Characterizing the long-term variability of snow-cover extent over the interior of North America

Brown, Ross; Hughes, Marilyn G.; Robinson, David A.

doi:10.3189/s0260305500015585

Cited by 15 publications

(13 citation statements)

References 16 publications

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“…The experiment fails to warm the air over the unenclosed plots, it does not increase CO 2 , and it does not address potential and poorly understood changes in precipitation. Although most models of climate change predict earlier snowmelt and/or later initial snow accumulation (Boer et al ., 1992; Brown et al ., 1994; CSIRO, 1994; Whetton et al ., 1996), other models of the potential consequences of climate change for winter precipitation in our study area suggest increases in snowpack (Giorgi et al ., 1998). There is evidence that this is indeed occurring.…”

Section: Discussionmentioning

confidence: 99%

Changes in flowering and abundance of Delphinium nuttallianum (Ranunculaceae) in response to a subalpine climate warming experiment

Saavedra

Inouye

Price

et al. 2003

Global Change Biology

103

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High‐altitude and high‐latitude sites are expected to be very sensitive to global warming, because the biological activity of most plants is restricted by the length of the short snow‐free season, which is determined by climate. Long‐term observational studies in subalpine meadows of the Colorado Rocky Mountains have shown a strong positive correlation between snowpack and flower production by the forb Delphinium nuttallianum. If a warmer climate reduces annual snowfall in this region then global warming might reduce fitness in D. nuttallianum. In this article we report effects of experimental warming on the abundance and flower production of D. nuttallianum. Plant abundance (both flowering and vegetative plants) was slightly greater on warmed than control plots prior to initiation of the warming treatment in 1991. Since 1994 experimental warming has had a negative effect on D. nuttallianum flower production, reducing both the abundance of flowering plants and the total number of flowers per plant. Flower bud abortion was higher in the heated plots than the controls only in 1994 and 1999. Results from both the warming experiment and analyses of unmanipulated long‐term plots suggest that global warming may affect the fecundity of D. nuttallianum, which may have cascading effects on the pollinators that depend on it and on the fecundity of plants that share similar pollinators.

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Section: Discussionmentioning

confidence: 99%

Changes in flowering and abundance of Delphinium nuttallianum (Ranunculaceae) in response to a subalpine climate warming experiment

Saavedra

Inouye

Price

et al. 2003

Global Change Biology

103

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“…Global warming in high elevation and latitude regions is likely to alter snow regimes, including reductions in snowpack levels and shorter periods of winter snow coverage (e.g., Brown et al 1994, Whetton et al 1996). Many researchers have reported strong relationships between snowpack timing and structure and various aspects of plant performance including distribution, growth, productivity, flowering phenology, and reproductive success (see Dunne et al 2003 for overview).…”

Section: Case Study 1: Plant Flowering Phenologymentioning

confidence: 99%

Integrating Experimental and Gradient Methods in Ecological Climate Change Research

Dunne

Saleska

Fischer

et al. 2004

Ecology

244

255

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Field‐based research on the responses of ecosystems to anthropogenic climate change has primarily used either natural gradient or experimental methods. Taken separately, each approach faces methodological, spatial, and temporal limitations that potentially constrain the generality of results and predictions. Integration of the two approaches within a single study can overcome some of those limitations and provide ways to distinguish among consistent, dynamic, and context‐dependent ecosystem responses to global warming. A simple conceptual model and two case studies that focus on climate change impacts on flowering phenology and carbon cycling in a subalpine meadow ecosystem illustrate the utility of this type of integration.

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“…4 Present address: Santa Fe Institute, 1399 Hyde Park Road, Santa Fe, New Mexico 87501 USA. E-mail: jdunne@santafe.edu pack, scientists predict that global warming will significantly reduce the duration and extent of snow cover during the year (Boer et al 1992, Brown et al 1994, CSIRO 1994, Whetton et al 1996, with some changes already occurring (Baumgartner and Apfl 1994, Groisman et al 1994, IPCC 2001. In northern montane regions, climate change may lead to more winter precipitation, resulting in initial increases in snowpack at high elevations (Johnson 1998, Inouye et al 2000.…”

Section: Introductionmentioning

confidence: 99%

Subalpine Meadow Flowering Phenology Responses to Climate Change: Integrating Experimental and Gradient Methods

Dunne

Harte

Taylor

2003

Ecological Monographs

406

381

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We integrated experimental and natural gradient field methods to investigate effects of climate change and variability on flowering phenology of 11 subalpine meadow shrub, forb, and graminoid species in Gunnison County, Colorado (USA). At a subalpine meadow site, overhead electric radiant heaters advanced snowmelt date by 16 d and warmed and dried soil during the growing season. At three additional sites, a snow removal manipulation advanced snowmelt date by 7 d without altering growing season soil microclimate. We compared phenological responses to experimental climate change with responses to natural microclimate variability across spatial gradients at small and landscape scales, as well as across a temporal gradient from a separate study. Both manipulations significantly advanced timing of flowering for the group of species and for most species individually, closely paralleling responses of timing to natural spatial and temporal variability in snowmelt date. Snowmelt date singularly explained observed shifts in timing only in the earliest flowering species, Claytonia lanceolata. Among all other species except Artemisia tridentata var. vaseyana, the latest flowering species, a consistent combination of temperature‐related microclimate factors (earlier snowmelt date, warmer soil temperatures, and decreased soil degree‐days) substantially explained earlier timing. Both manipulations also extended flowering duration for the group of species, similar to species' responses to natural snowmelt variability at small spatial scales. However, only early flowering species displayed consistent, significant changes in duration, with extended duration related to earlier snowmelt or warmer spring soil temperatures. Soil moisture was generally not a significant explanatory factor for either timing or duration of flowering. Best‐fit microclimate models explained an average of 82% of variation in timing but only 38% of variation in duration across species. Our research demonstrates the value of comparing and synthesizing results of multiple field methods within a single study. This integrated approach makes it easier to identify robust community‐wide trends, as well as species‐specific responses of phenology to climate change. The predicted short‐term flowering phenology responses to temperature‐related aspects of climate change may lead to longer term asynchronies in interspecific interactions, potentially altering population and evolutionary dynamics, community structure, and ecosystem functioning. Corresponding Editor: S. C. Pennings

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Characterizing the long-term variability of snow-cover extent over the interior of North America

Cited by 15 publications

References 16 publications

Changes in flowering and abundance of Delphinium nuttallianum (Ranunculaceae) in response to a subalpine climate warming experiment

Changes in flowering and abundance of Delphinium nuttallianum (Ranunculaceae) in response to a subalpine climate warming experiment

Integrating Experimental and Gradient Methods in Ecological Climate Change Research

Subalpine Meadow Flowering Phenology Responses to Climate Change: Integrating Experimental and Gradient Methods

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