ArticlePDF Available

Elevation-Dependent Temperature Trends in the Rocky Mountain Front Range: Changes over a 56- and 20-Year Record

PLOS
PLOS ONE
Authors:
Chris R McGuire
Chris R McGuire
Chris R McGuire
  • This person is not on ResearchGate, or hasn't claimed this research yet.
Cesar Nufio at Howard Hughes Medical Institute
Cesar Nufio
M. Deane Bowers at University of Colorado Boulder
M. Deane Bowers
Robert Penn Guralnick at University of Florida
Robert Penn Guralnick
Download full-text PDFDownload full-text PDF
Read full-text
Download citation

Abstract and Figures

Determining the magnitude of climate change patterns across elevational gradients is essential for an improved understanding of broader climate change patterns and for predicting hydrologic and ecosystem changes. We present temperature trends from five long-term weather stations along a 2077-meter elevational transect in the Rocky Mountain Front Range of Colorado, USA. These trends were measured over two time periods: a full 56-year record (1953-2008) and a shorter 20-year (1989-2008) record representing a period of widely reported accelerating change. The rate of change of biological indicators, season length and accumulated growing-degree days, were also measured over the 56 and 20-year records. Finally, we compared how well interpolated Parameter-elevation Regression on Independent Slopes Model (PRISM) datasets match the quality controlled and weather data from each station. Our results show that warming signals were strongest at mid-elevations over both temporal scales. Over the 56-year record, most sites show warming occurring largely through increases in maximum temperatures, while the 20-year record documents warming associated with increases in maximum temperatures at lower elevations and increases in minimum temperatures at higher elevations. Recent decades have also shown a shift from warming during springtime to warming in July and November. Warming along the gradient has contributed to increases in growing-degree days, although to differing degrees, over both temporal scales. However, the length of the growing season has remained unchanged. Finally, the actual and the PRISM interpolated yearly rates rarely showed strong correlations and suggest different warming and cooling trends at most sites. Interpretation of climate trends and their seasonal biases in the Rocky Mountain Front Range are dependent on both elevation and the temporal scale of analysis. Given mismatches between interpolated data and the directly measured station data, we caution against an over-reliance on interpolation methods for documenting local patterns of climatic change.
Topographic relief map showing locations of RMFR transect and important stations used for infilling and data correction (Denver station not shown). doi:10.1371/journal.pone.0044370.g001
Topographic relief map showing locations of RMFR transect and important stations used for infilling and data correction (Denver station not shown). doi:10.1371/journal.pone.0044370.g001
… 
Seasonal warming at the four survey sites. Ten-year mean temperatures from March through August across the survey sites for the years during Alexander's original survey (1955-1964) and the years including and prior to the resurvey (1999-2008). NS = Not Significant, * P = 0.01, ** P = 0.001, *** P = 0.0002. doi:10.1371/journal.pone.0012977.g001
Seasonal warming at the four survey sites. Ten-year mean temperatures from March through August across the survey sites for the years during Alexander's original survey (1955-1964) and the years including and prior to the resurvey (1999-2008). NS = Not Significant, * P = 0.01, ** P = 0.001, *** P = 0.0002. doi:10.1371/journal.pone.0012977.g001
… 
Yearly temperature trends derived by linear regressions for the periods of 1953–2008 (56-year) and 1989–2008 (20-year) across the RMFR transect. Trends shown as changes in the average yearly (A) mean, (B) maximum and (C) minimum temperatures ( u C) per year. Significance level of regressions denoted by * p , 0.05, ** p , 0.01. doi:10.1371/journal.pone.0044370.g002
Yearly temperature trends derived by linear regressions for the periods of 1953–2008 (56-year) and 1989–2008 (20-year) across the RMFR transect. Trends shown as changes in the average yearly (A) mean, (B) maximum and (C) minimum temperatures ( u C) per year. Significance level of regressions denoted by * p , 0.05, ** p , 0.01. doi:10.1371/journal.pone.0044370.g002
… 
Monthly temperature trends derived by linear regressions over a fifty-six-year period (1953–2008) across the RMFR transect. Trends shown as changes in the average monthly (A) maximum and (B) minimum temperatures ( u C) per year. Significance level of regression denoted by * p , 0.05. doi:10.1371/journal.pone.0044370.g003
Monthly temperature trends derived by linear regressions over a fifty-six-year period (1953–2008) across the RMFR transect. Trends shown as changes in the average monthly (A) maximum and (B) minimum temperatures ( u C) per year. Significance level of regression denoted by * p , 0.05. doi:10.1371/journal.pone.0044370.g003
… 
Monthly temperature trends derived by linear regressions over a twenty-year period (1989–2008) across the RMFR transect. Trends shown as changes in the average monthly (A) maximum and (B) minimum temperatures ( u C) per year. Significance level of regression denoted by * p , 0.05. doi:10.1371/journal.pone.0044370.g004
+1
Monthly temperature trends derived by linear regressions over a twenty-year period (1989–2008) across the RMFR transect. Trends shown as changes in the average monthly (A) maximum and (B) minimum temperatures ( u C) per year. Significance level of regression denoted by * p , 0.05. doi:10.1371/journal.pone.0044370.g004
… 
Figures - uploaded by Cesar Nufio
Author content
All figure content in this area was uploaded by Cesar Nufio
Content may be subject to copyright.
