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    • Plusieurs versions

    The Spatial Distribution and Ecological Impacts of Aeolian Soil Erosion in Kangerlussuaq, West Greenland

    Heindel, Ruth C, Chipman, Jonathan W, Virginia, Ross A
    Annals of the Association of American Geographers, 03 September 2015, Vol.105(5), pp.875-890 [Revue évaluée par les pairs]

    • Plusieurs versions

    Remote sensing and image interpretation

    Lillesand, Thomas M
    • Plusieurs versions

    Evaluation of Agricultural Land Cover Representations on Regional Climate Model Simulations in the Brazilian Cerrado

    Spera, Stephanie A., Winter, Jonathan M., Chipman, Jonathan W.
    Journal of Geophysical Research: Atmospheres, 27 May 2018, Vol.123(10), pp.5163-5176 [Revue évaluée par les pairs]

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    Why does the runoff in Hotan River show a slight decreased trend in northwestern China?

    Li, Baofu, Chen, Yaning, Chipman, Jonathan W., Shi, Xun, Chen, Zhongsheng
    Atmospheric Science Letters, January 2018, Vol.19(1), pp.n/a-n/a [Revue évaluée par les pairs]

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    Quantifying rates of soil deflation with Structure-from-Motion photogrammetry in west Greenland

    Heindel, Ruth C, Chipman, Jonathan W, Dietrich, James T, Virginia, Ross A
    Arctic, Antarctic, and Alpine Research, 01 January 2018, Vol.50(1) [Revue évaluée par les pairs]

    • Plusieurs versions

    Quantifying suspended sediment concentration in subglacial sediment plumes discharging from two Svalbard tidewater glaciers using Landsat-8 and in situ measurements

    Schild, Kristin M, Hawley, Robert L, Chipman, Jonathan W, Benn, Douglas I
    International Journal of Remote Sensing, 02 December 2017, Vol.38(23), pp.6865-6881 [Revue évaluée par les pairs]

    • Plusieurs versions

    Spatial analysis of amyotrophic lateral sclerosis in Northern New England, USA, 1997–2009

    Caller, Tracie A., Chipman, Jonathan W., Field, Nicholas C., Stommel, Elijah W.
    Muscle & Nerve, August 2013, Vol.48(2), pp.235-241 [Revue évaluée par les pairs]

    • Plusieurs versions

    Correction to: The Spatial Distribution and Ecological Impacts of Aeolian Soil Erosion in Kangerlussuaq, West Greenland

    Heindel, Ruth C, Chipman, Jonathan W, Virginia, Ross A
    Annals of the American Association of Geographers, 02 November 2018, Vol.108(6), pp.1733-1733 [Revue évaluée par les pairs]

    • Plusieurs versions

    A comparison of five malaria transmission models: benchmark tests and implications for disease control

    Wallace, Dorothy I, Southworth, Ben S, Shi, Xun, Chipman, Jonathan W, Githeko, Andrew K
    Malaria journal, 10 July 2014, Vol.13, pp.268 [Revue évaluée par les pairs]

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    Modeling the Response of Anopheles gambiae (Diptera: Culicidae) Populations in the Kenya Highlands to a Rise in Mean Annual Temperature

    Wallace, Dorothy, Prosper, Olivia, Savos, Jacob, Dunham, Ann M, Chipman, Jonathan W, Shi, Xun, Ndenga, Bryson, Githeko, Andrew
    Journal of medical entomology, 01 March 2017, Vol.54(2), pp.299-311 [Revue évaluée par les pairs]
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    Titre: Modeling the Response of Anopheles gambiae (Diptera: Culicidae) Populations in the Kenya Highlands to a Rise in Mean Annual Temperature
    Auteur: Wallace, Dorothy; Prosper, Olivia; Savos, Jacob; Dunham, Ann M; Chipman, Jonathan W; Shi, Xun; Ndenga, Bryson; Githeko, Andrew
    Sujet: Anopheles Gambiae ; Carrying Capacity ; Climate Change ; Mosquito Population Model ; Anopheles -- Physiology
    Description: A dynamical model of Anopheles gambiae larval and adult populations is constructed that matches temperature-dependent maturation times and mortality measured experimentally as well as larval instar and adult mosquito emergence data from field studies in the Kenya Highlands. Spectral classification of high-resolution satellite imagery is used to estimate household density. Indoor resting densities collected over a period of one year combined with predictions of the dynamical model give estimates of both aquatic habitat and total adult mosquito densities. Temperature and precipitation patterns are derived from monthly records. Precipitation patterns are compared with average and extreme habitat estimates to estimate available aquatic habitat in an annual cycle. These estimates are coupled with the original model to produce estimates of adult and larval populations dependent on changing aquatic carrying capacity for larvae and changing maturation and mortality dependent on temperature. This paper offers a general method for estimating the total area of aquatic habitat in a given region, based on larval counts, emergence rates, indoor resting density data, and number of households.Altering the average daily temperature and the average daily rainfall simulates the effect of climate change on annual cycles of prevalence of An. gambiae adults. We show that small increases in average annual temperature have a large impact on adult mosquito density, whether measured at model equilibrium values for a single square meter of habitat or tracked over the course of a year of varying habitat availability and temperature.
    Fait partie de: Journal of medical entomology, 01 March 2017, Vol.54(2), pp.299-311
    Identifiant: 1938-2928 (E-ISSN); 28031349 Version (PMID); 10.1093/jme/tjw174 (DOI)