INTRODUCTION
The concept of “likelihood” in applied hydrology plays numerous roles in
the design and performance of stormwater, wastewater, and natural drainage
systems. Likelihood is typically
represented in terms of a return period, an abstract representation of how
often an event of at least a particular size is expected to occur on average
over an extended time. This might sound
straightforward, but within this basic concept are a variety of difficulties of
both perception and reality that reward some study and reflection, especially
in the context of recent extreme rainfall events that highlight system capacity
limitations.
This paper explores how suggested changes in extreme rainfall return
periods have occasionally been mischaracterized compared to measured long-term
data trends in Environment and Climate Change Canada’s (ECCC’s) Engineering
Climate Datasets. Trends across Canada, southern
Ontario, and the Greater Toronto Area (GTA) are reviewed, including clarifications
following reviews by Canada’s Minister of the Environment and CBC Ombudsman
offices. Mischaracterizations may stem
from faulty intuitive perceptions or cognitive biases based on limited
available data, such as statements on the rarity of multiple extreme events
that fail to recognize the proliferation of rainfall monitoring stations in the
GTA. This paper statistically explores the rarity of such events, considering
the areal extent of storms and the independence/dependence of adjacent
gauges. It also shares examples of
often-overlooked historical great rainfalls and floods, based on newspaper
archives dating back to 1878 and ECCC records to 1840. These historical records, along with 2024
event data, are used to assess trends in Toronto’s 100-year rainfall.
While
the data does not suggest increases in extreme rainfall intensities in Toronto or
southern Ontario, other factors such as antecedent moisture conditions (defined
by multi-day rainfall) affect storm runoff and extraneous wastewater flow
responses. Thus, multi-day trends in Toronto and the western Lake Ontario
basin, based on long-term ECCC records that are typically over 150 years in
length, are assessed.
The spatial and temporal variability of 2024 extreme rainfall is
analyzed using event total volumes and selected short-duration intensity data
for several events. Data for 153 gauges in York Region,
Toronto and Peel Region were used to characterize areal reduction factors
around peak gauges, comparing with design factors and assumed values in some
local hydrologic analysis. Rainfall
atlas factors from the US mid-west and observed factors in August 2024 suggest that
values assumed in local studies could
be unconservative. Variations
in rainfall uniformity across a City and Region are also evaluated, comparing
convective storms, hurricane remnants, and spring storm characteristics,
highlighting the complexity of ‘real’ storms.
Lastly, while storm events are often characterized by rain gauge total
event volumes and their return periods, these statistics do not align with the
return period of system peak flows. For wastewater
systems in particular, peak flows are more closely correlated with
short-durations intensities. It is proposed that short-duration rainfall
metrics be considered a valuable supplement to total event characterizations.
INTUITIVE PERCEPTIONS OF PROBABILITY VS. DATA TRENDS
Following extreme rainfall events, media commentary often demonstrates
common biases in estimating an event’s rarity or severity, usually without
rigorous statistical analysis. Psychologist and Nobel laureate Daniel Kahneman
identified various biases in his book Thinking Fast and Slow (2013), and
local examples in the context of flooding and extreme rainfall have been
described by others (Muir, 2018). Politicians across Canada have routinely
declared trends in severe storms, for example:
i)
Prime
Minister Trudeau, after the 2017 Gatineau/Ottawa River flood, stated:
"The
frequency of extreme weather events is increasing, and that's related to
climate change. We're going to have to understand that bracing for a 100-year
storm is maybe going to happen every 10 years. Or every few years."[1]
ii)
Toronto
Mayor Tory stated to the CBC, following a federal grant for flood relief works:
"Toronto is
experiencing more severe storms, with more rain falling over a short amount of
time.”[2]
Requests for data on storm frequency and
severity have supported these claims. In
2019, Environment and Climate Change Canada Minister Catherine McKenna
responded on behalf of the PMO, writing that "the observational record has
not yet shown evidence of consistent changes in short-duration precipitation
extremes across the country"[3].
The General Manager of Toronto Water responded that the City would adjust its
messaging to not describe actual storms:
“We apologize for the delay in getting back to you
with regards to your question about the statement on storms being 'more severe'
and occurring over a 'short amount of time' and the City's messaging. We will
utilize language that describes what can happen to City infrastructure during a
rainfall rather than describing the actual rainstorm.”
(Personal
communication, L. Di Gironimo to R. Muir, July 29, 2019)
To improve media messaging, the authors of
this paper have highlighted these biases in media coverage through the Financial
Post[4]
and in a ‘Backgrounder’ document for the CBC Ombudsmen, to assist CBC and
Radio-Canada editors scrutinize reports on extreme weather and flooding. This
CBC Backgrounder was intended to improve reporting accuracy, given several
recent violations of the CBC’s Journalistic Standards and Practices in 2019 and
2020 regarding extreme rainfall trends[5] [6]
[7].
To contrast statements by political figures and the media, ECCC’s long-term
datasets have been used to characterize national and local trends in extreme
rainfall. These trends are reported in
the National Research Council of Canada (NRC) Guidelines on Undertaking a
Comprehensive Analysis of Benefits, Costs and Uncertainties of Storm Drainage
Infrastructure and Flood Control Infrastructure in a Changing Climate (2021). The
findings align with Minister McKenna’s statement above, namely, that there is no
overall increase in extremes at 226 climate stations across Canada when the
last 10 years of data area added, in southern Ontario’s local IDF statistics when
comparing 1990 IDF statistics with v3.1 Engineering Climate Datasets, or in
local Toronto-area extreme rainfall IDF analyses.
Media
and layperson statements suggesting changes in extreme rainfall often arise
from an ‘availability bias’, a cognitive short-cut defined by Kahneman whereby
judgments rely on easily recalled information rather than comprehensive data.