Nufioetal2010AlexanderResurv
ey.pdf
Content uploaded by Cesar Nufio
Author content
All content in this area was uploaded by Cesar Nufio
Content may be subject to copyright.
Elevation-Dependent Temperature Trends in the Rocky Mountain Front Range: Changes over a 56- and 20-Year Reco
rd.pdf
Available via license: CC BY 4.0
Content may be subject to copyright.
A preview of the PDF is not available

Supplementary resource (1)

Appendix S1
Data
September 2012
Chris R. McGuire · Cesar Nufio · M. Deane Bowers · Robert Penn Guralnick
... At Niwot Ridge, CO, a Long-Term Ecological Research (LTER) site, a 70-year climate record shows that maximum annual temperatures have been increasing faster than the global rate at ∼0.5°C/decade (McGuire et al., 2012). Concurrent shifts in environmental conditions including precipitation and atmospheric deposition complicate efforts to understand alpine rates of response to warming. ...
... Niwot Ridge has a mean annual temperature of −2.2°C and receives 884 mm of precipitation annually. Long term climate measurements from 1953-present at the D-1 site that hosts the highest elevation long-term weather station in North America at 3,749 m asl show a strong warming trend at Niwot Ridge during the spring and summer months (Bueno de Mesquita et al., 2021;McGuire et al., 2012). Precipitation patterns are highly variable and show a slight increase over time at alpine sites (Kittel et al., 2015). ...
Topographic Heterogeneity and Aspect Moderate Exposure to Climate Change Across an Alpine Tundra Hillslope
Article
Full-text available
  • Oct 2023
Alpine tundra ecosystems are highly vulnerable to climate warming but are governed by local‐scale abiotic heterogeneity, which makes it difficult to predict tundra responses to environmental change. Although land models are typically implemented at global scales, they can be applied at local scales to address process‐based ecological questions. In this study, we ran ecosystem‐scale Community Land Model (CLM) simulations with a novel hillslope hydrology configuration to represent topographically heterogeneous alpine tundra vegetation across a moisture gradient at Niwot Ridge, Colorado, USA. We used local observations to evaluate our simulations and investigated the role of topography and aspect in mediating patterns of snow, productivity, soil moisture, and soil temperature, as well as the potential exposure to climate change across an alpine tundra hillslope. Overall, our simulations captured observed gradients in abiotic conditions and productivity among heterogeneous, hydrologically connected vegetation communities (moist, wet, and dry). We found that south facing aspects were characterized by reduced snowpack and drier and warmer soils in all communities. When we extended our simulations to the year 2100, we found that earlier snowmelt altered the timing of runoff, with cascading effects on soil moisture, productivity, and growing season length. However, these effects were not distributed equally across the tundra, highlighting potential vulnerabilities of alpine vegetation in dry, wind‐scoured, and south facing areas. Overall, our results demonstrate how land model outputs can be applied to advance process‐based understanding of climate change impacts on ecosystem function.
