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Forest Management for bobwhites
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Trees play an important role in the well-being of bobwhites. Michael Hook of the SCDNR talks about how to manage forested land for both bobwhites and dollars.
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Webinars and Instructional Videos
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Bobwhite Quail Seminar Series
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Forest Management for Northern Bobwhite Quail
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In this webinar, Steve Chapman, NBCI Forestry Coordinator, will discuss pine forest management opportunities and practices that can not only help to bring back the bobwhite but also can have an impact on slowing the decline of those numerous songbird, pollinator and other wildlife species.
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NBCI Bobwhite Seminars
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Forester 1980.pdf
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TRB Library
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FIN-GEN
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Forests fuel fish growth in freshwater deltas
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Aquatic ecosystems are fuelled by biogeochemical inputs from surrounding lands and within- lake primary production. Disturbances that change these inputs may affect how aquatic ecosystems function and deliver services vital to humans. Here we test, using a forest cover gradient across eight separate catchments, whether disturbances that remove terrestrial biomass lower organic matter inputs into freshwater lakes, thereby reducing food web productivity. We focus on deltas formed at the stream-lake interface where terrestrial-derived particulate material is deposited. We find that organic matter export increases from more forested catchments, enhancing bacterial biomass. This transfers energy upwards through communities of heavier zooplankton, leading to a fourfold increase in weights of plankti- vorous young-of-the-year fish. At least 34% of fish biomass is supported by terrestrial primary production, increasing to 66% with greater forest cover. Habitat tracers confirm fish were closely associated with individual catchments, demonstrating that watershed protection and restoration increase biomass in critical life-stages of fish.
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Climate Science Documents
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Forests in Decline: Yellow-Cedar Research Yields Prototype for Climate Change Adaptation Planning
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Yellow-cedar has been dying across
600 miles of North Pacific coastal rain
forest—from Alaska to British Columbia—since
about 1880. Thirty years
ago, a small group of pathologists began
investigating possible biotic causes
of the decline. When no biotic cause
could be found, the scope broadened
into a research program that eventually
encompassed the fields of ecology,
soils, hydrology, ecophysiology, dendrochronology,
climatology, and landscape
analysis. Combined studies ultimately
revealed that the loss of this culturally,
economically, and ecologically valuable
tree is caused by a warming climate,
reduced snowpack, poor soil drainage,
and the species’ shallow roots. These
factors lead to fine-root freezing, which
eventually kills the trees.
The considerable knowledge gained
while researchers sought the cause
of widespread yellow-cedar mortality
forms the basis for a conservation
and adaptive management strategy. A
new approach to mapping that overlays
topography, cedar populations, soil
drainage, and snow enables land managers
to pinpoint locations where yellowcedar
habitat is expected to be suitable
or threatened in the future, thereby
bringing climate change predictions into
management scenarios.
The research program serves as a
prototype for evaluating the effects of
climate change in other landscapes. It
shows the value of long-term, multidisciplinary
research that encourages scientists
and land managers to work together
toward developing adaptive management
strategies
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Forests Videos and Webinars
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Videos and Webinars
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Forsyth McCallum 1978 New Zealand.pdf
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TRB Library
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FIN-GEN
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Four-year response of underplanted American chestnut (Castanea dentata) and three competitors to midstory removal, root trenching, and weeding treatments in an oak-hickory forest
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American chestnut (Castanea dentata) has been killed or reduced to recurrent stump sprouts throughout its range following the importation of multiple pathogens in the 19th and early 20th centuries. Under- standing what drives chestnut growth and survival would aid the development of appropriate silvicultural guidelines for restoring the species once blight resistant stock is available. Here we compare the response of planted American and hybrid chestnut seedlings to that of important competitors, northern red oak (Quercus rubra), sugar maple (Acer saccharum) and red maple (A. rubrum), under treatments designed to evaluate the effects of various sources of competition on seedling growth and survival. After four years, American and hybrid chestnut was significantly taller in trenched plots (181.8 ± 12.4 cm; mean ± SE) compared to untrenched plots (127.5 ± 7.9 cm), weeded plots (174.5 ± 12.7 cm) compared to unweeded plots (130.1 ± 6.5 cm) and in midstory removal plots (156.6 ± 7.8) versus full canopy (88.8 ± 11.7 cm), and had outperformed the other species in most competitive environments. Chestnut was the only species to respond to every treatment with significant growth increases, displaying a nota- ble ability to capture growing space when it became available. We suggest that American chestnut res- toration may be more successful where early stand management provides chestnut a brief period of reduced competition. Specifically, midstory removal can increase survival and growth of underplanted American chestnut, and when combined with multi-stage shelterwood removals of the overstory and some amount of competition control, may constitute a viable restoration strategy for chestnut in many of the eastern oak-hickory forests where it was originally dominant.
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Fox 1924.pdf
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TRB Library
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FIN-GEN
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Fragmentation and thermal risks from climate change interact to affect persistence of native trout in the Colorado River basin
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Impending changes in climate will interact with other stressors to threaten aquatic ecosystems and their biota. Native Colorado River cutthroat trout (CRCT; Oncorhynchus clarkii pleuriticus) are now relegated to 309 isolated high- elevation (>1700 m) headwater stream fragments in the Upper Colorado River Basin, owing to past nonnative trout invasions and habitat loss. Predicted changes in climate (i.e., temperature and precipitation) and resulting changes in stochastic physical disturbances (i.e., wildfire, debris flow, and channel drying and freezing) could further threaten the remaining CRCT populations. We developed an empirical model to predict stream temperatures at the fragment scale from downscaled climate projections along with geomorphic and landscape variables. We coupled these spa- tially explicit predictions of stream temperature with a Bayesian Network (BN) model that integrates stochastic risks from fragmentation to project persistence of CRCT populations across the upper Colorado River basin to 2040 and 2080. Overall, none of the populations are at risk from acute mortality resulting from high temperatures during the warmest summer period. In contrast, only 37% of populations have a ! 90% chance of persistence for 70 years (simi- lar to the typical benchmark for conservation), primarily owing to fragmentation. Populations in short stream frag- ments <7 km long, and those at the lowest elevations, are at the highest risk of extirpation. Therefore, interactions of stochastic disturbances with fragmentation are projected to be greater threats than warming for CRCT populations. The reason for this paradox is that past nonnative trout invasions and habitat loss have restricted most CRCT popula- tions to high-elevation stream fragments that are buffered from the potential consequences of warming, but at risk of extirpation from stochastic events. The greatest conservation need is for management to increase fragment lengths to forestall these risks.
Keywords: climate change, cutthroat trout, fragmentation, multiple stressors, native fish, stream temperature model, stream warming
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