This tendency overlooks many historical flood events that reveal no clear
upward trend. For example, Toronto’s significant rainfall and flooding events stretch
back over 150 years, with newspaper archives documenting numerous “great
floods”. FIGURE 1 compiles sample newspaper clippings from extreme events in 1878,
1897, and 1905. The “Great Flood”[8]
of 1878 resulted in the loss of 4 lives, or 1/20,000 of the population of about
80,000[9],
equivalent to a staggering 233 lives lost in 2024 based on today’s population.
FIGURE 1 – HISTORICAL FLOOD REPORTS PER
NEWSPAPER ARCHIVES (LATE 1800’s AND EARLY 1900’s)
Note: [Left] “The
Great Rainstorm”, The Globe and Mail, Sept. 14, 1878; [Centre] “Torrents of
Water”, The Globe and Mail, July 28, 1897, [Right] “Worst Storm of Year Sweeps
Over Toronto”, The Toronto Star, August 15, 1905.
Notwithstanding the actual data trends, following the July 16th,
2024 extreme rainfall in the GTA, claims of increasing storm frequency and
severity were widely reported. For example, a post-storm City of Toronto
council motion stated: “As a result of climate change, Toronto is experiencing
more frequent and severe storms, resulting in flooding events that impact our
road and transit network, our homes and businesses, and our infrastructure.”[10]
A Freedom Of Information (FOI) request to the City of Toronto for documentation
showing more frequent and/or more severe storms in Toronto indicated that
“despite a thorough search, they [Toronto Water Division] were unable to locate
any records responsive to your request. The following sections analyze the
probability of multiple extreme events and review southern Ontario trends,
including the impact of 2024 extreme rainfall on Toronto-area IDF
statistics. This analysis encourages use
of the more reflective “System 2” for analytical thinking, rather than the fast
and intuitive “System 1” when assessing claims of increasing severity and
frequency.
PROLIFERATION
OF RAINFALL GAUGES AND THE PROBABILITY OF MULTIPLE EXTREME EVENTS
Over
the past 40 years, municipalities in Ontario have invested heavily in
wastewater system monitoring and capacity to accommodate high extraneous flows
during wet weather. To support this
work, continuous, permanent monitoring of rainfall rates and wastewater flow
rates has proliferated across southern Ontario.
For example, the City of Toronto operated 17 rain gauges in 1982[12],
equivalent to one every 36 sq.km, similar to a 6 km grid. By 2013[13],
the City operated 35 gauges. In late 2024[14]
Toronto operated 50 gauges,
one every 12.4 sq.km, similar to a 3.5 km grid.
As a result of this higher density, more localized or short-lived storms
are captured, leading to apparent increases in the frequency of “extreme”
events that could otherwise pass between earlier, more coarsely-spaced gauges.
Across the GTA, other municipalities and regions have also increased the
number of permanent rain gauges as well:
● York Region increased their number of gauges
from 10 before 2008, to 18 in 2008[15], and 44 in 2024. The
combined total number of Regional, lower-tier municipality and Conservation
Authority gauges in 2024 is 72.
Lower-tier municipality, the City of Markham, increased from limited gauges before 2008, to 6 in 2008, and 13 in
2024[16].
● Peel Region increased from 8 before 2013, 28 in
2013, and 30 in 2024[17].
Combined with others including the City of Mississauga, and Conservation
Authorities, Peel Region has 64 rain gauges in 2024.
Combined, Toronto, Peel Region and York Region operate a total of 186
gauges in 2024, compared to half that number in earlier years pre-2008. A total
of 34 Halton Region gauges were in operation during the August 2014 Burlington
severe storm, according to Conservation Halton open data sources[18].
This brings the total number of gauges in the GTA (except for Durham) to 220.
TABLE 1 summarizes the number of gauges across Toronto, Peel and York
reporting over 86.3 mm of rainfall, equivalent to the York Region 24-hour
100-year rainfall totals, during three 2024 events.
TABLE 1 – RAINFALL GAUGES WITH 100-YEAR
RAINFALL VOLUME DURING JUNE, JULY AND AUGUST 2024 SEVERE STORM EVENTS
|
Region/Municipality
|
2024 Rainfall Event
|
|
June 19
|
July 16
|
August 17
|
|
Toronto (50
gauges)[19]
|
0
|
3
|
12
|
|
York (61 gauges)
|
2
|
0
|
10
|
|
Peel (42 gauges)
|
0
|
8
|
3
|
While 100-year rainfall totals were observed during each event, the
extent of extreme totals varied considerably across the events with only 2 of
153 gauges reporting over 86.3 mm on June 19th in York Region,
compared to 25 of 153 gauges on August 17th. It is suggested that the size of dependent
100-year gauge clusters is between 2 and 25 gauges. Accordingly, there may be a broad range of 7
to 93 independent samples among the
186 GTA gauges.
The insurance industry has suggested (argued?)
that the frequency of extreme rainfall events has increased due to climate
change effects[20]. However, many of these claims are based on theoretical
as opposed to observed data (Muir, 2018). A 2019 City of Toronto Council Member
Motion referenced the Insurance Bureau of Canada in stating that the GTA has
had six 100-year storms from 2005 to 2018 and that there were “a direct result
of climate” and sought to pursue legal option to recoup flood-related costs
from GHG emitters.
The risk of multiple extreme events over a
given period can be estimated to assess whether six 100-year storms would be
rare (or not) over 12 years. Assumptions
must first be made about how statistically independent or dependent rain gauges
records are. This affects the effective
number of samples observed. Lower risks
would be estimated when most rain gauges are assumed to be independent, such
that in each year of observation each of the gauge clusters provides a
sample. For small clusters of 2 gauges (e.g., June 2024
storm), the 186 GTA gauges above would result in 93 samples in each of the 12
years resulting in 1116 samples. Higher
risks would be estimated with larger clusters (e.g., August 2024 storm). With a cluster size of 25 gauges, there are
186/25 x 12 = 89 samples.
