An Overview of Climate Change Induced Hydrological Variations in Canada for Irrigation Strategies

Climate change is impacting different parts of Canada in a diverse manner. Impacts on temperature, precipitation, and stream flows have been reviewed and discussed region and province-wise. The average warming in Canada was 1.6 °C during the 20th century, which is 0.6 °C above the global average. Spatially, southern and western parts got warmer than others, and temporally winters got warmer than summers. Explicit implications include loss of Arctic ice @ 12.8% per decade, retreat of British Columbian glaciers @ 40–70 giga-tons/year, and sea level rise of 32 cm/20th century on the east coast, etc. The average precipitation increased since 1950s from under 500 to around 600 mm/year, with up to a 10% reduction in Prairies and up to a 35% increase in northern and southern parts. Precipitation patterns exhibited short-intense trends, due to which urban drainage and other hydraulic structures may require re-designing. Streamflow patterns exhibited stability overall with a temporal re-distribution and intense peaks. However, surface water withdrawals were well under sustainable limits. For agriculture, the rainfed and semi-arid regions may require supplemental irrigation during summers. Availability of water is mostly not a limitation, but the raised energy demands thereof are. Supplemental irrigation by water and energy-efficient systems, adaptation, and regulation can ensure sustainability under the changing climate.

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Effects of Climate Change on the Stream Flows in Upper Middle Fork Feather River Watershed and on the Groundwater Stresses in Sierra Valley Aquifer Based on Long-Term Dynamical Downscaling

World Environmental and Water Resources Congress 2017 ◽

10.1061/9780784480618.057 ◽

2017 ◽

Author(s):

M. S. Ceyhan ◽

A. Dib ◽

K. Ishida ◽

M. L. Kavvas ◽

N. Ohara ◽

...

Keyword(s):

Climate Change ◽

Dynamical Downscaling ◽

Stream Flows ◽

River Watershed ◽

Feather River ◽

Middle Fork

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CONSTRAINING LATEST HOLOCENE EXPANSION AND 20TH CENTURY RETREAT OF A SMALL CANADIAN ARCTIC ICE CAP USING ENTOMBED VEGETATION

10.1130/abs/2016am-287890 ◽

2016 ◽

Author(s):

Simon L. Pendleton ◽

◽

Gifford H. Miller ◽

Robert S. Anderson ◽

Sarah E. Crump

Keyword(s):

20Th Century ◽

Canadian Arctic ◽

Ice Cap ◽

Arctic Ice

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Economic damages from Hurricane Sandy attributable to sea level rise caused by anthropogenic climate change

Nature Communications ◽

10.1038/s41467-021-22838-1 ◽

2021 ◽

Vol 12 (1) ◽

Author(s):

Benjamin H. Strauss ◽

Philip M. Orton ◽

Klaus Bittermann ◽

Maya K. Buchanan ◽

Daniel M. Gilford ◽

...

Keyword(s):

Climate Change ◽

Sea Level Rise ◽

Sea Level ◽

East Coast ◽

The United States ◽

Hurricane Sandy ◽

Water Levels ◽

Anthropogenic Climate Change ◽

Economic Damage ◽

Sea Levels

AbstractIn 2012, Hurricane Sandy hit the East Coast of the United States, creating widespread coastal flooding and over $60 billion in reported economic damage. The potential influence of climate change on the storm itself has been debated, but sea level rise driven by anthropogenic climate change more clearly contributed to damages. To quantify this effect, here we simulate water levels and damage both as they occurred and as they would have occurred across a range of lower sea levels corresponding to different estimates of attributable sea level rise. We find that approximately $8.1B ($4.7B–$14.0B, 5th–95th percentiles) of Sandy’s damages are attributable to climate-mediated anthropogenic sea level rise, as is extension of the flood area to affect 71 (40–131) thousand additional people. The same general approach demonstrated here may be applied to impact assessments for other past and future coastal storms.

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The Impact Assessment of Climate Change on Building Energy Consumption in Poland

Energies ◽

10.3390/en14144084 ◽

2021 ◽

Vol 14 (14) ◽

pp. 4084

Author(s):

Hassan Bazazzadeh ◽

Peiman Pilechiha ◽

Adam Nadolny ◽

Mohammadjavad Mahdavinejad ◽

Seyedeh sara Hashemi safaei

Keyword(s):

Climate Change ◽

Energy Consumption ◽

Thermal Load ◽

Building Energy ◽

Building Energy Consumption ◽

Building Sector ◽

Energy Demands ◽

Heating Load ◽

The Impact ◽

The City

A substantial share of the building sector in global energy demand has attracted scholars to focus on the energy efficiency of the building sector. The building’s energy consumption has been projected to increase due to mass urbanization, high living comfort standards, and, more importantly, climate change. While climate change has potential impacts on the rate of energy consumption in buildings, several studies have shown that these impacts differ from one region to another. In response, this paper aimed to investigate the impact of climate change on the heating and cooling energy demands of buildings as influential variables in building energy consumption in the city of Poznan, Poland. In this sense, through the statistical downscaling method and considering the most recent Typical Meteorological Year (2004–2018) as the baseline, the future weather data for 2050 and 2080 of the city of Poznan were produced according to the HadCM3 and A2 GHG scenario. These generated files were then used to simulate the energy demands in 16 building prototypes of the ASHRAE 90.1 standard. The results indicate an average increase in cooling load and a decrease in heating load at 135% and 40% , respectively, by 2080. Due to the higher share of heating load, the total thermal load of the buildings decreased within the study period. Therefore, while the total thermal load is currently under the decrease, to avoid its rise in the future, serious measures should be taken to control the increased cooling demand and, consequently, thermal load and GHG emissions.

