David M Wilkinson
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Explore the profile of David M Wilkinson including associated specialties, affiliations and a list of published articles.
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48
Citations
517
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Recent Articles
1.
Lu Y, Jin L, Chen H, Luo A, Ehrlich E, Li S, et al.
Environ Res
. 2025 Feb;
271:121097.
PMID: 39938632
Urbanization can significantly drive biodiversity loss in river ecosystems, yet the underlying mechanisms require further study. Here, we used a trait-based approach to investigate temporal succession and variation in the...
2.
Toth P, Green A, Wilkinson D, Brides K, Lovas-Kiss A
Ecol Evol
. 2023 Nov;
13(11):e10677.
PMID: 38020707
Ducks and geese are little studied dispersal vectors for plants lacking a fleshy fruit, and our understanding of the traits associated with these plants is limited. We analyzed 507 faecal...
3.
Jin L, Chen H, Matsuzaki S, Shinohara R, Wilkinson D, Yang J
Water Res
. 2023 Sep;
245:120639.
PMID: 37774538
Eutrophication and harmful algal blooms have severe effects on water quality and biodiversity in lakes and reservoirs. Ecological regime shifts of phytoplankton blooms are generally thought to be driven by...
4.
Creevy A, Wilkinson D, Andersen R, Payne R
Eur J Protistol
. 2023 Apr;
89:125977.
PMID: 37060794
Extensive drainage of peatlands in north-west Europe for the purposes of afforestation for timber production and harvesting has altered the carbon balance and biodiversity value. Large-scale restoration projects aim to...
5.
Lenton T, Kohler T, Marquet P, Boyle R, Crucifix M, Wilkinson D, et al.
Trends Ecol Evol
. 2021 Jan;
36(4):333-344.
PMID: 33414020
Since Darwin, individuals and more recently genes, have been the focus of evolutionary thinking. The idea that selection operates on nonreproducing, higher-level systems including ecosystems or societies, has met with...
6.
Marston C, Wilkinson D, Sponheimer M, Codron D, Codron J, ORegan H
PeerJ
. 2020 Mar;
8:e8622.
PMID: 32117638
Examination of the feeding habits of mammalian species such as the African elephant () that range over large seasonally dynamic areas is exceptionally challenging using field-based methods alone. Although much...
7.
Strickson E, Hutchinson J, Wilkinson D, Falkingham P
J Anat
. 2019 Nov;
236(1):72-84.
PMID: 31713855
The surface area of feet in contact with the ground is a key morphological feature that influences animal locomotion. Underfoot pressures (and consequently stresses experienced by the foot), as well...
8.
Liu L, Chen H, Liu M, Yang J, Xiao P, Wilkinson D, et al.
ISME J
. 2019 May;
13(9):2196-2208.
PMID: 31053831
Although it is widely recognized that cyanobacterial blooms have substantial influence on the plankton community in general, their correlations with the whole community of eukaryotic plankton at longer time scales...
9.
Nicholson A, Wilkinson D, Williams H, Lenton T
J Theor Biol
. 2018 Aug;
457:249-257.
PMID: 30149011
A long-standing objection to the Gaia hypothesis has been a perceived lack of plausible mechanisms by which life on Earth could come to regulate its abiotic environment. A null hypothesis...
10.
Lenton T, Daines S, Dyke J, Nicholson A, Wilkinson D, Williams H
Trends Ecol Evol
. 2018 Jul;
33(8):633-645.
PMID: 30041995
Recently postulated mechanisms and models can help explain the enduring 'Gaia' puzzle of environmental regulation mediated by life. Natural selection can produce nutrient recycling at local scales and regulation of...