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Financial Costs of Meeting Global Biodiversity Conservation Targets: Current Spending and Unmet Needs
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World governments have committed to halting human-induced extinctions and safeguarding
important sites for biodiversity by 2020, but the financial costs of meeting these targets are
largely unknown. We estimate the cost of reducing the extinction risk of all globally threatened
bird species (by ≥1 International Union for Conservation of Nature Red List category) to be
U.S. $0.875 to $1.23 billion annually over the next decade, of which 12% is currently funded.
Incorporating threatened nonavian species increases this total to U.S. $3.41 to $4.76 billion
annually. We estimate that protecting and effectively managing all terrestrial sites of global
avian conservation significance (11,731 Important Bird Areas) would cost U.S. $65.1 billion
annually. Adding sites for other taxa increases this to U.S. $76.1 billion annually. Meeting
these targets will require conservation funding to increase by at least an order of magnitude.
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Simultaneously Mitigating Near-Term Climate Change and Improving Human Health and Food Security
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Tropospheric ozone and black carbon (BC) contribute to both degraded air quality and global
warming. We considered ~400 emission control measures to reduce these pollutants by using
current technology and experience. We identified 14 measures targeting methane and BC
emissions that reduce projected global mean warming ~0.5°C by 2050. This strategy avoids 0.7
to 4.7 million annual premature deaths from outdoor air pollution and increases annual crop
yields by 30 to 135 million metric tons due to ozone reductions in 2030 and beyond. Benefits
of methane emissions reductions are valued at $700 to $5000 per metric ton, which is well
above typical marginal abatement costs (less than $250). The selected controls target different
sources and influence climate on shorter time scales than those of carbon dioxide–reduction
measures. Implementing both substantially reduces the risks of crossing the 2°C threshold.
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Carbon Storage with Benefits
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Biochar—a material related to charcoal—has the potential to benefit farming as well as mitigate climate change.
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Biotic Multipliers of Climate Change
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A focus on species interactions may improve predictions of the effects of climate change
on ecosystems.
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Old Trees: Extraction, Conservation Can Coexist
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BECAUSE LARGE OLD TREES ARE ESSENTIAL FOR FOREST ECOSYSTEM INTEGRITY AND BIODIVERsity,
timber extraction in managed forests should preferentially be concentrated where large old
trees are least likely to develop (“Global decline in large old trees,” D. B. Lindenmayer et al.,
Perspectives, 7 December 2012, p. 1305). However, timber extraction and the conservation of
large old trees are not necessarily mutually exclusive.
Current forest policy and management practices in Flanders, Belgium, aim to convert
even-aged stands (areas in which trees are all the same age) to stands with trees of varying
ages in an effort to increase forest ecosystem stability and resilience and to allow trees to
grow old. As part of their ecologically sustainable forest management, public forest managers
have adopted a large-tree retention approach [see also (1, 2)]. Tree islands within
stands managed for production of high-quality timber are reserved for conservation, and
trees within these islands will never be extracted. Large old trees of commercially valuable
species that have grown beyond the commercially optimal dimensions will
not be logged either. And no tree beyond a threshold diameter [currently set at
dbh (diameter at breast height) of more than 102 cm] will ever be logged. The
strip-shelterwood system (in which trees are cut in linear strips and surrounding
trees are given time to grow old) and the coppice-with-standards system
(in which some trees are left to grow while others around them are cut) are
two examples of forest management that allows the combination of sustainable
forest exploitation and conservation of large old trees
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What Does Zero Deforestation Mean?
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Ambiguous defi nitions and metrics create risks
for forest conservation and accountability.
SCIENCE VOL 342
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Physical Laws Shape Biology
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IN THE PERSPECTIVE “A DYNAMICAL-SYSTEMS VIEW OF STEM CELL
biology” (12 October 2012, p. 215), C. Furusawa and K. Kaneko discuss
the relevance of dynamic systems biology approaches and the
concept of “attractors” to understand cell differentiation and proliferation.
We share their excitement in using computational models that
apply physical laws to cell fate decision.
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Water in the Balance
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Satellite data may enable improved management of regional groundwater reserves.
VOL 340 SCIENCE
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Enhanced Seasonal Exchange of CO2 by Northern Ecosystems Since 1960
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Seasonal variations of atmospheric carbon dioxide (CO2) in the Northern Hemisphere have increased since the 1950s, but sparse observations have prevented a clear assessment of the patterns of long-term change and the underlying mechanisms. We compare recent aircraft-based observations of CO2 above the North Pacific and Arctic Oceans to earlier data from 1958 to 1961 and find that the seasonal amplitude at altitudes of 3 to 6 km increased by 50% for 45° to 90°N but by less than 25% for 10° to 45°N. An increase of 30 to 60% in the seasonal exchange of CO2 by northern extratropical land ecosystems, focused on boreal forests, is implicated, substantially more than simulated by current land ecosystem models. The observations appear
to signal large ecological changes in northern forests and a major shift in the global carbon cycle.
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Pathways for Conservation
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NEXT WEEK, CONSERVATION SCIENTISTS WILL GATHER AT THE INTERNATIONAL CONGRESS FOR
Conservation Biology (ICCB) in Baltimore, Maryland, to grapple with the challenges of
preserving our natural world in the face of a growing and increasingly consumptive human
population. The natural world provides countless services, such as clean water, protection
from fl ooding, and carbon sequestration, while offering opportunities for new medicines,
foods, and energy production. Yet these valuable services and opportunities are disappearing
along with the species and natural areas that supply them. The needs of a growing human
population must be met while conserving the planet’s natural systems. Accomplishing both
will depend on making clearer connections between scientifi c results regarding issues such
as biodiversity loss and the critical decisions that must be made about conditions that underlie
change, such as greenhouse gas emissions and freshwater availability. The good news is
that today’s conservation scientists are developing innovative tools
and strategies.
SCIENCE VOL 341
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