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1.
W. R. Skinner M. D. Flannigan B. J. Stocks D. L. Martell B. M. Wotton J. B. Todd J. A. Mason K. A. Logan E. M. Bosch 《Theoretical and Applied Climatology》2002,71(3-4):157-169
Summary
In Canada, the average annual area of burned forest has increased from around 1 million ha in the 1970’s to over 2.5 million
ha in the 1990’s. A previous study has identified the link between anomalous mid-tropospheric circulation at 500 hPa over
northern North America and wildland fire severity activity in various large regions of Canada over the entire May to August
fire season. In this study, a northern North American study region of the hemispheric gridded 5° latitude by 10° longitude
500 hPa dataset is identified and analysed from 1959 to 1996 for a sequence of six monthly periods through the fire season,
beginning in April and ending in September. Synoptic types, or modes of upper air behavior, are determined objectively by
the eigenvector method employing K-means cluster analysis. Monthly burned areas from the Canadian Large Fire Database (LFDB)
for the same period, 1959 to 1996, are analysed in conjunction with the classified monthly 500 hPa synoptic types. Relationships
between common monthly patterns of anomalous upper flow and spatial patterns of large fire occurrence are examined at the
ecozone level. Average occurrence of a monthly synoptic type associated with very large area burned is approximately 18% of
the years from 1959 to 1996. The largest areas burned during the main fire (May to August) season occur in the western Boreal
and Taiga ecozones – the Taiga Plains, Taiga Shield, Boreal West Shield and Boreal Plains. Monthly burned areas are also analysed
temporally in conjunction with a calculated monthly zonal index (Zim) for two separate areas defined to cover western and eastern Canada. In both western and eastern Canada, high area burned
is associated with synoptic types with mid-tropospheric ridging in the proximity of the affected region and low Zim with weak westerlies and strong meridional flow over western Canada.
Received April 3, 2001 Revised July 13, 2001 相似文献
2.
W. R. Skinner B. J. Stocks D. L. Martell B. Bonsal A. Shabbar 《Theoretical and Applied Climatology》1999,63(1-2):89-105
Summary There is evidence that the area burned by wildland fire has increased in certain regions of Canada in recent decades. One
cause for this increase is changes in the mid-tropospheric circulation at 500 hPa over northern North America. This study
examines the physical links between anomalous mid-tropospheric circulation over various regions of Canada and wildland fire
severity. Analysis of monthly and seasonal burned areas for the period 1953 to 1995 reveals a bimodal distribution with distinct
low and extreme high burned area years. The high/low burned area years coincide with positive/negative 500 hPa height anomalies
over north-western, western, west-central and east-central Canada. Total area burned and the 500 hPa height anomaly data are
analyzed for statistical relationships using the Spearman rank correlation non-parametric measure. Results for the May to
August fire season indicate statistically significant correlations between regional total area burned and clusters of anomalous
500 hPa geopotential height values immediately over, and immediately upstream of the affected region. For the north-western
and west-central regions, significantly correlated clusters are found in the central Pacific as well, providing evidence of
the influence of a teleconnection structure on the summer climate of western and north-western North America. Two sample comparison
tests show statistically significant differences in both the means and variances of the fire data populations during negative
and positive phases of mid-tropospheric flow, and the means of the height anomaly populations during extremely high and extremely
low area burned seasons. Increases in regional total area burned are related to increases in mean 500 hPa heights, taken from
the significantly correlated clusters of height values, between two successive periods 1953–74 and 1975–95. For Canada as
a whole, the five lowest area burned seasons all occurred during the early period, while the five highest seasons occurred
during the later period. The difference in the geopotential height fields between the two periods identifies an increase in
500 hPa heights over most of Canada with an amplification of the western Canada ridge and an eastward shifted Canadian Polar
Trough (CPT).
Received October 19, 1998 相似文献
3.
