 65(2), 204215.
  • McDonald, E. V. (1994), The relative influences of climatic change, desert dust, and lithologic control on soil-geomorphic processes and soil hydrology of calcic soils formed on Quaternary alluvial-fan deposits in the Mojave Desert, California, Unpublished Ph.D. thesis, 382 pp., University of New Mexico.
  • McDonald, E. V., L. D. McFadden, and S. G. Wells (2003), Regional response of alluvial fans to the Pleistocene-Holocene climatic transition, Mojave Desert, California, in Paleoenvironments and Paleohydrology of the Mojave and Southern Great Basin Deserts, Geological Society of America Special Paper, vol. 368, edited by S. G. Wells and N. Lancaster, Geol. Soc. Am., Boulder, Colorado.
  • McFadden, L. D., J. B. Ritter, and S. G. Wells (1989), Use of multiparameter relative-age methods for age estimation and correlation of alluvial-fan surfaces on a desert piedmont, eastern Mojave Desert, California, Quat. Res., 32(3), 276290.
  • McKean, J., and J. Roering (2004), Objective landslide detection and surface morphology mapping using high-resolution airborne laser altimetry, Geomorphology, 57(3-4), 331351.
  • Nichols, K. K., P. R. Bierman, R. L. Hooke, E. M. Clapp, and M. Caffee (2002), Quantifying sediment transport on desert piedmonts using Be-10 and Al-26, Geomorphology, 45(1-2), 105125.
  • Nichols, K. K., P. R. Bierman, W. R. Foniri, A. R. Gillespie, M. Caffee, and R. Finkel (2006), Dates and rates of arid region geomorphic processes, GSA Today, 16, 411.
  • Pierre, C., G. Bergametti, B. Marticorena, E. Mougin, C. Bouet, and C. Schmechtig (2012), Impact of vegetation and soil moisture seasonal dynamics on dust emissions over the Sahel, J. Geophys. Res., 117, D06114, doi:10.1029/2011JD016950.
  • Regmi, N. R., J. R. Giardino, and J. D. Vitek (2010), Assessing susceptibility to landslides: Using models to understand observed changes in slopes, Geomorphology, 122(1-2), 2538.
  • Richard, S. M., S. J. Reynolds, J. E. Spencer, P. A. Pearthree, and Comps. (2000), Geologic map of Arizona: Arizona Geological Survey Map M-35, 1 sheet, scale:1:1,000,000.
  • Ritter, J. B., et al. (1993), Quaternary evolution of Cedar Creek alluvial-fan, Montana, Geomorphology, 8(4), 287304.
  • Romkens, M. J. M., K. Helming, and S. N. Prasad (2002), Soil erosion under different rainfall intensities, surface roughness, and soil water regimes, Catena, 46(2-3), 103123.
  • Sweeney, M. R., E. V. McDonald, and V. Etyemezian (2011), Quantifying dust emissions from desert landforms, eastern Mojave Desert, USA, Geomorphology, 135(1-2), 2134.
  • Wallace, R. E. (1977), Profiles and ages of young fault scarps, north-central Nevada, Geol. Soc. Am. Bull., 88(9), 12671281.
  • Wells, S. G., L. D. Mcfadden, and J. C. Dohrenwend (1987), Influence of late Quaternary climatic changes on geomorphic and pedogenic processes on a desert piedmont, eastern Mojave Desert, California, Quat. Res., 27(2), 130146.
  • Western Regional Climate Center (2012), Yuma Proving Ground, Arizona (029654) period of record monthly climate summary, http://www.wrcc.dri.edu/cgi-bin/cliMAIN.pl?az9654.
  • Whipple, K. X., and T. Dunne (1992), The influence of debris-flow rheology on fan morphology, Owens Valley, California, Geol. Soc. Am. Bull., 104(7), 887900.
  • White, K. (1993), Image processing of Thematic Mapper data for discriminating piedmont surficial materials in the Tunisian Southern Atlas, Int. J. Remote Sens., 14(5), 961977.
  • Wolman, G. M., and J. P. Miller (1960), Magnitude and frequency of forces in geomorphic processes, J. Geol., 68, 5474.
  • Zadeh, L. A. (1965), Fuzzy sets, Inf. Control, 8, 338353.