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  • 1
    Online Resource
    Online Resource
    Climate Change and Rocky Mountain Ecosystems. (2017)
    Cham :Springer International Publishing AG,
    Details
    Keywords: Climatic changes. ; Electronic books.
    Type of Medium: Online Resource
    Pages: 1 online resource (246 pages)
    Edition: 1st ed.
    ISBN: 9783319569284
    Series Statement: Advances in Global Change Research Series ; v.63
    URL: https://ebookcentral.proquest.com/lib/geomar/detail.action?docID=4920993
    Language: English
    Note: Intro -- Dedication -- Foreword -- Preface -- Acknowledgments -- Contents -- Contributors -- Chapter 1: Assessing Climate Change Effects in the Northern Rockies -- 1.1 Introduction -- 1.2 Northern Rockies Adaptation Partnership Process -- 1.3 Toward Implementation of Climate-Smart Management -- 1.4 A Brief Tour of the Northern Rockies -- 1.4.1 Western Rockies Subregion -- 1.4.2 Central Rockies Subregion -- 1.4.3 Eastern Rockies Subregion -- 1.4.4 Greater Yellowstone Area Subregion -- 1.4.5 Grassland Subregion -- References -- Chapter 2: Historical and Projected Climate in the Northern Rockies Region -- 2.1 Introduction -- 2.2 Climate Model Overview -- 2.3 Methods Used to Assess Future Climate in the Northern Rockies Region -- 2.4 Projected Future Climate in the Northern Rockies -- References -- Chapter 3: Effects of Climate Change on Snowpack, Glaciers, and Water Resources in the Northern Rockies -- 3.1 Introduction -- 3.2 Mechanisms for Climate Change Effects on Hydrology -- 3.3 Effects of Climate Change on Snowpack and Glaciers -- 3.4 Effects of Climate Change on Streamflow -- 3.4.1 Future Streamflow Projections -- 3.5 Adapting Water Resources and Management to Climate Change -- References -- Chapter 4: Effects of Climate Change on Cold-Water Fish in the Northern Rockies -- 4.1 Introduction -- 4.2 Analytical Approach -- 4.2.1 Assessment Area -- 4.2.2 Climate Change Scenarios -- 4.2.3 Fish Species -- 4.2.4 Trout Distribution Models -- 4.3 Vulnerability of Native Trout to Climate Change -- 4.3.1 Stream Temperature -- 4.3.2 Cutthroat Trout -- 4.3.3 Bull Trout -- 4.3.4 Additional Fish Species -- 4.4 Applying the Assessment -- 4.5 Adapting Fish Species and Fisheries Management to Climate Change -- 4.5.1 Adaptation Options -- 4.5.2 Principles of Climate-Smart Management -- References. , Chapter 5: Effects of Climate Change on Forest Vegetation in the Northern Rockies -- 5.1 Introduction -- 5.1.1 Climate Change Assessment Techniques -- 5.1.2 Forest Vegetation Responses to Climate -- 5.1.3 Biotic and Abiotic Disturbances -- 5.2 Climate Change Effects on Tree Species -- 5.2.1 Ponderosa Pine (Pinus ponderosa) -- 5.2.2 Douglas-Fir (Pseudotsuga menziesii) -- 5.2.3 Western Larch (Larix occidentalis) -- 5.2.4 Western White Pine (Pinus monticola) -- 5.2.5 Grand Fir (Abies grandis) -- 5.2.6 Western Redcedar (Thuja plicata) -- 5.2.7 Western Hemlock (Tsuga heterophylla) -- 5.2.8 Lodgepole Pine (Pinus contorta var. latifolia) -- 5.2.9 Limber Pine (Pinus flexilis) -- 5.2.10 Subalpine Fir (Abies lasiocarpa) -- 5.2.11 Engelmann Spruce (Picea engelmannii) -- 5.2.12 Mountain Hemlock (Tsuga mertensiana) -- 5.2.13 Alpine Larch (Larix lyallii) -- 5.2.14 Whitebark Pine (Pinus albicaulis) -- 5.2.15 Quaking Aspen (Populus tremuloides) -- 5.2.16 Cottonwood (Populus spp.) -- 5.2.17 Green Ash (Fraxinus pennsylvanica) -- 5.3 Effects of Climate Change on Broader Vegetation Patterns -- 5.4 Natural Resource Issues and Management -- 5.4.1 Landscape Heterogeneity -- 5.4.2 Timber Production -- 5.4.3 Carbon Sequestration -- 5.5 Adapting Forest Vegetation and Management to Climate Change -- 5.5.1 Adaptation Strategies and Tactics -- References -- Chapter 6: Effects of Climate Change on Rangeland Vegetation in the Northern Rockies -- 6.1 Introduction -- 6.2 Rangeland Vegetation -- 6.3 Management Issues -- 6.4 Assessing the Effects of Climate Change on Rangelands -- 6.4.1 Montane Grasslands -- 6.4.2 Montane Shrubs -- 6.4.3 Short Sagebrushes -- 6.4.4 Sprouting Sagebrush Species -- 6.4.5 Wyoming Big Sagebrush and Basin Big Sagebrush -- 