View
... Elevation-dependent warming (EDW) is a well-documented phenomenon characterized by temperature trends rising faster in high altitude mountains 7,8 . This phenomenon is supported and validated in numerous major mountain ranges, such as the Tibetan Plateau 9-12 , Rocky Mountains of North America 13,14 , Yunnan-Kweichow Plateau 15 , Tropical Andes mountain range 16 . However, it should be noted that the occurrence of the phenomenon of AEDW depends on the season, the study period and mountainous areas [17][18][19][20] . ...
Assessment of the elevation-dependent warming of land surface temperatures in the Qinling-Daba Mountains and its relationship with land surface albedo and aerosol optical depth from 2001 to 2021
Preprint
Full-text available
  • May 2024
In this paper, we examined the elevation-dependent warming (EDW) patterns of MODIS LST across different seasons in the Qinling-Daba Mountains, further investigate the connections between the EDW patterns of LST and ALB as well as AOD. The key findings include: 1) Our study reveals a robust correlation between LST and air temperature in the Qinling-Daba Mountains, suggesting the feasibility of using MODIS LST to predict the temperature trends 2) During the period from 2001 to 2010, MODIS LST shows a significant EDW trend, primarily in the spring season. In contrast, a negative EDW is observed in the period during 2011–2021, which is contrary to the earlier decade, particularly during the autumn and winter seasons. 3) EDW of MODIS LST is affected by the combination of ALB and AOD. The former has a negative influence on the change of LST, particularly above 2500 m in elevation. However, the latter is negatively correlated with the trend of MODIS LST, primarily at lower and middle altitudes (0-2500 m). This study gives a comprehensive explanation for the EDW of the temporal variations of LST in the Qinling-Daba Mountains to improve our understanding of the complex interactions and potential future climate scenarios in the region.
View
... Projected climate trends elevate risks to grass-hay ES through producer adoption of alternative agricultural practices and crops. With significant increases in growing degree days already documented in parts of the Intermountain West (McGuire et al., 2012), warming temperatures in the coming decades are projected to significantly expand agricultural climate zones, potentially shifting cropping patterns to higher altitudes (King et al., 2018). The emerging feasibility of more profitable cropping practices provides economic incentives for grass-hay conversion, including investments in efficient irrigation infrastructure, allowing producers to increase yields by applying water savings to the expansion of irrigated lands (Wallander and Hand, 2011). ...
Beneficial 'inefficiencies' of western ranching: Flood-irrigated hay production sustains wetland systems by mimicking historic hydrologic processes
Article
Full-text available
  • May 2024
Ranching in the American West has long relied on riparian ecosystems to grow grass-hay to feed livestock in winter and during drought. Producers seasonally flood grasslands for hay production using stream diversions and low-tech flood-irrigation on riparian floodplains. Inundation mimics natural processes that sustain riparian vegetation and recharge groundwater. The recent doubling in use of more efficient irrigation approaches, such as center-pivot sprinklers, threatens to accelerate climate change impacts by unintentionally decoupling more inefficient, traditional practices that sustain riparian systems. To assess ecosystem services provided by flood-irrigation hay production, we developed an exhaustive spatial inventory of grass-hay production and combined it with monthly surface water distributions modeled from satellite data. Surface water data were classified by wetland hydroperiod and used to estimate the proportion of wetlands supported by grass-hay production in the Intermountain West, USA. Elevation and proportion of grass-hay relative to other irrigated lands were enumerated to examine differences in their positions and abundance within landscapes. Lastly, we overlaid the delineated grass-hay wetlands with LANDFIRE pre-Euro-American Settings layer to quantify the efficacy of flood irrigation in mimicking the conservation of historical riparian processes. Findings suggest that inefficient grass-hay irrigation mirrored the timing of natural hydrology, concentrating ~93% of flooded grasslands in historical riparian ecosystems, affirming that at large scales, this ranching practice, in part, mimics floodplain processes sustaining wetlands and groundwater recharge. Despite representing only 2.5% of irrigated lands, grass-hay operations supported a majority (58%) of temporary wetlands, a rare and declining habitat for wildlife in the Intermountain West. Tolerance for colder temperatures confined grass-hay production to upper watershed reaches where higher value crops are constrained by growing degree days. This novel understanding of grass-hay agroecology highlights the vital role of working ranches in the resilience and stewardship of riparian systems.