B. J. Stocks M. A. Fosberg T. J. Lynham L. Mearns B. M. Wotton Q. Yang J-Z. Jin K. Lawrence G. R. Hartley J. A. Mason D. W. McKENNEY 《Climatic change》1998,38(1):1-13
In this study outputs from four current General Circulation Models (GCMs) were used to project forest fire danger levels in Canada and Russia under a warmer climate. Temperature and precipitation anomalies between 1 × CO2 and 2 × CO2 runs were combined with baseline observed weather data for both countries for the 1980–1989 period. Forecast seasonal fire weather severity was similar for the four GCMs, indicating large increases in the areal extent of extreme fire danger in both countries under a 2 × CO2 climate scenario. A monthly analysis, using the Canadian GCM, showed an earlier start to the fire season, and significant increases in the area experiencing high to extreme fire danger in both Canada and Russia, particularly during June and July. Climate change as forecast has serious implications for forest fire management in both countries. More severe fire weather, coupled with continued economic constraints and downsizing, mean more fire activity in the future is a virtual certainty. The likely response will be a restructuring of protection priorities to support more intensive protection of smaller, high-value areas, and a return to natural fire regimes over larger areas of both Canada and Russia, with resultant significant impacts on the carbon budget. 相似文献
4.
Predicted changes in fire weather suggest increases in lightning fire initiation and future area burned in the mixedwood boreal forest 总被引:1,自引:0,他引:1
Forecasting future fire activity as a function of climate change is a step towards understanding the future state of the western mixedwood boreal ecosystem. We developed five annual weather indices based on the Daily Severity Rating (DSR) of the Canadian Forest Fire Weather Index System and estimated their relationship with annual, empirical counts of lightning fire initiation for 588 landscapes in the mixedwood boreal forest in central-eastern Alberta, Canada from data collected between 1983 and 2001 using zero-inflated negative binomial regression models. Two indices contributed to a parsimonious model of initiation; these were Seasonal Severity Rating (SSR), and DSR-sequence count. We used parameter estimates from this model to predict lightning fire initiation under weather conditions predicted in 1 × CO2 (1975–1985), 2 × CO2 (2040–2049) and 3 × CO2 (2080–2089) conditions simulated by the Canadian Regional Climate Model (CRCM). We combined predicted initiation rates for these conditions with existing empirical estimates of the number of fire initiations that grow to be large fires (fire escapes) and the fire size distribution for the region, to predict the annual area burned by lightning-caused fires in each of the three climate conditions. We illustrated a 1.5-fold and 1.8-fold increase of lightning fire initiation by 2040–2049 and 2080–2089 relative to 1975–1985 conditions due to changes in fire weather predicted by the CRCM; these increases were calculated independent of changes in lightning activity. Our simulations suggested that weather-mediated increases in initiation frequency could correspond to a substantial increase in future area burned with 1.9-fold and 2.6-fold increases in area burned in 2040–2049 and 2080–2089 relative to 1975–1985 conditions, respectively. We did not include any biotic effects in these estimates, though future patterns of initiation and fire growth will be regulated not only by weather, but also by vegetation and fire management. 相似文献
5.
Anabela Carvalho Mike D. Flannigan Kim A. Logan Lynn M. Gowman Ana Isabel Miranda Carlos Borrego 《Climatic change》2010,98(1-2):177-197
In this study, we investigated the impact of future climate change on fire activity in 12 districts across Portugal. Using historical relationships and the HIRHAM (High Resolution Hamburg Model) 12 and 25 km climate simulations, we assessed the fire weather and subsequent fire activity under a 2 × CO2 scenario. We found that the fire activity prediction was not affected by the spatial resolution of the climate model used (12 vs. 25 km). Future area burned is predicted to increase 478% for Portugal as a whole, which equates to an increase from 1.4% to 7.8% of the available burnable area burning annually. Fire occurrence will also see a dramatic increase (279%) for all of Portugal. There is significant spatial variation within these results; the north and central districts of the country generally will see larger increases in fire activity. 相似文献
6.
