ENVGEO362 Lecture 2 Fall 2024 PDF

Summary

This document, part of an ENVGEO362 lecture, examines natural resource management, focusing on water resources. It details the physical aspects of water resources, their uses, and the challenges in managing groundwater.

Full Transcript

Natural resource management

2. Water resource
management
Some physical aspects of water resources
Water resources and their uses
Main sources:
– Physical Geography, Strahler & Archibold
– Textbook chapter 14
Intro: the cycling of water on the continents

As water is a mobile resource, it is important to have a good
understanding of some physical aspects of water resources.

Earth's water: what is where?
Spheres showing available
quantities globally:
(1) All water (sphere over western
U.S., 860 miles in diameter),
(2) Fresh liquid water in the
ground, lakes, swamps, and rivers
(sphere over Kentucky, 169.5
miles in diameter),
(3) Fresh-water lakes and rivers
(sphere over Georgia, 34.9 miles
in diameter).

Source: http://water.usgs.gov
Intro: the cycling of water on the continents

Source:
Reviews of Geophysics
Volume 50, Issue 4,
RG4003, 8 NOV 2012
DOI:
10.1029/2012RG000389
http://onlinelibrary.wiley.com/doi/10.1029/2012R
G000389/full#rog1750-fi
g-0001

Oceanic and terrestrial sources of continental precipitation (average annual water flows
in 1,000 km³) Estimates of the
- observed main water reservoirs (black numbers, in 10 3 km3) and the
- flow of moisture through the system (red numbers, in 10 3 km3 yr−1).
Adjusted from Trenberth et al. [2007a] for the period 2002–2008 as in Trenberth et al..
Intro: the cycling of water on the continents

In terms of management of water resources, the focus is primarily on
the surplus of land precipitation over evaporation over land.

– infiltration of water from rainfall in soils, temporarily held as soil
water (soil moisture)
– runoff: e.g. when rain falls too rapidly to pass into the soil
– evapotranspiration: evaporation from the soil and transpiration
– percolation: slow movement
under the influence of gravity
beyond the soil water belt to
groundwater (here: pore spaces
in the bedrock or regolith
completely filled with water)
→ water table = top of the
saturated zone
Intro: the cycling of water on the continents

– water table: highest under hills/elevated land surfaces, vs lower in
valleys
– lakes, ponds, marshes: where the water table intersects the surface:
– very slow flow rate of subsurface water
– water table raises because of downward percolation, and lowers
because of seepage into lakes and streams
Intro: the cycling of water on the continents

– aquifers: underground layer containing abundant, freely flowing
groundwater (e.g. layers of sand or sandstone); porous rock saturated
with water
– aquitards: hold little water, relatively impermeable (e.g. layers of
clay and shale)
– where impervious rock is overlain by porous rock, groundwater can
freely move through the aquifer and cause springs
Problems of groundwater management

Rapid withdrawal of groundwater has seriously affected the
environment in many places:
– Increased urban populations and industrial developments require
larger water demands → new wells (affecting groundwater), or using
more and more surface water
– Agriculture in dry climates is heavily dependent on irrigation water
from pumped wells (especially since major river systems are likely to
be already fully used for irrigation)

Agriculture near
Taber, AB
Problems of groundwater management

* water table depletion (when depletion exceeds infiltration)
– water level in the well drops
– surrounding water table drops in the shape of a downward-
pointing cone (cone of depression)
Problems of groundwater management

* contamination of groundwater: pollutants
– contamination of wells by pollutants that infiltrate the ground and
reach the water table can be a major environmental problem arising
from groundwater withdrawal (e.g. Walkerton 2000)
– disposal of solid wastes can pose a major environmental problem
in developed countries because their advanced industrial economies
provide an endless source of garbage
Problems of groundwater management

* contamination of groundwater: saltwater intrusion in coastal
wells
– a layer of salt water from the ocean may lie under a coastal fresh
water aquifer (fresh water is less dense than salt water)
– as the freshwater aquifer is depleted, the level of salt water rises
and eventually reaches the well from below, making the well water
unusable

Source: https://www.usgs.gov/mission-areas/water-resources/science/saltwater-intrusion
Stream flow and flooding

By Shannon1 -
Own work, CC
BY-SA 4.0,
https://commons.
wikimedia.org/w/i
ndex.php?
curid=83615743