Using the online Stat Trek tool,[21]
probabilities of multiple 100-year events were calculated for various scenarios
over 12 to 21 years. Scenario 1 and 2 are based on six 100-year storms over 12
years (2005 to 2018) in the GTA, as quoted by the IBC[22]. A review indicates the reported storms
include both small areal extent (e.g., Mississauga Aug. 4, 2009 and Toronto
Aug. 7, 2018) and large areal extent storms (e.g., GTA Aug. 19 2005, July 8,
2013, and Aug. 4, 2014). The 2017 event is believed to have included
Orangeville, Ontario rainfall (June 22-23, 2017) or include the Lake Ontario
high water level event. Scenario 3 is
based on 12 events across southern Ontario over 21 years (2004-2024), as
presented in the Nov. 2024 CVC Stormwater & Climate Change Seminar.
TABLE 2 – PROBABILITY OF MULTIPLE STORMS
ACROSS THE GTA
|
Gauge
Cluster Size
|
Number
of Independent Clusters
(= 220 / cluster size)
|
Scenario
1 a
|
Scenario
2 b
|
Scenario
3 c
|
|
2
(Jun. 2024)
|
110
|
99.1% d
|
N/A
|
N/A
|
|
|
11
(Jul. 2024)
|
20
|
3.5% (6 events)
9.5 % (5 GTA events) e
|
22.1% f
|
53.9% g
|
|
25
(Aug. 2024)
|
8.8
|
N/A
|
10.1% h
|
N/A
|
|
a
Extent = Small & Large; # Years =
12; # Events = 6 (2005, 2009, 2013, 2014, 2017, 2018)
b
Extent = Large; # Years = 12; # Events =
4 (2005, 2013, 2014, 2024)
c
Extent = Small & Large; # Years =
21; # Events = 12 (2004x2. 2005x2, 2009, 2013, 2014, 2013, 2017x2, 2018, 2024)
d 110x12
= 1320 samples
e
Five events excl. 2017 Orangeville rainfall outside GTA; 20x12 = 240 samples
f 20x12
= 240 samples
g 20x21
= 420 GTA samples, factor by 5x for S.Ont. including Stoney Creek,
Peterborough, Orangeville and Elmira = 2100
h 8.8x20
= 176 samples
Considering large areal extent storms, the risk of 4 events such as
those in 2005, 2013, 2014 and 2024 would be in the range of 10.1% to 22.1% over
12 years (see Scenario 2). When the areal extent and number of gauges
increases, the probability decreases such as in Scenario 3. The number of
gauges has been factored up to represent the larger area of southern Ontario in
which twelve 100-year events have been reported over 21 years (2004-2024).
Assuming an average gauge cluster size of 11 to represent both the small and
large areal extent storms, the probability of 12 100-year events over 21 years
is quite high at over 50%.
The
probability should account for both event volume and its spatial coverage. As
noted by Adams and Howard (1986) in their paper Design Storm Pathology:
Obviously, a natural
hydrological event containing many characteristics cannot be fully described by
statistics of only one, or at most a few, of the characteristics of the natural
event.
The
challenge of characterizing the complexities of individual storms would support
the Toronto Water position to “utilize language that describes what can happen
to City infrastructure during a rainfall rather than describing the actual
rainstorm”.
To this end, this paper concludes by contrasting
infrastructure responses compared to rainfall inputs. Yet, practitioners must
make assumptions regarding the areal extent of design storms in hydrologic
analyses and so later sections evaluate storm size and areal reduction curves
considering 2024 events, local hydrology studies, and industry references that
may implicitly account for the probability of storm areal extent.
SOUTHERN ONTARIO IDF TRENDS
In
the 2021 NRC Flood Cost Benefit Guideline, IDF statistics from 1990 were
compared with those from ECCC’s v3.1 dataset (up to 2017), where no overall
increase in extreme rainfall intensities for 21 southern Ontario stations were
found. TABLE 3 updates that analysis to 2021 (v3.3), where results show minor
or insignificant increases or decreases across various durations and return
periods.
TABLE 3 – AVERAGE
CHANGE IN SOUTHERN ONTARIO IDF - ECCC IDF TABLES PRE V.1 DATA (TO 1990) VS.
V3.30 DATA (TO 2021)
|
Duration
|
Return
Period
|
|
2-Year
|
5-Year
|
10-Year
|
25-Year
|
50-Year
|
100-Year
|
All
|
|
5 min
|
-2.1%
|
-1.6%
|
-1.6%
|
-1.6%
|
-1.4%
|
-1.4%
|
-1.6%
|
|
10 min
|
-0.1%
|
0.0%
|
0.0%
|
0.2%
|
0.2%
|
0.2%
|
0.1%
|
|
15 min
|
-0.2%
|
0.1%
|
0.3%
|
0.5%
|
0.6%
|
0.7%
|
0.3%
|
|
30 min
|
-0.1%
|
0.3%
|
0.5%
|
0.6%
|
0.7%
|
0.8%
|
0.5%
|
|
1 hr
|
0.0%
|
0.4%
|
0.5%
|
0.6%
|
0.8%
|
0.8%
|
0.5%
|
|
2 hrs
|
-1.3%
|
-0.9%
|
-0.8%
|
-0.7%
|
-0.5%
|
-0.5%
|
-0.8%
|
|
6 hrs
|
-1.5%
|
-1.4%
|
-1.5%
|
-1.5%
|
-1.5%
|
-1.5%
|
-1.5%
|
|
12 hrs
|
-1.1%
|
-0.4%
|
-0.2%
|
0.0%
|
0.2%
|
0.3%
|
-0.2%
|
|
24 hrs
|
-0.4%
|
-0.3%
|
-0.3%
|
-0.3%
|
-0.2%
|
-0.2%
|
-0.3%
|
|
Avg.
|
-0.8%
|
-0.4%
|
-0.3%
|
-0.2%
|
-0.1%
|
-0.1%
|
-0.3%
|
Stations:
Sarnia Airport, Chatham WPCP, Delhi CS, Port Colborne, Ridgetown RCS, St Catharine’s
Airport, St. Thomas WPCP, Windsor Airport, Brantford MOE/Airport, Fergus Shand
Dam, Guelph Turfgrass CS, London CS, Mount Forest (Aut), Stratford WWTP,
Waterloo Wellington Airport, Bowmanville Mostert, Hamilton Airport, Hamilton
RBG CS, Oshawa WPCP, Toronto City, Toronto International Airport (Pearson).