Using regional climate model data to simulate historical and future river flows in northwest England 总被引:2,自引:0,他引:2
Daily rainfall and temperature data were extracted from the multi-ensemble HadRM3H regional climate model (RCM) integrations
for control (1960–1990) and future (2070–2100) time-slices. This dynamically downscaled output was bias-corrected on observed
mean statistics and used as input to hydrological models calibrated for eight catchments which are critical water resources
in northwest England. Simulated daily flow distributions matched observed from Q95 to Q5, suggesting that RCM data can be used with some confidence to examine future changes in flow regime. Under the SRES A2 (UKCIP02
Medium-High) scenario, annual runoff is projected to increase slightly at high elevation catchments, but reduce by ~16% at
lower elevations. Impacts on monthly flow distribution are significant, with summer reductions of 40–80% of 1961–90 mean flow,
and winter increases of up to 20%. This changing seasonality has a large impact on low flows, with Q95 projected to decrease in magnitude by 40–80% in summer months, with serious consequences for water abstractions and river
ecology. In contrast, high flows (> Q5) are projected to increase in magnitude by up to 25%, particularly at high elevation catchments, providing an increased risk
of flooding during winter months. These changes will have implications for management of water resources and ecologically
important areas under the EU Water Framework Directive. 相似文献
7.
Climate change that results from increasing levels of greenhouse gases in the atmosphere has the potential to increase temperature and alter rainfall patterns across the boreal forest region of Canada. Daily output from the Canadian Climate Centre coupled general circulation model (GCM) and the Hadley Centre's HadCM3 GCM provided simulated historic climate data and future climate scenarios for the forested area of the province of Ontario, Canada. These models project that in climates of increased greenhouse gases and aerosols, surface air temperatures will increase while seasonal precipitation amounts will remain relatively constant or increase slightly during the forest fire season. These projected changes in weather conditions are used to predict changes in the moisture content of forest fuel, which influences the incidence of people-caused forest fires. Poisson regression analysis methods are used to develop predictive models for the daily number of fires occurring in each of the ecoregions across the forest fire management region of Ontario. This people-caused fire prediction model, combined with GCM data, predicts the total number of people-caused fires in Ontario could increase by approximately 18% by 2020–2040 and50% by the end of the 21st century. 相似文献
8.
S. P. Malevsky-Malevich E. K. Molkentin E. D. Nadyozhina O. B. Shklyarevich 《Climatic change》2008,86(3-4):463-474
The problem of forest fires is very important for Russia. In this paper we consider this problem in the connection with the
projection of significant climate change. An approach to determine the magnitude of change in wildfire risk in Russia under
the influence of climate warming is discussed. Observations for the European part of Russia and for Siberia have been used
in this analysis. A statistical correlation between drought indices calculated by use of monthly sums of temperature and precipitation
and the frequency of fire danger was obtained for the forest zone of Russia. The change in fire danger potential was evaluated
using temperature and precipitation monthly means at the nodes of a regular spatial grid. Climate change scenarios were obtained
from Global Climate Models (GCM) ensemble projections. The maximum increases (about 12–30%) of the number of days with fire
danger conditions during the twenty-first century fire season were obtained for the southern forest zone boundary in both
the European region of Russia and in Siberia. In the Baikal and Primoriye Regions, fire danger distributions in the twenty-first
century are not projected to change significantly. 相似文献
9.
Simulations of impacts of a double-CO2 climate with the Changed Climate Fire Modeling System in Northern California consistently projected increases in area burned and in the frequency of escaped fires compared with simulations of the present climate. However, the magnitude of those increases was strongly influenced by vegetation type, choice of atmospheric general circulation model (GCM) scenario, and choice of climatic forcing variables. The greatest projected increase in fire severity occurred in grasslands, using the Princeton Geophysical Fluid Dynamics Laboratory GCM, with wind speed, temperature, humidity and precipitation as driving variables. 相似文献
10.
