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Showing 1–7 of 7 results
Advanced filters: Author: Lyla L. Taylor Clear advanced filters

  • Combining high-resolution mapping of foliar and herbivore faecal sodium concentrations across Africa, the authors show that plant-derived sodium availability constrains megaherbivore densities at a continental scale.

    • Andrew J. Abraham
    • Gareth P. Hempson
    • Christopher E. Doughty
    Research
    Nature Ecology & Evolution
    Volume: 10, P: 105-116

  • Climatic variables have played a significant role in plant evolution across the Phanerozoic. Here, the authors link climate with a new dynamic vegetation model to identify two windows of opportunity for plant biomass expansion, corresponding with the expansion of land plants and the angiosperm radiation.

    • Khushboo Gurung
    • Katie J. Field
    • Benjamin J. W. Mills
    ResearchOpen Access
    Nature Communications
    Volume: 13, P: 1-9

  • A state-level analysis of the impact of enhanced weathering deployment on carbon sequestration on agricultural land suggests that enhanced weathering could help the USA meet net-zero 2050 goals.

    • David J. Beerling
    • Euripides P. Kantzas
    • Maria Val Martin
    ResearchOpen Access
    Nature
    Volume: 638, P: 425-434

  • The chemical breakdown of rocks can be enhanced by spreading silicate granules over land. Research suggests that this measure, which increases the rate at which CO2 is locked up in ocean carbonates, could lower atmospheric CO2 by 30–300 ppm by 2100.

    • Lyla L. Taylor
    • Joe Quirk
    • David J. Beerling
    Research
    Nature Climate Change
    Volume: 6, P: 402-406

  • To reduce climate warming we must stop adding CO2 to the atmopshere, and develop approaches for removing it. Adding crushed, fast-reacting silicate rocks to croplands could improve productivity, restore soil quality and reduce atmospheric CO2.

    • David J. Beerling
    • Jonathan R. Leake
    • James Hansen
    Reviews
    Nature Plants
    Volume: 4, P: 138-147