Vegetation-mediated feedback in water, carbon, nitrogen and phosphorus cycles
Publication date
2013
Authors
Wassen, M.J.
Boer, H.J. de
Fleischer, K.
Rebel, K.T.
Dekker, S.C.
Editors
Advisors
Supervisors
Document Type
Article
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(c) UU Universiteit Utrecht, 2013
Abstract
Since the industrial revolution, industry,
traffic and the manufacture and application of nitrogenous
fertilizers have increased carbon dioxide emissions
and accelerated the nitrogen (N) cycle. The combined
effects of a warming climate,CO2 fertilization, land-use
change and increased N availabilitymay be responsible
for primary productivity increases in many parts of the
world. Enhanced productivity may lead to shifts in
albedo and transpiration, which feed back to the water
cycle through heat fluxes and precipitation. Plants may
also respond to elevated CO2 by closing their stomata or
by structurally adapting their stomatal density and size,
which potentially diminishes transpiration. Intensification
of agriculture has also led to an increase in both
nitrogenous (N) and phosphorus (P) fertilization. The
combined effect of atmospheric N deposition and P
fertilization has distorted the balance between N and P
availability in many ecosystems. The active role of
plants in accessing nutrients from the soil may trigger
switches in nutrient availability, triggering shifts in
plant productivity and species composition in these
ecosystems and therefore also in the carbon (C) cycle.
In response to global change, the above plant responses
may influence each other positively or negatively and
may impact on the elemental cycles of C, N and P and
the water cycle. We are only beginning to understand
how these four cycles interact, the role of plant
processes and vegetation in these interactions, and the
net outcome for plant competition, vegetation distribution,
landscape development and directions of global
change. In this paper we have integrated a number of
recent research findings into known relationships that
together elucidate interactions between these cycles
through vegetation, and could potentially have unexpected
effects on landscapes and larger-scale systems
(continental, global). These interactions include processes
operating at very distinct temporal and spatial
scales, in which terrestrial ecosystems and their spatial
organization in the landscape are key.We argue that to
better understand the effects of changes in land cover
and land use on biogeochemical and biogeophysical
fluxes, it is necessary to account for feedbacks via
vegetation and how these interfere with elemental
cycles. Finally, we suggest directions for further
research to fill the current knowledge gaps.
Keywords
Carbon, Nitrogen, Phosphorus, Nutrients, Stomata, Global climate change, Plants, Water, Ecosystem, Feedbacks, Scales