6.4.6 Mountain Big Sagebrush -- 6.4.7 Northern Great Plains -- 6.5 Adapting Rangeland Vegetation and Management to Climate Change. , References -- Chapter 7: Effects of Climate Change on Ecological Disturbance in the Northern Rockies -- 7.1 Introduction -- 7.2 Wildfire -- 7.2.1 Overview -- 7.2.2 Potential Future Wildfire Regimes and Wildfire Occurrence -- 7.2.3 Potential Interactions Between Wildfire and Other Disturbances -- 7.3 Bark Beetles -- 7.3.1 Overview -- 7.3.2 Drivers of Bark Beetle Outbreaks -- 7.3.3 Potential Effects of Climate Change on Bark Beetles -- 7.3.4 Projected Effects of Climate Change on Bark Beetle Populations -- 7.4 White Pine Blister Rust -- 7.4.1 Overview -- 7.4.2 Effects of Climate Change on WPBR -- 7.4.3 Interactions with Other Disturbance Processes -- 7.5 Forest Diseases -- 7.5.1 Overview -- 7.5.2 Effects of Climatic Variability and Change on Forest Diseases -- 7.5.3 Forest Pathogen Interactions -- 7.6 Nonnative Plants -- 7.6.1 Overview -- 7.6.2 Effects of Climate Change on Nonnative Species -- References -- Chapter 8: Effects of Climate Change on Wildlife in the Northern Rockies -- 8.1 Climate-Wildlife Interactions -- 8.2 Communities and Habitat -- 8.3 Species Sensitivity to Climate Change -- 8.3.1 American Beaver (Castor canadensis) -- 8.3.2 American Pika (Ochotona princeps) -- 8.3.3 Canada Lynx (Lynx canadensis) -- 8.3.4 Fisher (Pekania pennanti) -- 8.3.5 Moose (Alces alces) -- 8.3.6 Northern Bog Lemming (Synaptomys borealis) -- 8.3.7 Pronghorn (Antilocapra americana) -- 8.3.8 Pygmy Rabbit (Brachylagus idahoensis) -- 8.3.9 Townsend's Big-Eared Bat (Corynorhinus townsendii) -- 8.3.10 Ungulates (Elk, Mule Deer, White-Tailed Deer) -- 8.3.11 Wolverine (Gulo gulo) -- 8.3.12 Brewer's Sparrow (Spizella breweri) -- 8.3.13 Flammulated Owl (Otus flammeolus) -- 8.3.14 Greater Sage-Grouse (Centrocercus urophasianus) -- 8.3.15 Harlequin Duck (Histrionicus histrionicus) -- 8.3.16 Mountain Quail (Oreortyx pictus) -- 8.3.17 Pygmy Nuthatch (Sitta pygmaea). , 8.3.18 Ruffed Grouse (Bonasa umbellus) -- 8.3.19 Columbia Spotted Frog (Rana luteiventris) -- 8.3.20 Western Toad (Anaxyrus boreas) -- 8.4 Adapting Wildlife and Wildlife Management to Climate Change -- References -- Chapter 9: Effects of Climate Change on Recreation in the Northern Rockies -- 9.1 Introduction -- 9.2 Relationships Between Climate Change and Recreation -- 9.3 Outdoor Recreation in the Northern Rockies -- 9.4 Assessing the Vulnerability of Recreation to Climate Change -- 9.4.1 Current Conditions and Management -- 9.4.2 Warm-Weather Activities -- 9.4.3 Cold-Weather Activities -- 9.4.4 Wildlife Activities -- 9.4.5 Gathering Forest Products -- 9.4.6 Water-Based Activities (Not Including Fishing) -- 9.4.7 Summary -- 9.5 Adapting Recreation and Recreation Management to Climate Change -- 9.5.1 Adaptation by Recreation Participants -- 9.5.2 Adaptation by Federal Land Management -- References -- Chapter 10: Effects of Climate Change on Ecosystem Services in the Northern Rockies -- 10.1 Introduction -- 10.2 Ecosystem Services on Public Lands in the Northern Rockies -- 10.3 Social Vulnerability and Adaptive Capacity -- 10.4 Assessing the Effects of Climate Change on Ecosystem Services -- 10.4.1 Water Quantity -- 10.4.2 Water Quality, Aquatic Habitats, and Fish -- 10.4.3 Building Materials and Wood Products -- 10.4.4 Mining Materials -- 10.4.5 Forage for Livestock -- 10.4.6 Viewsheds and Clean Air -- 10.4.7 Regulation of Soil Erosion -- 10.4.8 Carbon Sequestration -- 10.4.9 Summary -- References -- Chapter 11: Effects of Climate Change on Cultural Resources in the Northern Rockies -- 11.1 Background and Cultural Context -- 11.2 Climate Change Effects on Cultural Resources -- 11.2.1 Primary Effects and Stressors -- 11.2.2 Spatial and Temporal Risk Assessment -- 11.3 Adapting Cultural Resources and Management to Climate Change -- References. , Chapter 12: Toward Climate-Smart Resource Management in the Northern Rockies -- 12.1 Partnership and Process -- 12.1.1 Increasing Organizational Capacity to Address Climate Change -- 12.1.2 Implementation: The Path Forward -- References -- Index.