X-C Zhang 《Climatic change》2007,84(3-4):337-363
Spatial downscaling of climate change scenarios can be a significant source of uncertainty in simulating climatic impacts
on soil erosion, hydrology, and crop production. The objective of this study is to compare responses of simulated soil erosion,
surface hydrology, and wheat and maize yields to two (implicit and explicit) spatial downscaling methods used to downscale
the A2a, B2a, and GGa1 climate change scenarios projected by the Hadley Centre’s global climate model (HadCM3). The explicit
method, in contrast to the implicit method, explicitly considers spatial differences of climate scenarios and variability
during downscaling. Monthly projections of precipitation and temperature during 1950–2039 were used in the implicit and explicit
spatial downscaling. A stochastic weather generator (CLIGEN) was then used to disaggregate monthly values to daily weather
series following the spatial downscaling. The Water Erosion Prediction Project (WEPP) model was run for a wheat–wheat–maize
rotation under conventional tillage at the 8.7 and 17.6% slopes in southern Loess Plateau of China. Both explicit and implicit
methods projected general increases in annual precipitation and temperature during 2010–2039 at the Changwu station. However,
relative climate changes downscaled by the explicit method, as compared to the implicit method, appeared more dynamic or variable.
Consequently, the responses to climate change, simulated with the explicit method, seemed more dynamic and sensitive. For
a 1% increase in precipitation, percent increases in average annual runoff (soil loss) were 3–6 (4–10) times greater with
the explicit method than those with the implicit method. Differences in grain yield were also found between the two methods.
These contrasting results between the two methods indicate that spatial downscaling of climate change scenarios can be a significant
source of uncertainty, and further underscore the importance of proper spatial treatments of climate change scenarios, and
especially climate variability, prior to impact simulation. The implicit method, which applies aggregated climate changes
at the GCM grid scale directly to a target station, is more appropriate for simulating a first-order regional response of
nature resources to climate change. But for the site-specific impact assessments, especially for entities that are heavily
influenced by local conditions such as soil loss and crop yield, the explicit method must be used. 相似文献
11.
Self-organizing map (SOM) is used to simulate summer daily precipitation over the Yangtze–Huaihe river basin in Eastern China, including future projections. SOM shows good behaviors in terms of probability distribution of daily rainfall and spatial distribution of rainfall indices, as well as consistency of multi-model simulations. Under RCP4.5 Scenario, daily rainfall at most sites (63%) is projected to shift towards larger values. For the early 21st century (2016–2035), precipitation in the central basin increases, yet decreases occur over the middle reaches of the Yangtze River as well as a part of its southeast area. For the late 21st century (2081–2100), the mean precipitation and extreme indices experience an overall increase except for a few southeast stations. The total precipitation in the lower reaches of the Yangtze River and in its south area is projected to increase from 7% at 1.5 °C global warming to 11% at 2 °C, while the intensity enhancement is more significant in southern and western sites of the domain. A clustering allows to regroup all SOM nodes into four distinct regimes. Such regional synoptic regimes show remarkable stability for future climate. The overall intensification of precipitation in future climate is linked to the occurrence-frequency rise of a wet regime which brings longitudinally closer the South Asia High (eastward extended) and the Western Pacific Subtropical High (westward extended), as well as the reduction of a dry pattern which makes the two atmospheric centers of action move away from each other. 相似文献
12.
Projected changes in summer precipitation characteristics in China during the 21st century are assessed using the monthly precipitation outputs of the ensemble of three “best” models under the Special Report on Emissions Scenarios (SRES) A1B, A2, and B1 scenarios. The excellent reproducibility of the models both in spatial and temporal patterns for the precipitation in China makes the projected summer precipitation change more believable for the future 100 years. All the three scenarios experiments indicate a consistent enhancement of summer precipitation in China in the 21st century. However, the projected summer precipitation in China demonstrates large variability between sub-regions. The projected increase in precipitation in South China is significant and persistent, as well as in North China. Meanwhile, in the early period of the 21st century, the region of Northeast China is projected to be much drier than the present. But, this situation changes and the precipitation intensifies later, with a precipitation anomaly increase of 12.4%–20.4%
at the end of the 21st century. The region of the Xinjiang Province probably undergoes a drying trend in the future 100 years, and is projected to decrease by 1.7%–3.6% at the end of the 21st century. There is no significant long-term change of the projected summer precipitation in the lower reaches of the Yangtze River valley. A high level of agreement of the ensemble of the regional precipitation change in some parts of China is found across scenarios but smaller changes are projected for the B1 scenario and slightly larger changes for the A2 scenario. 相似文献
13.
