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Ted Takeaways: Podcast 1 - Empathy & Building Inclusive Teams
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The first of two short podcasts with Mr. Ted Coopwood III, DEI practitioner and conservation leader. Podcast I focuses on how to 1) better understand the experiences of diverse colleagues and 2) build inclusive and diverse teams.
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Ted Takeaways: Podcast 2 - Working with Diverse Communities
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The second of two short podcasts with Mr. Ted Coopwood III, DEI practitioner and conservation leader. Podcast II focuses on how to better work with diverse communities in the field.
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Tedla Fernando 1969 New Habitats.pdf
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TRB Library
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TAN-TEV
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Tedla Fernando 1970.pdf
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TRB Library
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TAN-TEV
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Teitelbaum_et_al-2015-Ecology_Letters.pdf
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Climate Science Documents
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Temperature and precipitation controls over leaf- and ecosystem-level CO2 flux along a woody plant encroachment gradient
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Conversion of grasslands to woodlands may alter the sensitivity of CO2 exchange of individual plants and entire ecosystems to air temperature and precipitation. We combined leaf-level gas exchange and ecosystem-level eddy covariance measurements to quantify the effects of plant temperature sensitivity and ecosystem temperature responses within a grassland and mesquite woodland across seasonal precipitation periods. In so doing, we were able to estimate the role of moisture availability on ecosystem temperature sensitivity under large-scale vegetative shifts. Optimum temperatures (Topt) for net photosynthetic assimilation (A) and net ecosystem productivity (NEP) were estimated from a function fitted to A and NEP plotted against air temperature. The convexities of these tem- perature responses were quantified by the range of temperatures over which a leaf or an ecosystem assimilated 50% of maximum NEP (Ω50). Under dry pre- and postmonsoon conditions, leaf-level Ω50 in C3 shrubs were two-to-three times that of C4 grasses, but under moist monsoon conditions, leaf-level Ω50 was similar between growth forms. At the ecosystems-scale, grassland NEP was more sensitive to precipitation, as evidenced by a 104% increase in maxi- mum NEP at monsoon onset, compared to a 57% increase in the woodland. Also, woodland NEP was greater across all temperatures experienced by both ecosystems in all seasons. By maintaining physiological function across a wider temperature range during water-limited periods, woody plants assimilated larger amounts of carbon. This higher carbon-assimilation capacity may have significant implications for ecosystem responses to projected climate change scenarios of higher temperatures and more variable precipitation, particularly as semiarid regions experi- ence conversions from C4 grasses to C3 shrubs. As regional carbon models, CLM 4.0, are now able to incorporate functional type and photosynthetic pathway differences, this work highlights the need for a better integration of the interactive effects of growth form/functional type and photosynthetic pathway on water resource acquisition and temperature sensitivity.
Keywords: eddy covariance, mesquite (Prosopis velutina), net ecosystem exchange, photosynthesis, respiration, temperature optima, vegetative change, woody plant encroachment
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Temperature control of larval dispersal and the implications for marine ecology, evolution, and conservation
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Temperature controls the rate of fundamental biochemical processes
and thereby regulates organismal attributes including development
rate and survival. The increase in metabolic rate with
temperature explains substantial among-species variation in lifehistory
traits, population dynamics, and ecosystem processes.
Temperature can also cause variability in metabolic rate within
species. Here, we compare the effect of temperature on a key
component of marine life cycles among a geographically and
taxonomically diverse group of marine fish and invertebrates.
Although innumerable lab studies document the negative effect of
temperature on larval development time, little is known about the
generality versus taxon-dependence of this relationship. We
present a unified, parameterized model for the temperature dependence
of larval development in marine animals. Because the
duration of the larval period is known to influence larval dispersal
distance and survival, changes in ocean temperature could have
a direct and predictable influence on population connectivity,
community structure, and regional-to-global scale patterns of
biodiversity.