Overall,
these minor changes are neither statistically nor practically significant to design.
The analysis considers 1026 station-years of data with an average record period
of 49 years.
TORONTO-AREA IDF TRENDS
Toronto-area IDF trends can be further explored considering the effect
of the July 16 and August 17, 2024 storms.
ECCC’s v3.3 datasets (to 2021) for the long-term stations Toronto City
(i.e., “Bloor Street” ID 6158355) and Toronto Intl. Airport (i.e., Pearson
Airport, ID 6158731) indicate 100-year 24-hour rainfall volumes of 97.3 mm and
117.3 mm, respectively. Adding subsequent years maxima and the July 2024
rainfall of 83.6 mm at Toronto City[23] and
August 2024 rainfall of 128.3
mm[24]
at Pearson, the 100-year 24-hour rainfall increases to 98.4 mm and 122.2 mm. While the Pearson A.
statistic has increased, it is virtually unchanged from the 1990 statistic
(121.5 mm). The Toronto City statistic is 2.6% above the 1990 value (95.9 mm).
TABLE 4 summarizes these values. These
minimal changes are consistent with municipal studies in southern Ontario that
have also found limited changes in local design intensities[25].
TABLE 4 – TORONTO CITY AND PEARSON AIRPORT
100-YEAR 24-HOUR RAINFALL STATISTICS
|
Record Period
|
Pearson
A.
|
Ratio
to 1990
|
Toronto
City
|
Ratio
to 1990
|
|
1990 (Pre v1)
|
121.5 mm
|
100.0 %
|
95.9 mm
|
100.0 %
|
|
ECCC v3.3 (to 2017/2021)
|
117.3 mm
|
96.5 %
|
97.3 mm
|
101.5 %
|
|
ECCC v3.3 extended to 2024
storms
|
122.2mm
|
100.6 %
|
98.4 mm
|
102.6 %
|
|
ECCC 1-30 Day IDF (1840-1910)
|
N/A
|
N/A
|
102.9 mm
|
107.3 %
|
These findings suggest that previous,
long-term Toronto rainfall intensities were higher than current values, but
that the changes are insignificant relative to their underlying uncertainty.
For example, the confidence intervals reported by ECCC for these 100-year
statistics are typically large (Toronto City 95% confidence limits is +- 0.6
mm/hr, equivalent to +- 14.4 mm per day). This 28.8 mm confidence band is much
wider than the changes in mean statistic values over time and suggests that
designers should be as focused on core uncertainty in rainfall statistics as
any changes in statistics (e.g., non-stationarity due to climate effects over
time).
Toronto short-duration rainfall statistics above include 5-minute to
24-hour values and consider data as early as 1940 for Toronto City and 1950 for
Pearson A. stations. ECCC’s 1–30-day IDF dataset extends significantly further
back to 1840 and have been used in ECCC analyses (Pollock, 1974). This Toronto data has been analyzed to
determine a long-term 100-year 24-hour rainfall statistic, using the same
Gumbel extreme value distribution used for the short-duration datasets. FIGURE
2 illustrates this long-term series.
The statistic for the early Toronto City
record of 1840 to 1910 is 102.9 mm, which is 4.6% higher than the v3.3 short
duration dataset with 2022-2024 added (i.e., 1940-2024). This can be explained by high rainfall events
in 1843, 1878, 1897 and 1905.
The changes in southern Ontario and Toronto-area statistics do not
support the many strong statements by political figures and the media that have
claimed increases in storm intensity.
Those statements are likely based on System 1 thinking and limited
analysis, and can demonstrate an availability bias with a lack of awareness of
many earlier extreme events noted previously. Long-term trends in southern
Ontario daily maximum rainfall have mixed results based on ECCC data[26].
FIGURE 2 - TORONTO CITY MAXIMUM 1-DAILY
RAINFALL - COMBINED ECCC 1-30 DAY, v3.3 IDF DATASETS
& 2022-2024 DAILY MAXIMA
TRENDS
IN ANTECEDENT MOISTURE CONDITIONS
Runoff and extraneous flow in wastewater systems are complex and depends
not only on peak intensities but also on soil and system moisture before a
storm. The Soil Conservation Service
(SCS) Curve Number (CN) Method accounts for this by using the total rainfall of
the preceding five days (the Antecedent Moisture Condition, or AMC). According
to this approach:
·
AMC I (dry): Less than 35 mm in
the previous five days.
·
AMC II (normal): Between 35 and
53 mm.
·
AMC III (wet): Over 53 mm.
In
Ontario, ‘return-period’ convective storms usually assume AMC II conditions, while
historical storms like Hurricane Hazel use AMC III because of high preceding
rainfall.
The ECCC 1-30 Day IDF annual series may also be used to assess trends in
multi-day rainfall in southern Ontario. FIGURE 3 illustrates a 5-day maximum rainfall
trend for Toronto from 1840 to 2002. It is noted that recent years’ data up to
2016 have been omitted due to incomplete/partial ECCC data[27].