Changes in the discharge of a large river (North Saskatchewan
River), for one specific year, at Prince Albert, SK
- watershed of appr. 130K km2
Note: data can be retrieved via
https://wateroffice.ec.gc.ca/index_e.html
Stream flow and flooding
Hydrographs of larger streams show the effects of
- base flow (seepage of groundwater into the channel)
- direct input (runoff)

E.g. the hydrograph of the North Saskatchewan River in Prince
Albert:
- Dec-Ma: mainly groundwater seepage (as snowpack covers the
drainage basin)
- Ma-Apr: first peak due to snow melt on the Prairies
- June: later melt of large snowpack in headwaters near the Rockies
(+ lag time), increasing groundwater storage and base flow
- Aug/Sept: occasional rainstorms
- Nov: cold snap sets ice on the river and reduces discharge

Q: How does this annual flow cycle impact irrigation?
Q: How can global warming have an impact here?
Stream flow and flooding

River Floods
= when the discharge of a river cannot be accommodated within its
normal channel
e.g. in Ontario:
- localized high intensity short duration rainfall (often associated
with severe thunderstorms)
- ice jams (e.g. spring break up)
Note: in Ontario also often shoreline flooding related to high water
levels/high winds on the Great Lakes

https://www.cbc.ca/news/canada/kitchener-
waterloo/grca-flood-warning-entire-grand-
river-watershed-1.5424109
Stream flow and flooding

Flood plain:
broad belt of low, flat ground bordering a river channel that floods
regularly; typical for most low-gradient rivers of humid climates

Source: https://trca.ca/conservation/flood-risk-management/defining-flood-risk/
Stream flow and flooding

Fig: Precipitation and stream flow for a 800 km2 drainage basin in Ohio, following a heavy
summer rainstorm.

Stream flow
A stream’s discharge increases in response to a period of heavy
rainfall (or snow melt).
Delayed response:
– lag time = difference between the time when half of the
precipitation has occurred and the time when half the runoff has
passed downstream
Stream flow and flooding

– the delay depends e.g. on the size of the drainage basin feeding
the stream; larger drainage basins show a longer delay

– flash floods: short lag times (characteristic of streams draining
small watersheds with steep slopes); stream can quickly rise to a
high level, sometimes accompanied by great quantities of course
rock debris swept by the flood water
Stream flow and flooding
Magnitude of a flood = peak discharge (or highest stage) of the river
during flooding

Historical and real time data help to:
- understand the river’s previous behaviour
- monitor changes to predict the onset of a flood

Canadian federal and provincial agencies coordinate the forecasting
from regional centres across the country:
- analyze precipitation patterns
- analyze progress of high waters moving downstream
- compare with flood history of the specific river
→ specific flood forecasts
Stream flow and flooding
e.g. in this location, what is
a 5-year flood?
a 600 m3/s maximum
annual flood can be
expected on average every
5 years here (aka a 5-year
flood)
a 100-year flood? flood
event that has on average
a 1/100 chance (1%
probability) of being
equaled or exceeded in Fig.: flood frequency data for the Lillooet River
at Pemberton, BT. Each dot is a measured yearly
any given year. discharge in an 88-year record.
Note: these are probabilities:
a five-year flood can be
followed the next year by
another five-year flood...
Assessing Canada’s water resources
Q: Some countries in the world are water poor; they cannot afford
the cost of sustainable clean water to all people at all times.
- Would you consider Canada water rich or water poor in
comparison to the rest of the world?
- Which data would you need to realistically assess this?

https://cropinno.com/2022/08/06/
https://www.country1053.ca/2019/09/27/ drought-in-canadian-farms/
new-nature-trail-in-big-trout-bay/
Water resources and their uses

Source:
https://tableau.apps.fao.org/views/ReviewDashboard-v1/country_dashboard?
%3Adisplay_count=n&%3Aembed=y&%3AisGuestRedirectFromVizportal=y&
%3Aorigin=viz_share_link&%3AshowAppBanner=false&%3AshowVizHome=n
Water resources and their uses

Source:
https://tableau.apps.fao.org/views/ReviewDashboard-v1/country_dashboard?
%3Adisplay_count=n&%3Aembed=y&%3AisGuestRedirectFromVizportal=y&
%3Aorigin=viz_share_link&%3AshowAppBanner=false&%3AshowVizHome=n
Water resources and their uses

Source:
https://www150.statcan.gc.ca/
n1/en/pub/11-627-m/11-627-
m2022087-eng.pdf?
st=LaSGRQqz
Water resources and their uses

Source:
https://www.canada.ca/en/environme
nt-climate-change/services/environm
ental-indicators/water-withdrawal-
consumption-sector.html