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Temperature increase of 21st century mitigation scenarios
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Estimates of 21st Century global-mean surface temperature in- crease have generally been based on scenarios that do not include climate policies. Newly developed multigas mitigation scenarios, based on a wide range of modeling approaches and socioeconomic assumptions, now allow the assessment of possible impacts of climate policies on projected warming ranges. This article assesses the atmospheric CO2 concentrations, radiative forcing, and tem- perature increase for these new scenarios using two reduced- complexity climate models. These scenarios result in temperature increase of 0.5–4.4°C over 1990 levels or 0.3–3.4°C less than the no-policy cases. The range results from differences in the assumed stringency of climate policy and uncertainty in our understanding of the climate system. Notably, an average minimum warming of 1.4°C (with a full range of 0.5–2.8°C) remains for even the most stringent stabilization scenarios analyzed here. This value is sub- stantially above previously estimated committed warming based on climate system inertia alone. The results show that, although ambitious mitigation efforts can significantly reduce global warming, adaptation measures will be needed in addition to mitigation to reduce the impact of the residual warming.
climate climate policy stabilization integrated assessment scenario
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Temperature Mediated Moose Survival in Northeastern Minnesota
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The earth is in the midst of a pronounced warming trend and temperatures in Minnesota, USA, as elsewhere, are projected to increase. Northern Minnesota represents the southern edge to the circumpolar distribution of moose (Alces alces), a species intolerant of heat. Moose increase their metabolic rate to regulate their core body temperature as temperatures rise. We hypothesized that moose survival rates would be a function of the frequency and magnitude that ambient temperatures exceeded the upper critical temperature of moose. We compared annual and seasonal moose survival in northeastern Minnesota between 2002 and 2008 with a temperature metric. We found that models based on January temperatures above the critical threshold were inversely correlated with subsequent survival and explained .78% of variability in spring, fall, and annual survival. Models based on late-spring temperatures also explained a high proportion of survival during the subsequent fall. A model based on warm-season temperatures was important in explaining survival during the subsequent winter. Our analyses suggest that temperatures may have a cumulative influence on survival. We expect that continuation or acceleration of current climate trends will result in decreased survival, a decrease in moose density, and ultimately, a retreat of moose northward from their current distribution.
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Temperature sensitivity of drought-induced tree mortality portends increased regional die-off under global change-type drought
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Large-scale biogeographical shifts in vegetation are predicted in response to the altered precipitation and temperature regimes associated with global climate change. Vegetation shifts have profound ecological impacts and are an important climate-ecosystem feedback through their alteration of carbon, water, and energy exchanges of the land surface. Of particular concern is the potential for warmer temperatures to compound the effects of increasingly severe droughts by triggering widespread vegetation shifts via woody plant mortality. The sensitivity of tree mortality to temperature is dependent on which of 2 non-mutually-exclusive mechanisms predominates—temperature-sensitive carbon starvation in response to a period of protracted water stress or temperature-insensitive sudden hydraulic failure under extreme water stress (cavitation). Here we show that experimentally induced warmer temperatures (4 °C) shortened the time to drought- induced mortality in Pinus edulis (pin ̃ on shortened pine) trees by nearly a third, with temperature-dependent differences in cumu- lative respiration costs implicating carbon starvation as the primary mechanism of mortality. Extrapolating this temperature effect to the historic frequency of water deficit in the southwestern United States predicts a 5-fold increase in the frequency of regional-scale tree die-off events for this species due to temperature alone. Projected increases in drought frequency due to changes in pre- cipitation and increases in stress from biotic agents (e.g., bark beetles) would further exacerbate mortality. Our results demon- strate the mechanism by which warmer temperatures have exac- erbated recent regional die-off events and background mortality rates. Because of pervasive projected increases in temperature, our results portend widespread increases in the extent and frequency of vegetation die-off.
biosphere–atmosphere feedbacks drought impacts global-change ecology Pinus edulis carbon starvation
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