FIGURE 3 – TORONTO CITY 5-DAY MAXIMUM
RAINFALL (ECCC 1-30 DAY IDF DATASET 1840-2002)
The data shows a slight decrease in 5-day rainfall over 162-years, with
some of the highest totals in the 1800’s (1841, 1843, 1878, 1894 and 1897).
Outside of Toronto, records for Woodstock,
Welland, and Belleville indicate slight increases in multi-day totals. For example, Welland’s 10-day rainfall has
increased by 0.16 mm per year since 1872.
York Region flow monitoring shows that the 10-day antecedent rainfall can
affect Rainfall Derived Inflow and Infiltration (RDII) in the wastewater
system. Over a 20-year planning horizon,
a Welland-type increase of 3.2 mm in 10-day rainfall (i.e., from 100.3 mm today
to 103.5 mm in 2045) could raise RDII volumes by about 3%[28]. In regions with past and projected increases
this factor could be considered in wastewater system planning, including as
part of sensitivity analysis on system response.
In practice, the key take-away for hydrologic
modelers and infrastructure designers for surface water systems is that
absolute AMC values, rather than minor trends, matter most. FIGURE 3 illustrates that the majority of
years experienced AMC III (wet) conditions, not AMC II (normal) conditions
applied in return-period storm hydrologic modelling. Given the more prevalent ‘wet’ AMC
conditions, higher CN values and more conservative runoff potential could be
considered in return-period event simulations, such as for the 100-year storm.
SPATIAL
VARIABILITY OF EXTREME RAINFALL
The July 16th, 2024 storm in Markham
demonstrated notable spatial variability.
TABLE 5 (adapted from AECOM’s York Region summary) illustrates how
rainfall intensity return periods varied across 18 Markham gauges for various
durations.
TABLE 5 – MARKHAM RAIN GAUGE RETURN PERIOD
VARIABILITY ON JULY 16, 2024
|
Site
ID
|
Rainfall Intensity by Duration
|
|
|
5
min
|
10
min
|
15
min
|
30
min
|
1
hr
|
2
hrs
|
6
hrs
|
12
hrs
|
24
hrs
|
Total Rain
|
|
R-MUN-MA-05
|
30
|
30
|
25
|
19.5
|
17.5
|
13.5
|
4.96
|
2.5
|
1.25
|
30 mm
|
|
R-MUN-MA-07
|
36
|
32.4
|
28.8
|
23.6
|
18.2
|
14
|
5.03
|
2.53
|
1.27
|
30.4 mm
|
|
R-MUN-MA-08
|
69
|
55.5
|
47
|
46.5
|
33.5
|
23.1
|
9.08
|
4.56
|
2.28
|
54.75 mm
|
|
R-MUN-MA-09
|
40.8
|
28.8
|
24.8
|
20.8
|
15
|
10.1
|
3.5
|
1.75
|
0.88
|
21 mm
|
|
R-MUN-MA-11
|
96
|
88.8
|
71.2
|
54.8
|
35.4
|
22.1
|
8.3
|
4.18
|
2.09
|
50.2 mm
|
|
R-MUN-MA-12
|
60
|
60
|
53.6
|
37.6
|
30.2
|
17.3
|
6.3
|
3.23
|
1.62
|
38.8 mm
|
|
R-MUN-MA-13
|
98.4
|
72
|
63.2
|
54.8
|
39.8
|
23
|
8.2
|
4.1
|
2.05
|
49.2 mm
|
|
R-MUN-MA-14
|
111
|
102
|
88
|
64.5
|
42.8
|
25.12
|
8.83
|
4.42
|
2.21
|
53 mm
|
|
R-MUN-MA-15
|
63
|
55.5
|
49
|
45
|
32.8
|
21.75
|
7.88
|
3.96
|
1.98
|
47.5 mm
|
|
R-MUN-MA-16
|
66
|
63
|
56
|
40
|
29
|
17.75
|
6.21
|
3.1
|
1.55
|
37.25 mm
|
|
R-MUN-MA-18
|
26.4
|
24
|
19.2
|
15.6
|
12.8
|
8.6
|
3.03
|
1.53
|
0.77
|
18.4 mm
|
|
R-MUN-MA-21
|
90
|
85.5
|
82
|
73
|
53.8
|
33.38
|
12.8
|
6.44
|
3.22
|
77.25 mm
|
|
R-MUN-MA-22
|
21.6
|
14.4
|
14.4
|
14
|
11.6
|
7.9
|
3.17
|
1.63
|
0.82
|
19.6 mm
|
|
R-TR-MA-06
|
105.6
|
90
|
80.8
|
70.8
|
44.6
|
25.4
|
8.97
|
4.5
|
2.26
|
54.2 mm
|
|
R-YR-MA-01
|
69.6
|
57.6
|
48
|
46.4
|
33.2
|
23.4
|
8.93
|
4.53
|
2.27
|
54.4 mm
|
|
R-YR-MA-03
|
64.8
|
56.4
|
52.8
|
44.4
|
33.4
|
22.1
|
8.6
|
4.37
|
2.18
|
52.4 mm
|
|
R-YR-MA-19
|
86.4
|
79.2
|
68
|
54.4
|
36.8
|
23.6
|
8.57
|
4.33
|
2.17
|
52 mm
|
|
R-YR-MA-20
|
100.8
|
81.6
|
70.4
|
59.6
|
40.6
|
23.4
|
8.37
|
4.3
|
2.15
|
51.6 mm
|
|
Return Period
|
Buttonville Airport IDF Intensities
|
|
|
2 Year Event
|
106.2
|
74.5
|
60.2
|
36.7
|
21.2
|
11.8
|
5.5
|
3.2
|
1.8
|
|
5 Year Event
|
136.4
|
95.6
|
77.8
|
51.2
|
31
|
16.6
|
7.2
|
4.1
|
2.3
|
|
10 Year Event
|
156.4
|
109.7
|
89.5
|
60.8
|
37.5
|
19.8
|
8.4
|
4.8
|
2.6
|
|
25 Year Event
|
181.7
|
127.4
|
104.3
|
72.9
|
45.6
|
23.7
|
9.8
|
5.6
|
3
|
|
50 Year Event
|
200.4
|
140.5
|
115.2
|
81.9
|
51.7
|
26.7
|
10.9
|
6.2
|
3.3
|
|
100 Year Event
|
219
|
153.6
|
126.1
|
90.8
|
57.7
|
29.6
|
12
|
6.7
|
3.6
|
|
Return Period
|
Number of Exceedances
|
% of all stats
|
|
2 Year Event
|
0
|
1
|
5
|
6
|
2
|
2
|
2
|
2
|
10
|
19%
|
|
5 Year Event
|
0
|
0
|
2
|
4
|
6
|
2
|
4
|
9
|
0
|
17%
|
|
10 Year Event
|
0
|
0
|
0
|
2
|
4
|
8
|
6
|
0
|
0
|
12%
|
|
25 Year Event
|
0
|
0
|
0
|
1
|
0
|
2
|
0
|
0
|
1
|
2.5%
|
|
50 Year Event
|
0
|
0
|
0
|
0
|
1
|
0
|
0
|
1
|
0
|
1.2%
|
|
100 Year Event
|
0
|
0
|
0
|
0
|
0
|
1
|
1
|
0
|
0
|
1.2%
|
|
|
|
|
|
|
|
|
|
|
|
|
|
Key:
|
|
more
prevalent return period for rainfall duration
|
FIGURE 5 maps the spatial variability of total rainfall volumes and categorizes
gauge intensities based on their highest return period.