View
... We found that snow cover during both spring drop-off and autumn questing periods strongly depressed subsequent tick loads, and that higher summer temperatures were associated with greater tick loads than lower temperatures. Because climate change is expected to produce both warmer summers (McGuire et al., 2012) and shorter winters (Evan & Eisenman, 2021;Musselman et al., 2021) in the Rocky Mountains, a trend toward higher tick loads among moose in these areas in the future is expected. ...
Warm places, warm years, and warm seasons increase parasitizing of moose by winter ticks
Article
Full-text available
  • Mar 2024
Observed links between parasites, such as ticks, and climate change have aroused concern for human health, wildlife population dynamics, and broader ecosystem effects. The one‐host life history of the winter tick ( Dermacentor albipictus ) links each annual cohort to environmental conditions during three specific time periods when they are predictably vulnerable: spring detachment from hosts, summer larval stage, and fall questing for hosts. We used mixed‐effects generalized linear models to investigate the drivers of tick loads carried by moose ( Alces alces ) relative to these time periods and across 750 moose, 10 years, and 16 study areas in the western United States. We tested for the effects of biotic factors (moose density, shared winter range, vegetation, migratory behavior) and weather conditions (temperature, snow, humidity) during each seasonal period when ticks are vulnerable and off‐host. We found that warm climatic regions, warm seasonal periods across multiple partitions of the annual tick life cycle, and warm years relative to long‐term averages each contributed to increased tick loads. We also found important effects of snow and other biotic factors such as host density and vegetation. Tick loads in the western United States were, on average, lower than those where tick‐related die‐offs in moose populations have occurred recently, but loads carried by some individuals may be sufficient to cause mortality. Lastly, we found interannual variation in tick loads to be most correlated with spring snowpack, suggesting this environmental component may have the highest potential to induce change in tick load dynamics in the immediate future of this region.
View
... Many of the undisturbed sites are found at higher elevation particularly in the headwaters draining protected lands. The elevation is also known to be a surrogate measure of temperature (McGuire et al., 2012). Global increments of temperatures are a consequence of climate change and land use driven by human activities such as impacts of landcover changes that are found to be both intensive and widespread in parts of the watershed (Vitousek, 1994). ...
Using the Biological Condition Gradient Model as a Bioassessment Framework to Support Rehabilitation and Restoration of the Upper Tana River Watershed in Kenya
Article
Full-text available
  • Jul 2021
The biological condition gradient (BCG), a scientific framework that describes the change in ecosystem characteristics in response to human-induced levels of stressors, was modified and used to characterize watershed habitats in the Upper Tana River watershed, Kenya. The inbuilt utilities of BCG, including its simplicity, versatility, and its robust nature, allowed its use by seven taxonomic groups of macroinvertebrates, diatoms, fish, herpetofauna (amphibians and reptiles), plants, macrofungi, and birds to assess and monitor landscape conditions in both terrestrial and aquatic habitats. The biological data were described using taxa abundance distribution measures followed by multivariate analyses to determine their relationship with water or soil quality and thereafter assessment of taxa tolerant levels in response to environmental stress and disturbances. Preliminary findings reported that the taxonomic groups complemented each other, with each taxonomic group reliably assessing ecological conditions to a certain degree that supported assigning all 36 sampled sites into BCG tiers. The BCG models developed for all taxonomic groups assisted in the identification and selection of taxa indicating varying levels of landscape conditions. These taxa, referred to as flagship or indicator taxa, assist in simplifying the BCG model and, hence, are possible for use by parataxonomists or ordinary citizens to assess and monitor the ecological health of habitats under consideration. Furthermore, the capability of BCG models to assess landscape conditions shows how they can be used to identify important habitats for conservation, direct investment for restoration, and track progress.
View
... Since these ecosystems are highly sensitive to mercury contamination, it is important to consider how future change will impact mercury transport, bioavailability, and toxicity. In the Rocky Mountains, climate change is causing increased warming (McGuire et al. 2012), drought conditions (Tague & Dugger 2010), and growing season length (Hu et al. 2010), all of which have important implications for mercury cycling in local and distant ecosystems. Here, we focus specifically on the effects of shifting hydrology and wildfire on mercury mobilization and ecosystem exposure (Fig. 4). ...