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  • 2
    Online Resource
    Online Resource
    Climate Change and Rocky Mountain Ecosystems (2018)
    Cham : Springer
    Details Availability
    Keywords: Environment ; Climate change ; Ecosystems ; Wildlife ; Fish ; Natural resources ; Rocky Mountains ; Klimaänderung ; Ökosystem
    Description / Table of Contents: This book is the result of a team of approximately 100 scientists and resource managers who worked together for two years to understand the effects of climatic variability and change on water resources, fisheries, forest vegetation, non-forest vegetation, wildlife, recreation, cultural resources and ecosystem services. Adaptation options, both strategic and tactical, were developed for each resource area. This information is now being applied in the northern rocky Mountains to ensure long-term sustainability in resource conditions. The volume chapters provide a technical assessment of the effects of climatic variability and change on natural and cultural resources, based on best available science, including new analyses obtained through modeling and synthesis of existing data. Each chapter also contains a summary of adaptation strategies (general) and tactics (on-the-ground actions) that have been developed by science-management teams
    Type of Medium: Online Resource
    Pages: Online-Ressource (XVII, 236 p. 42 illus., 37 illus. in color, online resource)
    ISBN: 9783319569284
    Series Statement: Advances in Global Change Research 63
    URL: https://doi.org/10.1007/978-3-319-56928-4
    URL: https://swbplus.bsz-bw.de/bsz491754280cov.jpg
    DOI: 10.1007/978-3-319-56928-4
    Language: English
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  • 3
    Electronic Resource
    Electronic Resource
    Effects of Unseeded Areas on Species Richness of Coal Mines Reclaimed with Municipal Biosolids (2005)
    Oxford, UK; Malden, USA : Blackwell Science Inc
    Restoration ecology 13 (2005), S. 0 
    Details
    ISSN: 1526-100X
    Source: Blackwell Publishing Journal Backfiles 1879-2005
    Topics: Biology
    Notes: Land application of municipal biosolids on coal mine spoils can benefit vegetation establishment in mine reclamation. However, the application of biosolids leads to domination by early-successional species, such as grasses, and low establishment of woody and volunteer species, thus reducing potential for forestry as a postmining land use. In this experiment, tree seedlings were planted in strips (0.6-, 1-, and 4-m wide) that were not seeded with grasses, and the effects of unseeded strip width on seedling growth and species richness were assessed. Planted seedling mortality was high; therefore, the effect of unseeded strip width on seedling growth could not be determined. However, it was found that natural plant invasion and species richness were highest in the 4-m unseeded strips. The practice of leaving 4-m-wide unseeded strips in mine reclamation with biosolids in the eastern United States, along with the improvement of tree seedling planting practices and planting stock, would help promote a more species-rich plant community that could be utilized for forestry or a variety of other postmining land uses.
    Type of Medium: Electronic Resource
    URL: http://dx.doi.org/10.1111/j.1526-100X.2005.00081.x
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  • 4
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    Dry forest resilience varies under simulated climate-management scenarios in a central Oregon, USA landscape (2014)
    Wiley-Blackwell
    Details
    Publication Date: 2014-12-01
    Description: Determining appropriate actions to create or maintain landscapes resilient to climate change is challenging because of uncertainty associated with potential effects of climate change and their interactions with land management. We used a set of climate-informed state-and-transition models to explore the effects of management and natural disturbances on vegetation composition and structure under different future climates. Models were run for dry forests of central Oregon under a fire suppression scenario (i.e., no management other than the continued suppression of wildfires) and an active management scenario characterized by light to moderate thinning from below and some prescribed fire, planting, and salvage logging. Without climate change, area in dry province forest types remained constant. With climate change, dry mixed-conifer forests increased in area (by an average of 21?26% by 2100), and moist mixed-conifer forests decreased in area (by an average of 36?60% by 2100), under both management scenarios. Average area in dry mixed-conifer forests varied little by management scenario, but potential decreases in the moist mixed-conifer forest were lower with active management. With changing climate in the dry province of central Oregon, our results suggest the likelihood of sustaining current levels of dense, moist mixed-conifer forests with large-diameter, old trees is low (less than a 10% chance) irrespective of management scenario; an opposite trend was observed under no climate change simulations. However, results also suggest active management within the dry and moist mixed-conifer forests that creates less dense forest conditions can increase the persistence of larger-diameter, older trees across the landscape. Owing to projected increases in wildfire, our results also suggest future distributions of tree structures will differ from the present. Overall, our projections indicate proactive management can increase forest resilience and sustain some societal values, particularly in drier forest types. However, opportunities to create more disturbance-adapted systems are finite, all values likely cannot be sustained at current levels, and levels of resilience success will likely vary by dry province forest type. Land managers planning for a future without climate change may be assuming a future that is unlikely to exist. # doi:10.1890/13-1653.1
    Print ISSN: 1051-0761
    Electronic ISSN: 1939-5582
    Topics: Biology
    Published by Wiley-Blackwell on behalf of The Ecological Society of America (ESA).
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