X. Yin 《Theoretical and Applied Climatology》1999,64(3-4):249-261
Summary Numerical models are often the only means available to generate solar irradiance (SR) information, for historical or future
SR specifications as well as due to inadequacies of contemporary SR measurements. This paper evaluates five such models that
have been proposed as generic and applied as such. Special emphasis is given to Solar123, an integrative model rooted in Lambert’s
Cosine Law and Bouguer’s Law with globally-parameterized atmospheric property functions and with input limited to precipitation,
air temperature, geographic location, topography and rudimentary land cover information. The selected SR models in general
perform well in reproducing the SR data for the USA, with a root mean square error-to-data mean ratio (RMSE/SRmean ratio) of 9.8–11.4%. A possible exception is the Bristow-Campbell logic as implemented by the Vegetation/Ecosystem Modeling
and Analysis Project. Beyond the USA, Solar123 yields an RMSE/SRmean ratio of 8–17% by region (196 stations in total), generally outperforming the other SR models. Compared to time-sequential
monthly SR data, projections by Solar123 have an RMSE/SRmean ratio of 8.6–14.1% for six weather stations representative of major climate regimes in Canada, or an RMSE/SRmean ratio of 13–24% for three forest sites in the USA, Germany and Japan. Solar123 projections also compare favorably against
the output from the General Circulation Models in terms of ratio change in SR with the doubling of the atmospheric carbon-dioxide
concentration: the two fall within ±10% of each other for 85% of a total 264 cases, and within ±20% for all but 3 of the cases.
The above statistics suggest that Solar123 represents an improvement over other SR models not only in configuration but also
in projection accuracy, and that Solar123 is useful for projecting spatial variation in SR across weather stations around
the world and over different land covers, and for projecting temporal variation in SR under the present climate regimes and
likely for regimes changed beyond the present fluctuation range. The work further calls into question the common practice
of applying SR data irrespective of local land cover.
Received May 20, 1999 相似文献
14.
Summary Freeze thaw cycles are examined in Toronto Canada. Using data from 1960 to 1989 for three Toronto area weather stations, trends
in freeze thaw activity, the relationship to mean monthly temperature and projections of freeze thaw activity are examined.
For downtown Toronto the annual frequency of freeze thaw cycles is decreasing significantly, most notably in the shoulder
months of October and April. At the Pearson International Airport and the Toronto Island Airport similar annual trends were
not found, however there was evidence of decreased freeze thaw activity in April and October. Polynomial curve fitting provided
functional relationships between mean monthly temperature and freeze thaw activity. These relationships enabled the assessment
of freeze thaw activity under synthetic warming conditions. The results of this analysis show that the warming of the magnitude
typically projected for the rest of this century will not likely generate a significant change in the freeze thaw activity
although there are indications that the freeze thaw season will contract. 相似文献
15.
Jonghan Ko Lajpat R. Ahuja S. A. Saseendran Timothy R. Green Liwang Ma David C. Nielsen Charles L. Walthall 《Climatic change》2012,111(2):445-472
Agricultural systems models are essential tools to assess potential climate change (CC) impacts on crop production and help
guide policy decisions. In this study, impacts of projected CC on dryland crop rotations of wheat-fallow (WF), wheat-corn-fallow
(WCF), and wheat-corn-millet (WCM) in the U.S. Central Great Plains (Akron, Colorado) were simulated using the CERES V4.0
crop modules in RZWQM2. The CC scenarios for CO2, temperature and precipitation were based on a synthesis of Intergovernmental Panel on Climate Change (IPCC 2007) projections for Colorado. The CC for years 2025, 2050, 2075, and 2100 (CC projection years) were super-imposed on measured
baseline climate data for 15–17 years collected during the long-term WF and WCF (1992–2008), and WCM (1994–2008) experiments
at the location to provide inter-annual variability. For all the CC projection years, a decline in simulated wheat yield and
an increase in actual transpiration were observed, but compared to the baseline these changes were not significant (p > 0.05) in all cases but one. However, corn and proso millet yields in all rotations and projection years declined significantly
(p < 0.05), which resulted in decreased transpiration. Overall, the projected negative effects of rising temperatures on crop
production dominated over any positive impacts of atmospheric CO2 increases in these dryland cropping systems. Simulated adaptation via changes in planting dates did not mitigate the yield
losses of the crops significantly. However, the no-tillage maintained higher wheat yields than the conventional tillage in
the WF rotation to year 2075. Possible effects of historical CO2 increases during the past century (from 300 to 380 ppm) on crop yields were also simulated using 96 years of measured climate
data (1912–2008) at the location. On average the CO2 increase enhanced wheat yields by about 30%, and millet yields by about 17%, with no significant changes in corn yields. 相似文献
16.