FIGURE 5 – MARKHAM RAIN GAUGE MAXIMUM
INTENSITY RETURN PERIOD AND TOTAL EVENT VOLUME JULY 17, 2024
Although
this event was described as “100-year”, only 1.2% of all gauge-duration
statistics exceeded the 100-year threshold. Specifically, only the 2 and 6-hour
intensities at R-MUN-MA-21 exceeded the Buttonville Airport’s 100-year IDF
statistics. Most prevalent return
periods ranged from 2 to 10 years. Shorter-duration
intensities (less than 1 hour), which govern local storm sewer performance, generally
matched 2 to 25-year return period intensities.
The response of the wastewater collection system to this and other
events is described in a subsequent section, comparing peak flow return periods
to average and maximum rainfall return periods.
TEMPORAL
VARIABILITY OF EXTREME RAINFALL FOR DIFFERENT STORM TYPES
While the previous section illustrates spatial variability over an
entire storm, this section focuses on temporal changes in intensity. FIGURE 6 compares two events in Markham: a
convective storm on August 17th, 2024 and remnants of Hurricane
Beryl on July 10th, 2024. The
chart on the right shows highly variable accumulations across gauges for the
convective event (coefficient of variation, or COV, of 0.41), while the chart
on the left shows a more consistent accumulation for the hurricane remnant (COV
of 0.11). The temporal lags between the
highest intensities, suggest movement of highest intensity cells across the
city.
FIGURE 6 – TEMPORAL VARIABILITY OF
CONVECTIVE AND HURRICANE STORM TYPES IN MARKHAM IN 2024
Looking more broadly across York Region, the August convective storm
generally displayed the highest COV, averaging 0.51 across 69 gauges, whereas
the July hurricane remnant was more uniform (average COV of 0.18). A “spring”
event on April 2, 2024 had intermediate variability (average COV of 0.30).
When IDF statistics are derived from Annual Maximum Series (AMS), the
type of storm is not considered. That is, rainfall data resulting from
convective storms (e.g., August 2005 and July 2013 Toronto events) is combined
with rainfall data resulting from hurricane-type events (e.g., October
1954). As these events have different
origins and patterns, separate series and statistics could be considered. Others have noted the importance of
considering seasonal extreme rainfall statistics that may be explained by the
variable storm types and seasonal factors.
For instance, Dickinson (1976) noted “The implications of this seasonal
variability are significant for the estimation of flood peaks and their
frequency of occurrence.” Future
research could assess the joint probability of factors like seasonal intensity
variations and AMC conditions, particularly if rising AMC (wet) intervals align
with higher storm intensities.
AREAL
REDUCTION FOR 2024 CONVECTIVE STORMS
To
characterize the areal extent of 2024 convective storms, rainfall event volumes
were compiled from York Region, Peel Region and Toronto gauges. Peel Region data includes data for gauges
operated by the Region and the City of Mississauga. York Region data includes
Region-, municipality- and Conservation Authority-operated gauge data. FIGURES
7A, 7B and 7C illustrate total event volume surface for three major storms in June,
July and August.
FIGURE 7A – JUNE 19, 2024 GTA RAINFALL
DISTRIBUTION
FIGURE 7B – JULY 16, 2024 GTA RAINFALL
DISTRIBUTION
FIGURE 7C – AUGUST 17, 2024 GTA RAINFALL
DISTRIBUTION
Areal reduction curves were then derived for circular areas around each peak
gauge: 96.8 mm at Markham R-MUN-MA-16 (June 19th), 104.2 mm at Peel
Region RG 07 (July 16th), and 128 mm at Toronto RG-046[29]
(August 17th). FIGURE 8 shows
how average rainfall drops relative to the peak gauge volume as the area
expands.
FIGURE 8 illustrates a wide variation in areal reduction around the peak
gauge, consistent with the 100-year gauge counts noted earlier. The June event (only two gauges over 100-year
totals) had a steep drop-off in mean areal rain, whereas the more widespread
August event maintained higher volumes over a larger area. Mean rainfall for selected TRCA and CVC
watersheds is also shown, illustrating how watershed size can affect average
totals. Despite that trend the mean
Mimico Creek July rainfall was high relative to the maximum rainfall in that
watershed, despite its moderate watershed size.