Mercury cycling in the U.S. Rocky Mountains: a review of past research and future priorities
Article
Full-text available
  • Dec 2023
  • BIOGEOCHEMISTRY
Mercury cycles at levels three- to five-fold higher today than the pre-Industrial era, resulting in global contamination of ecosystems. In the western United States (U.S.), mercury mobilization has led to widespread production of methylmercury (MeHg), a potent, bioaccumulating neurotoxin, which has resulted in fish consumption advisories across all states. Mountain regions are particularly sensitive to continued mercury contamination as they receive higher rates of atmospheric deposition, compared to lower elevations, and have aquatic ecosystems on the landscape conducive to MeHg production. In this paper, we focus on the U.S. Rocky Mountain region and synthesize: (1) current knowledge regarding the mercury cycle; (2) impacts of climate change on the mercury cycle connected to hydrology and wildfire; and (3) future research priorities for informing mercury research and regulation. Studies on the interactions between mercury contamination and climate change in mountain ecosystems is still nascent. We use the findings from this synthesis to summarize the following research needs: (1) quantify sources of mercury in wet and dry deposition, as these pathways dictate mercury exposure and toxicity, and are shifting with climate change; (2) investigate MeHg in mountain aquatic ecosystems, which are important pathways of human mercury exposure and provide food resources and habitat to local wildlife; and (3) examine the disproportionate impact of mercury contamination on indigenous communities through community-led research. Although we focus on the Rocky Mountains for this review, the findings are applicable to semi-arid mountain ecosystems globally and must be prioritized to promote the health of ecosystems and people everywhere.
View
... Finally, many authors have shown that there is no clear (significant) relationship between warming magnitude and elevation (e.g., Dimiri et al., 2022 in the Indian Himalayan region for observations and modelling fields from 1970 to 2099; Oyler et al., 2015 in the western United States from 1991 to 2012; Wang et al., 2016within the Arctic over 1961-2010or Pepin & Lundquist, 2008 over 1000 high elevation stations across the globe). In addition, at the global scale, there is abundant literature analysing the influence of elevation on mean air temperature trends (e.g., Bradley et al., 2004;Knight, 2022;Moradi & Darand, 2022;Pepin et al., 2015;Pepin & Lundquist, 2008;Rangwala, 2013), whereas a smaller number of studies focusing on maximum and minimum air temperature trends have been conducted (e.g., Liu et al., 2009;McGuire et al., 2012). For example, Pepin et al. (2015) investigated global air temperature variations in mountainous regions, highlighting their trends, spatial distribution and seasonal variations. ...
Long‐term observed changes of air temperature, relative humidity and vapour pressure deficit in Bolivia, 1950–2019
Article
Full-text available
This study analyzes the long‐term observed changes of mean (Tmean), maximum (Tmax) and minimum (Tmin) air temperatures, relative humidity (RH) and vapour pressure deficit (VPD) at different elevation ranges across Bolivia from 1950 to 2019. The linear trends in air temperature series present a significant increase, with no substantial seasonal or spatial differences. On an annual basis, RH exhibited a non‐significant decrease (−0.08% decade⁻¹), while VPD showed a significant increase (0.01 hPa decade⁻¹) (p < 0.05). Although prior research has suggested that highland elevations experience faster warming than the global average, we have not identified a distinct correlation between elevation gradients and differential warming rates in Bolivia. Future research could investigate elevation‐dependent climate trends by examining seasonal and monthly patterns of climatic variables in relation to topographical gradients in various highland regions.
View
Surface air temperature change in the Wuyi Mountains, southeast China
Article
Full-text available
  • Jun 2024
  • J MT SCI-ENGL
Detecting changes in surface air temperature in mid-and low-altitude mountainous regions is essential for a comprehensive understanding of warming trend with altitude. We use daily surface air temperature data from 64 meteorological stations in Wuyi Mountains and its adjacent regions to analyze the spatio-temporal patterns of temperature change. The results show that Wuyi Mountains have experienced significant warming from 1961 to 2018. The warming trend of the mean temperature is 0.20°C/decade, the maximum temperature is 0.17°C/decade, and the minimum temperature is 0.26°C/decade. In 1961-1990, more than 63% of the stations showed a decreasing trend in annual mean temperature, mainly because the maximum temperature decreased during this period. However, in 1971-2000, 1981-2010 and 1991-2018, the maximum, minimum and mean temperatures increased. The fastest increasing trend of mean temperature occurred in the southeastern coastal plains, the quickest increasing trend of maximum temperature occurred in the northwestern mountainous region, and the increase of minimum temperature occurred faster in the southeastern coastal and northwestern mountainous regions than that in the central area. Meanwhile, this study suggests that elevation does not Surface air temperature change in the Wuyi Mountains, southeast China 1993 affect warming in the Wuyi Mountains. These results are beneficial for understanding climate change in humid subtropical middle and low mountains.