In a warming climate, atmospheric wave activity and associated weather patterns may change, although conflicting results have been reported on this topic. Additionally, atmospheric wave changes in a future climate have mainly focused on waves of a specified spatial scale, rather than a particular spatiotemporal scale. Here, changes in the variability of Rossby waves of multiple spatiotemporal scales are analyzed using the wavenumber-frequency power spectrum, a tool commonly applied to analyze atmospheric equatorial waves. Daily 500 hPa geopotential height data over 40°–60°N from historical (1950–2005) and future (2006–2099) simulations from 20 models in the Coupled Model Intercomparison Project Phase 5 (CMIP5) under the RCP8.5 scenario were analyzed. When compared to the historical period, the late 21st century climate projections showed a decline in spectral power for both eastward and westward propagating waves with wavenumbers greater than 8 that spanned over all frequencies in all seasons, but an increase in mean power for eastward propagating waves with wavenumbers 1–7 over all frequencies was shown in winter and spring. This increase in power was accompanied by increased variance, i.e., an increased meridional extent of 500 hPa ridges and troughs, and was the result of increases in the mean number of high amplitude events and duration of activity within this wave band. These results indicate that large-scale (~ 104 km) eastward propagating weather systems may intensify with higher amplitudes for ridges and troughs, while short-scale (102–103 km) weather systems may decrease in their intensity due to reduced variability in the late 21st century under the high emissions scenario. Potential mechanisms for these changes are discussed, including enhanced Arctic warming and midlatitude-tropical interactions. 相似文献
17.
Management alternatives to offset climate change effects on Mediterranean fire regimes in NE Spain 总被引:1,自引:0,他引:1
Fire regime is affected by climate and human settlements. In the Mediterranean, the predicted climate change is likely to exacerbate fire prone weather conditions, but the mid- to long-term impact of climate change on fire regime is not easily predictable. A negative feedback via fuel reduction, for instance, might cause a non-linear response of burned area to fire weather. Also, the number of fires escaping initial control could grow dramatically if the fire meteorology is just slightly more severe than what fire brigades are prepared for. Humans can directly influence fire regimes through ignition frequency, fire suppression and land use management. Here we use the fire regime model FIRE LADY to assess the impacts of climate change and local management options on number of fires, burned area, fraction of area burned in large fires and forest area during the twenty-first century in three regions of NE Spain. Our results show that currently fuel-humidity limited regions could suffer a drastic shift of fire regime with an up to 8 fold increase of annual burned area, due to a combination of fuel accumulation and severe fire weather, which would result in a period of unusually large fires. The impact of climate change on fire regime is predicted to be less pronounced in drier areas, with a gradual increase of burned area. Local fire prevention strategies could reduce but not totally offset climate induced changes in fire regimes. According to our model, a combination of restoring the traditional rural mosaic and classical fire prevention would be the most effective strategy, as a lower ignition frequency reduces the number of fires and the creation of agricultural fields in marginal areas reduces their extent. 相似文献
18.