FIGURE 8 – AREAL REDUCTION FOR THREE 2024
GTA EXTREME RAINFALL EVENTS COMPARED TO DESIGN GUIDANCE
Design areal reduction factors have been added FIGURE 8 including the 1-to-24-hour
ranges reported by the WMO and by NWS/NOAA in the US mid-west (Huff and Angel,
1992). The WMO values are one source of
factors for return period storms recommend by OMNR (2002). While OMNR prescribes factors for historical
storms (Hurricane Hazel and Timmins Storm) based on observed characteristics,
on thunderstorms in small areas in notes data limitations:
“When analyzing
thunderstorm type rainfall in urban areas, storm distribution becomes an
important factor. Variation in rainfall intensity over small areas, such as 5
km2, can be significant. Unfortunately, due to lack of rainfall
data, no guidelines are available on storm distribution within small urban
areas.”
The WMO factors have been applied in the GTA such as the Don River
Hydrology Update (AECOM, 2018) applying the 1-hour reduction factor to the 12-hour
design storm. The August event factor
observed around the Toronto RG-046 gauge, and July event Mimico Creek factor
would appear to exceed the Don Watershed study design values. The Mimico Creek July factor aligns with the
WMO 24-hour factor, suggesting that high conservative factors can be realized
in real storms. As the Huff and Angel
factors are based on over 600 observed storms and can exceed the long duration
WMO factors cited by OMNR, practitioners should consider the possibility of
large area extreme storms. The 2024 storm observations confirm that high
rainfall volumes may be sustained over very small study areas (e.g., local
wastewater collection sewersheds or small storm drainage areas). For example, the Carolyn Creek July storm
factor is 0.95 over an equivalent circular area of 13 sq.km[30].
Larger wastewater collection areas, e.g., that may be 250 sq.km in size[31],
may have limited reduction factors over long durations based on the upper bound
of the WMO and Huff-Angel 24-hour curves.
OBSERVED
FLOW RATE RETURN PERIOD COMPARED TO AVERAGE AND PEAK RAINFALL RETURN PERIOD
Peak flows in Markham’s wastewater system were
compared to design storm outputs from the City’s calibrated InfoWorks model. Four
monitoring sites[32]
are near rain gauge MA-016 (June 19, 2024 event), and two sites[33]
are near gauges MA-01 and MA-07 (August 17, 2024 event). These older Unionville
and West Thornhill communities exhibited both high total volumes and periods of
high intensity.
The return period of wastewater flow peaks at the four sites on June 19,
2024 was typically in the 5 to 10-year range, with one site recording less than
a 2-year peak flow. Even though the 2
and 24-hour intensities at MA-016 exceeded 100-year return periods, shorter
durations (2 and 25-year return periods) actually governed the peak flows. So,
while the storm event exhibited some 100-year characteristics, the critical
characteristics that govern wastewater system response and performance risk
were not nearly as unlikely.
Similarly, the return period of flows for the August 17, 2024 event were
in the 2 to 10-year range. While the
MA-01 2 hour and MA-07 6-hour intensities both exceeded 100-year values, the
shorter duration intensities (2 and 25-year return periods) were less severe
and aligned with observed peak flows.
This discrepancy shows that long-duration metrics (i.e., total event
volumes) do not always correlate with wastewater system flow peaks. In many
cases, short-duration intensities are a more accurate indicator of potential
infrastructure stress. Yet, storm mapping and news reports often highlight
total volumes instead.
CONCLUSIONS
Claims of changes in extreme storm severity
and frequency are often inconsistent with observed and reported trends
documented in ECCC’s Engineering Climate Datasets. For instance, v3.3 IDF files
for southern Ontario do not show any overall increase in extreme rainfall
intensities compared to pre-1990 values.
Even when considering data up to the 2024 extreme events, the Pearson Airport’s
24-hour, 100-year rainfall volume is only 0.6% higher than in 1990, and Toronto
City’s 2.6% increase still remains 0.1% below the long-term value, including an
additional 100 years of data from 1840 to 1940.
The probability of recording multiple extreme storms over multiple years
in the GTA has increased with the growing number of municipal rainfall
gauges. With 220 gauges, observing six
100-year events in 12 years becomes statistically probably (over 99%) if only
one gauge in the network is affected by a small-sized storm cell. However,
observing four moderate-sized storms over that same period has a lower
probability (around 22.1%) considering 11 affected gauges in each independent
cluster. This is consistent with ECCC’s
reporting following the extreme May 16, 1974 storm, that a 4.2 inch or greater
rainfall could be observed every two years in southern Ontario. The areal extent of storms should therefore
be considered an additional factor to assess the probability of events
affecting large systems, which may be combined with the isolated peak volumes
often used to characterize events and could be reflected in locally-derived
areal-reduction factors for convective storms in urban areas. An assessment of
2024 extreme rainfall patterns suggests that areal reduction factors applied in
practice can sometimes underestimate both these observed and literature
reference values.
In
several Markham catchments, wastewater system peak flows showed lower design
return periods than event’s volume return periods (i.e., long-duration
intensities). These peaks aligned more
closely with short-duration intensities, rather than 24-hour volumes. This
suggests that the severity of storms should be more critically addressed for
different systems considering more than the event volume (e.g., governing short
duration intensities).
Extreme
storms in the GTA in 2024 included both convective events, featuring high
spatial and temporal variability, and remnants of tropical storms (hurricanes)
with less variability. These events have
independent causes yet are combined in single annual series and IDF frequency
analyses implying identical distributions, which is unlikely. Modified IDF analysis excluding
hurricane-type events from annual series should be evaluated. This could assess how high daily
hurricane-derived rainfall volumes affecting short duration design intensities
when daily IDF volumes are used derive short duration intensities in
traditional design hyetographs.