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Changes in U.S. East Coast Cyclone Dynamics with Climate Change

Journal of Climate ◽

10.1175/jcli-d-14-00418.1 ◽

2015 ◽

Vol 28 (2) ◽

pp. 468-484 ◽

Cited By ~ 29

Author(s):

Christopher G. Marciano ◽

Gary M. Lackmann ◽

Walter A. Robinson

Keyword(s):

Climate Change ◽

Boundary Conditions ◽

Potential Vorticity ◽

East Coast ◽

The United States ◽

Sea Level Pressure ◽

Cyclone Intensity ◽

Field Amplification ◽

Lateral Boundary Conditions ◽

Relative Potential

Abstract Previous studies investigating the impacts of climate change on extratropical cyclones have primarily focused on changes in the frequency, intensity, and distribution of these events. Fewer studies have directly investigated changes in the storm-scale dynamics of individual cyclones. Precipitation associated with these events is projected to increase with warming owing to increased atmospheric water vapor content. This presents the potential for enhancement of cyclone intensity through increased lower-tropospheric diabatic potential vorticity generation. This hypothesis is tested using the Weather Research and Forecasting Model to simulate individual wintertime extratropical cyclone events along the United States East Coast in present-day and future thermodynamic environments. Thermodynamic changes derived from an ensemble of GCMs for the IPCC Fourth Assessment Report (AR4) A2 emissions scenario are applied to analyzed initial and lateral boundary conditions of observed strongly developing cyclone events, holding relative humidity constant. The perturbed boundary conditions are then used to drive future simulations of these strongly developing events. Present-to-future changes in the storm-scale dynamics are assessed using Earth-relative and storm-relative compositing. Precipitation increases at a rate slightly less than that dictated by the Clausius–Clapeyron relation with warming. Increases in cyclone intensity are seen in the form of minimum sea level pressure decreases and a strengthened 10-m wind field. Amplification of the low-level jet occurs because of the enhancement of latent heating. Storm-relative potential vorticity diagnostics indicate a strengthening of diabatic potential vorticity near the cyclone center, thus supporting the hypothesis that enhanced latent heat release is responsible for this regional increase in future cyclone intensity.

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Predicted changes in energy demands for heating and cooling due to climate change

Physics and Chemistry of the Earth Parts A/B/C ◽

10.1016/j.pce.2010.03.003 ◽

2010 ◽

Vol 35 (1-2) ◽

pp. 100-106 ◽

Cited By ~ 25

Author(s):

Mojca Dolinar ◽

Boris Vidrih ◽

Lučka Kajfež-Bogataj ◽

Sašo Medved

Keyword(s):

Climate Change ◽

Heating And Cooling ◽

Energy Demands

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Comparative Analysis or Precipitation Variation Characteristics between Subtropical Monsoon Climate and Temperate Monsoon Climate-Take Changsha and Chengde for Example

Tobacco Regulatory Science ◽

10.18001/trs.7.5.29 ◽

2021 ◽

Vol 7 (5) ◽

pp. 1113-1122

Author(s):

Bo Chen ◽

Shi-jun Xu ◽

Xin-ping Zhang ◽

Yi Xie

Keyword(s):

Climate Change ◽

Extreme Precipitation ◽

Precipitation Intensity ◽

Annual Precipitation ◽

Wet Season ◽

Precipitation Frequency ◽

Extreme Precipitation Events ◽

Average Precipitation ◽

Autumn And Winter ◽

Average Annual Precipitation

Using the methods of literature review, regression analysis and moving average, this paper selects the daily precipitation of Changsha and Chengde from 1951 to 1986 as samples, and analyzes the average precipitation, precipitation frequency, precipitation intensity, extreme precipitation time and other indicators of Changsha and Chengde from the perspective of interannual and seasonal changes Trends. The researches show that: the average precipitation of Changsha in the 36 years is 1151.2mm, spring is the wet season, autumn and winter are the dry seasons, and the maximum average precipitation is in spring; the average annual precipitation, precipitation frequency in spring, summer and winter, annual precipitation frequency, annual precipitation intensity and extreme precipitation events show a decreasing trend. The average annual precipitation of Chengde city is 454.1 mm, wet season in summer and dry season in spring, autumn and winter; the average annual precipitation, precipitation in four seasons, annual precipitation frequency, precipitation frequency in spring, autumn and winter, annual precipitation intensity and extreme precipitation events show a decreasing trend, while the precipitation frequency in summer shows an increasing trend. The study of regional climate change based on the time series data of this stage is of great significance to comprehensively understand the law of regional climate change and predict the future trend of climate change.

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