View
A drying climate and habitat availability drive extirpations of a southward advancing ground squirrel
Article
  • Feb 2024
Ground squirrels act as important members of grassland ecosystems by serving as both ecosystem engineers and as a prey base for carnivores. There is mounting evidence that climate change is driving ground squirrel population declines. We resurveyed 54 historical localities throughout the Wyoming Basin and western Colorado where Wyoming Ground Squirrel (Urocitellus elegans) specimens were collected to investigate if climate change was driving extirpations at these historically occupied sites. We detected extirpations at 12 sites and used binomial generalized linear models in an information-theoretic framework to investigate if climate change was associated with these extirpations. Additionally, we investigated if land cover change was associated with persistence and if land cover ameliorated or exacerbated the effects of climate change. We found that changes in climate, especially increasingly dry summer air and increasing mean summer temperatures, were associated with a reduced probability that U. elegans persisted at a historically occupied site. In addition, we found that current forest cover at a site and increasing rangeland cover at the regional level were associated with reduced probability that U. elegans persisted, although these associations were weaker than the climate associations. The effects of climate change and land cover change did not interact. Our findings build on mounting evidence that montane-associated ground squirrels throughout the Western United States are negatively impacted by climate change. The reduction in ground squirrel abundance or their extirpation due to climate change could lead to changes in ecosystem structure or reductions in trophic complexity.
View
Plant functional traits are dynamic predictors of ecosystem functioning in variable environments
Article
Full-text available
A central goal at the interface of ecology and conservation is understanding how the relationship between biodiversity and ecosystem function (B–EF) will shift with changing climate. Despite recent theoretical advances, studies which examine temporal variation in the functional traits and mechanisms (mass ratio effects and niche complementarity effects) that underpin the B–EF relationship are lacking. Here, we use 13 years of data on plant species composition, plant traits, local‐scale abiotic variables, above‐ground net primary productivity (ANPP), and climate from the alpine tundra of Colorado (USA) to investigate temporal dynamics in the B–EF relationship. To assess how changing climatic conditions may alter the B–EF relationship, we built structural equation models (SEMs) for 11 traits across 13 years and evaluated the power of different trait SEMs to predict ANPP, as well as the relative contributions of mass ratio effects (community‐weighted mean trait values; CWM), niche complementarity effects (functional dispersion; FDis) and local abiotic variables. Additionally, we coupled linear mixed effects models with Multimodel inference methods to assess how inclusion of trait–climate interactions might improve our ability to predict ANPP through time. In every year, at least one SEM exhibited good fit, explaining between 19.6% and 57.2% of the variation in ANPP. However, the identity of the trait which best explained ANPP changed depending on winter precipitation, with leaf area, plant height and foliar nitrogen isotope content (δ¹⁵N) SEMs performing best in high, middle and low precipitation years, respectively. Regardless of trait identity, CWMs exerted a stronger influence on ANPP than FDis and total biotic effects were always greater than total abiotic effects. Multimodel inference reinforced the results of SEM analysis, with the inclusion of climate–trait interactions marginally improving our ability to predict ANPP through time. Synthesis. Our results suggest that temporal variation in climatic conditions influences which traits, mechanisms and abiotic variables were most responsible for driving the B–EF relationship. Importantly, our findings suggest that future research should consider temporal variability in the B–EF relationship, particularly how the predictive power of individual functional traits and abiotic variables may fluctuate as conditions shift due to climate change.
