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Drivers of global land use change : are increasing demands for food and bioenergy offset by technological change and yield increase?

Engstrom, Kerstin LU (2013)
Abstract
Globally, the food and energy demands of the growing global population are rising and require increased agricultural

production. Additionally, climate change will have adverse effects on agricultural productivity. Technological change can

contribute to closing yield gaps and reducing post-harvest losses, but needs to be facilitated through investments and

education. Considering the multiple drivers of the land system and their complex interactions, it is one of the great challenges

of the 21st century to find solutions for how to sustainably increase food and bioenergy production. This requires

understanding of land use change, its drivers and their multiple interactions. Here, a parsimonious... (More)
Globally, the food and energy demands of the growing global population are rising and require increased agricultural

production. Additionally, climate change will have adverse effects on agricultural productivity. Technological change can

contribute to closing yield gaps and reducing post-harvest losses, but needs to be facilitated through investments and

education. Considering the multiple drivers of the land system and their complex interactions, it is one of the great challenges

of the 21st century to find solutions for how to sustainably increase food and bioenergy production. This requires

understanding of land use change, its drivers and their multiple interactions. Here, a parsimonious land use model (PLUM) is

developed and a review of global scenarios of environmental change is carried out to address the question of how drivers of

environmental change, including lifestyle-related dietary changes, bioenergy production, and technological change, will affect

future land use. The results of the model development and evaluation suggest that a parsimonious approach can contribute to

understanding and exploring solutions to the challenge outlined above. The model can reproduce agricultural land use at the

global and regional scale and at the same time the approach is explicit about uncertainties in model input parameters and the

quantification of uncertainty ranges for each model output. The exploration of the uncertainty range of the model parameters

showed that global cereal land is strongly affected by changes in cereal yields in developing countries. The increasing

demand for food, represented by cereals, milk and meat, had in the past 20 years only very little influence on expanding

agricultural land. The results of the review of bioenergy representation in global scenario studies show that assumptions

related to technological change, such as yield increase and efficiency of bioenergy production, are essential for the projected

land use for bioenergy in the future. The projected land use for bioenergy in the reviewed scenarios spans 0.2-10% of total

global area in 2100, which can be considered a wide range, given that current cropland is about 12% of global land area.

Further, the research suggests that high primary energy requirements, mitigation strategies, or a combination of these driving

forces, will in any case stimulate an increased bioenergy production in the future. (Less)
Please use this url to cite or link to this publication:
author
supervisor
organization
publishing date
type
Thesis
publication status
published
subject
keywords
Global land use change, food demands, bioenergy demands, technological change, modelling, scenarios, uncertainty
pages
105 pages
publisher
Department of Physical Geography and Ecosystem Science, Lund University
ISBN
978-91-85793-33-4
language
English
LU publication?
yes
id
d7000603-634b-49d6-8d5e-cdc16b727221 (old id 4732711)
alternative location
http://www.sub.su.se/start/sok/soktraff/?librisid=13987674
date added to LUP
2016-04-04 11:49:17
date last changed
2019-03-22 11:32:38
@misc{d7000603-634b-49d6-8d5e-cdc16b727221,
  abstract     = {{Globally, the food and energy demands of the growing global population are rising and require increased agricultural<br/><br>
production. Additionally, climate change will have adverse effects on agricultural productivity. Technological change can<br/><br>
contribute to closing yield gaps and reducing post-harvest losses, but needs to be facilitated through investments and<br/><br>
education. Considering the multiple drivers of the land system and their complex interactions, it is one of the great challenges<br/><br>
of the 21st century to find solutions for how to sustainably increase food and bioenergy production. This requires<br/><br>
understanding of land use change, its drivers and their multiple interactions. Here, a parsimonious land use model (PLUM) is<br/><br>
developed and a review of global scenarios of environmental change is carried out to address the question of how drivers of<br/><br>
environmental change, including lifestyle-related dietary changes, bioenergy production, and technological change, will affect<br/><br>
future land use. The results of the model development and evaluation suggest that a parsimonious approach can contribute to<br/><br>
understanding and exploring solutions to the challenge outlined above. The model can reproduce agricultural land use at the<br/><br>
global and regional scale and at the same time the approach is explicit about uncertainties in model input parameters and the<br/><br>
quantification of uncertainty ranges for each model output. The exploration of the uncertainty range of the model parameters<br/><br>
showed that global cereal land is strongly affected by changes in cereal yields in developing countries. The increasing<br/><br>
demand for food, represented by cereals, milk and meat, had in the past 20 years only very little influence on expanding<br/><br>
agricultural land. The results of the review of bioenergy representation in global scenario studies show that assumptions<br/><br>
related to technological change, such as yield increase and efficiency of bioenergy production, are essential for the projected<br/><br>
land use for bioenergy in the future. The projected land use for bioenergy in the reviewed scenarios spans 0.2-10% of total<br/><br>
global area in 2100, which can be considered a wide range, given that current cropland is about 12% of global land area.<br/><br>
Further, the research suggests that high primary energy requirements, mitigation strategies, or a combination of these driving<br/><br>
forces, will in any case stimulate an increased bioenergy production in the future.}},
  author       = {{Engstrom, Kerstin}},
  isbn         = {{978-91-85793-33-4}},
  keywords     = {{Global land use change; food demands; bioenergy demands; technological change; modelling; scenarios; uncertainty}},
  language     = {{eng}},
  note         = {{Licentiate Thesis}},
  publisher    = {{Department of Physical Geography and Ecosystem Science, Lund University}},
  title        = {{Drivers of global land use change : are increasing demands for food and bioenergy offset by technological change and yield increase?}},
  url          = {{http://www.sub.su.se/start/sok/soktraff/?librisid=13987674}},
  year         = {{2013}},
}