As
desirable as simplifications are, design storms inherently simplify complex
hydrologic processes, especially when dealing with varying antecedent moisture
conditions or mixed storm populations. The lack of dedicated “urban hydrometric
networks” historically justified relying on design storms that can be somewhat
arbitrary (Marsalek and Watt). However, some jurisdictions, such as the City of
Ottawa, have begun using frequency analyses of wastewater system RDII flows,
reducing the need for design storms assumptions. This approach deserves
continued consideration to overcome what could be an intractable challenge of
defining the 100-year design storm.
Bryan Karney, Ph.D, P.Eng., University of Toronto*
Christopher Zuccaro, B.A.S.c University of Toronto
Robert J. Muir, M.A.Sc., P.Eng., City of Markham
Zahra Parhizgari, M.Sc., PMP, P.Eng., City of Markham
Jack Zi, P.Eng., City of Markham
(originally presented at WEAO 2025 Technical Conference, London, Ontario, April, 2025, *corresponding author)
PRESENTATION
BIBLIOGRAPHY
Adams,
B.J., Howard, C.D.D., (1986) Design Storm Pathology, Canadian Water Resources
Journal, https://doi.org/10.4296/cwrj1103049
AECOM,
(2018), Don River Hydrology Update, Toronto and Region Conservation Authority.
City of
Ottawa (2008), Sanitary Sewer Extraneous Flow Analysis https://docs.google.com/document/d/0B9bXiDM6h5VianROT1EtV2c5UFU/edit?usp=sharing&ouid=115169455109461543967&resourcekey=0-sIt--IZF8kevusIkk76iMg&rtpof=true&sd=true
Dickinson,
T. (1976), Season variability of rainfall extremes, Atmosphere, Volume 14,
Number 4, https://doi.org/10.1080/00046973.1976.9648424
Huff,
F.A., Angel, J.R. (1992) Rainfall Frequency Atlas of the Midwest, Bulletin 71,
Midwestern Climate Centre (CAA, NWS, NOAA), Illinous State Water Survey. https://drive.google.com/file/d/1-jY16dLUu1Pi_9SDWd_kp8Sof3HMehSs/view?usp=sharing
Marsalek,
J, W.E. Watt (1983), Environment Canada, National Water Research Institute,
Design Storms for Urban Drainage Design. https://drive.google.com/file/d/1N4xc7qJAJv0ZhY24KDVOcSrLV0NbMn72/view?usp=sharing
Muir,
R., (2018) Evidence Based Policy Gaps in Water Resources: Thinking Fast and
Slow on Floods and Flow, Journal of Water Management Modeling, https://www.chijournal.org/C449
Ontario
Ministry of Natural Resources, (2002), Technical Guide River & Stream
Systems: Flooding Hazard Limit
Pollock,
D.M, (1976), Environment Canada, Atmospheric Environment, The Rainstorm of May
16, 1974, In Southern Ontario. https://drive.google.com/file/d/1MRXf36wCUtA6ynzMl-3UMot4tNzVDM5T/view?usp=sharing
National Research Council of
Canada (NRC) (2021) Guidelines on Undertaking a Comprehensive Analysis of
Benefits, Costs and Uncertainties of Storm Drainage Infrastructure and Flood
Control Infrastructure in a Changing Climate.
FOOTNOTES
Toronto Open Data / Historic
Rain Gauge Locations and Precipitation
https://open.toronto.ca/dataset/historic-rain-gauge-locations-and-precipitation/
Toronto Open Data / Rain Gauge
Locations and Precipitation
https://open.toronto.ca/dataset/rain-gauge-locations-and-precipitation/
York Regional and Municipal
Inflow & Infiltration Assessment Reduction Assessment, Region of York, Rain
Gauges Installation Report (AECOM, 2008)
R. Muir, City of Markham,
personal communication December, 2024
M. Faye, Region of Peel,
personal communication October, 2024
Note that Toronto rainfall
data reflects reported 3-hour total. Additional gauges may observe over 86.3 mm
for longer durations.
Insurance Bureau of Canada,
Telling the Weather Story (2012),
https://www.iclr.org/wp-content/uploads/PDFS/telling-the-weather-story.pdf
August 17, 2024 per
rainfallhttps://www.theweathernetwork.com/en/news/weather/severe/when-it-rains-it-pours-toronto-records-its-wettest-summer-on-record-ontario.
Toronto City 2018-2021 rainfall added to series plus 2022 and 2023 trendline
estimates.
Welland, Belleville and daily
maximum rainfall has increased by 2.7 mm, 2.2 mm and 6.9 mm per century based
on data back to 1873, 1866 and 1870, respectively. Peterborough daily maximum
has decreased by 5.9 mm per century based on data back to 1866.
Incomplete/partial year data
in the 1-30 Day dataset was replaced with short-duration IDF data for the
previous 100-year statistical analysis.
York Region RDII antecedent
rainfall chart indicates approximate linear increase in RDII volume with
antecedent rainfall totals grouped for total below 12.5 mm, 12.5-38.1mm and
above 38.1 mm with a strong correlation between RDII volume storm volume for
these groups of antecedent rainfall (i.e., reported R-squared values of 0.904,
0.8866 and 0.9622 respectively).
Note – highest rainfall was
135 mm at Toronto RG-052, however RG-046 is situated more centrally within a
higher rainfall area.
Actual watershed area is 5.3
sq.km. Maximum rainfall in watershed was 102 mm while mean watershed rainfall
was 97 mm.
City of Toronto Ashbridge’s
Bay Wastewater Treatment Plant approximate sewershed size is 25,000 ha (2021
Annual Report, www.toronto.ca)
Monitor ID’s MA006a, MA006b_10,
MA006c_2 and MA083_10
Monitor ID’s MA044_10 and
MA046_10