Estimating emissions from forest fires in Thailand using MODIS active fire product and country specific data 总被引:1,自引:0,他引:1
Agapol Junpen Savitri Garivait Sebastien Bonnet 《Asia-Pacific Journal of Atmospheric Sciences》2013,49(3):389-400
Studies on air pollution and climate change have shown that forest fires constitute one of the major sources of atmospheric trace gases and particulate matter, especially during the dry season. However, these emissions remain difficult to quantify due to uncertainty on the extent of burned areas and deficient knowledge on the forest fire behaviours in each country. This study aims to estimate emissions from forest fires in Thailand by using the combination of the Moderate Resolution Imaging Spectroradiometer (MODIS) for active fire products and country-specific data based on prescribed burning experiments. The results indicate that 27817 fire hotspots (FHS) associated with forest fires were detected by the MODIS during 2005–2009. These FHS mainly occurred in the northern, western, and upper north-eastern parts of Thailand. Each year, the most significant fires were observed during January–May, with a peak in March. The majority of forest FHS were detected in the afternoon. According to the prescribed burning experiments, the average area of forest burned per fire event was found to fall within the range 1.09 to 12.47 ha, depending upon the terrain slope and weather conditions. The total burned area was computed at 159309 ha corresponding to the surface biomass fuel of 541515 tons dry matter. The forest fire emissions were computed at 855593 tons of CO2, 56318 tons of CO, 3682 tons of CH4, 108 tons of N2O, 4928 tons of PM2.5, 4603 tons of PM10, 357 tons of BC and 2816 tons of OC. 相似文献
19.
K. D. Hage 《大气与海洋》2013,51(1):8-14
The methods used in an earlier study focusing on the province of Ontario, Canada, were adapted for this current study to expand the study area over eastern Canada where the infrastructure is at risk of being impacted by freezing rain. To estimate possible impacts of climate change on future freezing rain events, a three-step process was used in the study: (1) statistical downscaling, (2) synoptic weather typing, and (3) future projections. A regression-based downscaling approach, constructed using different regression methods for different meteorological variables, was used to downscale the outputs of eight general circulation models to each of 42 hourly observing stations over eastern Canada. Using synoptic weather typing (principal components analysis, a clustering procedure, discriminant function analysis), the freezing rain-related weather types under historical climate (1958–2007) and future downscaled climate conditions (2016–2035, 2046–2065, 2081–2100) were identified for all selected stations. The potential changes in the frequency of future daily freezing rain events can be projected quantitatively by comparing future and historical frequencies of freezing rain-related weather types. The modelled results show that eastern Canada could experience more freezing rain events late this century during the coldest months (i.e., December to February) than the averaged historical conditions. Conversely, during the warmest months of the study season (i.e., November and April in the southern regions, October in the northern regions), eastern Canada could experience less freezing rain events late this century. The increase in the number of daily freezing rain events in the future for the coldest months is projected to be progressively greater from south to north or from southwest to northeast across eastern Canada. The relative decrease in magnitude of future daily freezing rain events in the warmest months is projected to be much less than the relative increase in magnitude in the coldest months. 相似文献
20.
Lucas da Costa Santos Jefferson Vieira Jos&#; Fabiani Denise Bender Daniel Soares Alves Pablo Ricardo Nitsche Elton Fialho dos Reis Rubens Duarte Coelho 《Theoretical and Applied Climatology》2020,140(1):55-68
The hydrological variable evapotranspiration (ET) is challenging to estimate because it cannot be measured directly in natural environments (except in small plots). The uncertainties associated with the models used for its prediction have increased under climate change conditions. We studied the influence of stomatal resistance on ET estimates using the Penman-Monteith method as projected by three general circulation models in two emission scenarios (RCP4.5 and RCP8.5) for future climates throughout the twenty-first century (2010–2039, 2040–2069, and 2070–2099). We also investigated the probable ET rate changes in relation to the current (30 years average, 1980–2009) climate conditions for the Paraná state in the southern region of Brazil. The results were regionalized to help policymakers assess climate change impacts and design adaptation measures. ET increases of up to 15% were found in future climate conditions, which may lead to a significant increase in the water demand for agricultural crops. However, we believe that plant morphophysiological changes may occur under atmospheric CO2 enrichment conditions and that a possible reduction in stomatal conductance will result in lower ET increases than those obtained with the traditional Penman-Monteith method. When considering future climate scenarios, we propose the equation be adjusted to consider stomatal resistance as a function of CO2 concentrations. 相似文献