View
Historical changes in the phenology of British Odonata are related to climate
Article
Full-text available
  • Feb 2007
Responses of biota to climate change take a number of forms including distributional shifts, behavioural changes and life history changes. This study examined an extensive set of biological records to investigate changes in the timing of life history transitions (specifically emergence) in British Odonata between 1960 and 2004. The results show that there has been a significant, consistent advance in phenology in the taxon as a whole over the period of warming that is mediated by life history traits. British odonates significantly advanced the leading edge (first quartile date) of the flight period by a mean of 1.51 ±0.060 (SEM, n=17) days per decade or 3.08±1.16 (SEM, n=17) days per degree rise in temperature when phylogeny is controlled for. This study represents the first review of changes in odonate phenology in relation to climate change. The results suggest that the damped temperature oscillations experienced by aquatic organisms compared with terrestrial organisms are sufficient to evoke phenological responses similar to those of purely terrestrial taxa.
View
Recent Changes in Frost Days and the Frost-Free Season in the United States.
Article
Full-text available
  • Sep 2002
move to an earlier date. This results in an increase in the frost-free season. However, there is a distinct spatial pattern to the results that is consistent with the spatial pattern of annual temperature trends for the twentieth century. The geographical pattern shows the western United States with the largest decreases in frost days, and increases in frost-free season length. But the southeast United States, which is one of the few areas of the world showing cooling over the twentieth century, has no significant changes in the number of frost days or the frost-free season.
View
View
Bioclimatic model of Melanoplus sanguinipes (Fabricius) (Orthoptera: Acrididae) populations in Canada and the potential impacts of climate change
Article
Full-text available
  • Jan 2006
The northern Great Plains of North America has experienced a number of severe grasshopper infestations over the last 100 years. Grasshopper densities have been observed to be in synchrony over vast geographical areas. Weather is probably the most significant factor that affects fluctuations in population abundance of Melanoplus sanguinipes, the migratory grasshopper. Inferential modeling was used to develop a bio-climatic model of M. sanguinipes that closely agreed with current distribution and abundance patterns of this species in North America over a 30 yr period. Incremental climate change scenarios were then applied to the bio-climatic model to predict changes to potential distribution and relative abundance of M. sanguinipes, resulting from climate change. Compared to predicted range and distribution under current climate conditions, model results indicated that M. sanguinipes would have increased range and relative abundance for temperature increases between 1 and 7 0C. The model predicted that range of this crop pest would be extended to regions that are not currently used for agricultural production in North America.
View
View
Twentieth-Century Change in the Climate Record for the Front Range, Colorado, U.S.A.
Article
  • May 2000
The long-term climate records of the Mountain Research Station (MRS) at the University of Colorado cover a range of elevations from the lower montane forest zone (similar to 2000-2400 m), through the upper montane forest (similar to 2400-2800 m) and subalpine forest (similar to 2800-3300 m) to the alpine tundra (>3300 m) on Niwot Ridge, Colorado. Temperature records from all four MRS sites and the additional high plains site of Longmont (1509 m) are analyzed for the period 1952-1997, after extraction of much extra data from the original thermograph charts. The records are adjusted for instrumental changes where necessary and all four records are judged to be homogenous. Contrasting temporal trends are uncovered at the various elevations with warming at middle elevations and absolute cooling above the treeline in the alpine tundra. The resulting increased surface-based lapse rates do not arise from changes in relative frequencies of airflow types as is shown by a synoptic analysis based on objective airflow indices. Lapse rate increases are most systematic for synoptic classes with westerly components and during fall, winter, and spring. Climate at high elevations of the Front Range appears to be responding in an unusual way to global-warming influences.
View
The climate of Niwot Ridge, Front Range, Colorado, USA
Article
  • Nov 1989
The climate of Niwot Ridge is described using monthly and annual mean temperatures and monthly and annual total precipitation values for the period 1951 to 1985 and comparable precipitation values for the nearby Silver Lake station from 1915. Summary statistics and water budget values are presented. Time series analysis indicates abnormally low temperatures in the early 1980s and an overall downward trend in temperature. Autoregressive moving average forecasting models and spectral analysis hint at some cyclicity in the data series of annual values of both temperature and precipitation. Silver Lake annual precipitation data show only a slight downward trend when the extremely high value for the year of 1921 is excluded. Implications of these changes for the alpine tundra ecosystem are briefly discussed.