- some sectors have high consumption of water used
(e.g. agriculture and oil and gas);
- other sectors return most of the water withdrawn
(e.g. thermal power generation)
Source:
https://www15
0.statcan.gc.ca
/n1/daily-quoti
dien/170321/g-
b001-eng.htm
Assessing Canada’s water resources

- Average precipitation in Canada: 600 mm annually (a bit less
than the average worldwide)
-Average runoff (renewable): 330 mm annually (runoff:
precipitation that eventually flows into rivers and streams)
- Canada: 7% of the world's renewable runoff (one of the highest
total renewable water resources per capita worldwide)
- Canada: on top of this also a lot of non-renewable water
resources, totaling 20% of the world's total freshwater supply
(e.g. only 1% of water supply of the Great Lakes is renewed on an
annual basis).
- but: looking at the total amount does not tell the whole story;
assessing Canada’s water resources needs to be based on more
than just the total amount: the volume available is very diverse
from region to region, the variability changes throughout the year,
the importance for ecosystems, water quality,...
Assessing Canada’s water resources
(a) volume available in specific places:
runoff in parts of the southern prairies less than 50mm/yr
vs. 2.000+mm/yr in parts of BC

Source:
https://www150.statcan.gc.ca/
n1/daily-quotidien/170321/mc-
b001-eng.htm
Assessing Canada’s water resources
(b) variability:
- times of year when it is available (in parts of the country where
stream flow is linked strongly to snowmelt, the majority of total
annual flow occurs in spring, e.g. Saskatchewan River Basins in
southern Alberta: most of the stream flow in May and June)
- variability from year to year (e.g. 1.7 billion to 13.2 billion m³/year
flow volume in the river described).
See e.g. annual changes in the amount of water flowing in Canada's
rivers (2001-2019) at
https://www.youtube.com/watch?v=6XcMWiNYy04&t=51s

Natural ecosystems are adapted to this variability, but human
societies are at risk from too little/too much
--> humans have become adept at controlling when and where
water flows e.g. using dams and reservoirs, esp. in southern
Canada
Assessing Canada’s water resources
(b) variability:
- data on runoff and precipitation (knowing the frequency of high
and low flows during the last 30 years): allows water managers to
make meaningful assumptions about future water availability
(based on “stationarity” = statistical concept that allows/allowed
planners to assume that the future will be similar to the past)

- however, variability will increase due to climate change:
timing of precipitation, means and extremes of precipitation,
evapotranspiration, rates of discharge of rivers …
→ the past will no longer be a reliable guide to the future; water
management will become more difficult as uncertainty increases

aka “death of stationarity”
Assessing Canada’s water resources
(c) importance for ecosystems:
Withdrawals of surface water/groundwater (especially when
withdrawals increase during dry periods)

--> can affect base flow in streams and rivers (since the base flow is
supported by groundwater discharge), especially important in
drier summer months

--> reduced base flows also means reduced surface water flows in
streams and rivers; this affects the quality of aquatic habitats, or
leaves insufficient flows in rivers for dilution of wastewater
treatment plant effluent,...
Assessing Canada’s water resources
(d) water quality:

Water pollution through point sources (e.g. sewage, industrial
discharge), or non-point sources (e.g. agricultural runoff)
- phosphorous (e.g. runoff from farm fields) can accelerate
eutrophication, algae, reducing dissolved oxygen levels, and
degrading habitat quality for fish/aquatic organisms
- industrial discharges, atmospheric deposition: toxic substances e.g.
heavy metals, PCBs

- water pollution can also threaten human health,
e.g. Walkerton case (see textbook p. 351): runoff from livestock
farm → municipal well → 7 casualties and 2K+ seriously ill →
complete overhaul of Ontario’s approach to drinking water safety
e.g. (boiling) water advisories in many First Nations communities,
see e.g. https://www.sac-isc.gc.ca/eng/1506514143353/1533317130660
Assessing Canada’s water resources
(e) human use and activities
Human activities stress the
- quality of (ground)water: groundwater can be contaminated from
leaking underground storage tanks, chemical spills, urban and
rural land-use practices
- quantity of groundwater:
- about ¼ of Canadians rely on groundwater for drinking water
- appr. 40% of agricultural water (and some of the industrial
water as well) is supplied by groundwater

Climate change gives significant extra concerns:
- quantity concerns (reductions) for many parts of the country
- quality concerns: increased surface temperatures, reduced
assimilative capacity, saltwater intrusion in aquifers in coastal
areas