View
Thermal Time, Chill Days and Prediction of Budburst in Picea sitchensis
Article
  • Dec 1983
(1) The dates of budhurst of lateral shoots on 2- to 10-year old trees of Picea sitchensis were recorded on fourteen occasions at sites near meteorological stations in lowland and upland Britain between 1960 and 1980. (2) The following relationship accounted for 92% of the variation in thermal time from 1 February to the date of budburst among the fourteen observations: thermal time = 67.4 + 4401.8 exp (-0.042 x chill days) where thermal time was day degrees >5 ⚬C accumulated from 1 February, and chill days were the number of days ⩽5 ⚬C counted from 1 November, both based on mean daily air temperature ((max. + min.)/2). This model may be used to estimate the date of budburst on young P. sitchensis of most provenances growing in upland Britain. (3) The following features or assumptions of the model were examined with reference to the literature and/or by experimentation: the small effect of provenance; linearity in the relationship between bud growth rate and temperature; the large effect of chilling on thermal time to budhurst; the omission of daylength and soil temperature as variables; the choice of starting dates for effective chilling and thermal time; and the use of simple fixed base temperatures. (4) The model was applied to mean daily temperatures at Eskdalemuir for the period 1912-82. The predicted dates of budburst ranged from 23 April in 1961 to 30 May in 1923, with a mean date of 12 May.
View
Altitudinal and Seasonal Distribution of Orthoptera in the Rocky Mountains of Northern Colorado
Article
  • Oct 1969
Ninety-four species of Orthoptera (s. lat.) occur along an altitudinal transect from 5,000 ft (1,530 m) to above 14,000 ft (4,265 m) in the Front Range of the Rocky Mountains of Colorado, near 40@? N. Lat. These were sampled, with observations on life histories in relation to altitude, at a series of altitudinally spaced stations during the seasons of 1949, 1958, 1959, and 1960, the stations being selected for maximum variety of Orthoptera at each altitude. Other observations of the past 35 years were added. Sampling was by a sweeping technique designed to be qualitatively exhaustive of species and age groups; it was thus quasiquantitative. Times of hatching, times of different juvenile stages, and times of maturing were determined for species at the different altitudes at which they occurred. These data are summarized by species, the 94 species being in the following families: Mantidae, 2; Phasmidae, 1; Tetrigidae, 4; Acrididae, 73; Tettigoniidae, 8; Gryllacrididae, 3; Gryllidae, 3. Numbers of resident species found in 1,000 ft altitudinal bands were as follows: 5-6,000 ft, 71; 6-7,000 ft, 49; 7-8,000 ft, 34; 8-9,000 ft, 25; 9-10,000 ft, 19; 10-11,000 ft, 15; 11-12,000 ft, 9; over 12,000 ft, 3. Larger average numbers of individuals per species occur at higher elevations. Many more species of low frequency occur at low altitudes than high, the total number of species known from a given high altitude station often being present in a single collection, while, at low altitude stations, even the most varied collection lacks species occasionally collected there. The reduction in species numbers with altitude is correlated with a similar reduction with latitude, and the geographic distribution of particular species of Orthoptera is correlated with altitude. Of the 18 species of Acrididae recorded north of 60@? N. Lat. in North America nine are common to abundant in the area of study up to 10,000 ft, six of these to 11,000 ft or more. However, three strictly montane species from above 10,000 ft are not known from the far north. The altitudinal distribution of the 36 most common species provided a basis for testing various suggested schemes of altitudinal zonation. A few high plains species that feed only on forbs are apparently restricted in part by the distribution of host plants, and a few grass-feeders do not invade the grassy clearings in montane forest, but the majority of species occurring on the high plains do range into clearings in the lower montane forest up to about 7,000 ft. Pest species with wide altitudinal ranges are essentially indiscriminate plant feeders. The reduction in number of species of Orthoptera with altitude is much greater than the reduction in number of plant species, so variety of plants is not a limiting factor in their altitudinal distribution. A more important factor is apparently the length of growing season--in particular its abbreviation at the end. Evidence for this is the occurrence of early juvenile instars of some species above the altitude at which the species normally completes its life cycle. Evidence was found for the relations between phenology and altitude postulated by A. D. Hopkins in the times of maturing of species with wide altitudinal ranges, with events somewhat earlier than expected at the highest altitudes. Events that occur near the middle of the summer (hatching of eggs of species that overwinter as juveniles) are independent of altitude, but this too is the harmony with the Hopkins law.
View
View