DATE FILED: December 29, 2017 3:51 PM
FILING ID: 98AB7865D8F01
CASE NUMBER: 2016CW3128

Aspen’s Water Future: Estimating the
Number and Severity of Possible Future
Water Shortages

Prepared by:

November 30, 2017
1

 Contents
Impact of Uncertainty on the Number and Severity of Future Water Shortages......................................... 3
Purpose ..................................................................................................................................................... 3
Definition of a Water Shortage ................................................................................................................. 4
Analytical Model ....................................................................................................................................... 4
Historical Streamflow............................................................................................................................ 4
Hydrograph Modification Utility ........................................................................................................... 5
Operations Tool .................................................................................................................................... 5
Model Output ....................................................................................................................................... 6
Uncertainties Affecting Supply and Demand ............................................................................................ 6
Period of Record ................................................................................................................................... 6
Flow Adjustment Factors ...................................................................................................................... 8
Climate Change ..................................................................................................................................... 9
Demand ................................................................................................................................................... 13
Previous Water Demand Estimates and Water Production ............................................................... 13
Evapotranspiration Impacts ................................................................................................................ 16
Results of the Uncertainty Analysis ........................................................................................................ 17
Current Supply and Demand Conditions ............................................................................................ 17
Year 2065 Conditions With No Uncertainty........................................................................................ 18
Year 2065 Conditions With Uncertainty ............................................................................................. 21
Sensitivity of the Results to Risk Assumptions.................................................................................... 25
Appendix A: Monte Carlo Simulation as a Tool for Assessing Supply and Demand Uncertainties............ 26
What is Monte Carlo Simulation? ........................................................................................................... 26
The Benefit of Monte Carlo Simulation .................................................................................................. 26
Monte Carlo Simulation and Climate Change ......................................................................................... 27
Implementing Monte Carlo Simulation .................................................................................................. 27
Appendix B: Model Screenshots ................................................................................................................ 31
Appendix C: Service Area Map of the Aspen Water System ...................................................................... 38

2

 Impact of Uncertainty on the Number and Severity of Future Water
Shortages
Purpose

The City of Aspen water system is supplied in a “run-of-the-river” manner utilizing Castle and Maroon
Creeks to meet municipal demands. This run-of-the-river characteristic means that as long as there is
water in the creeks, Aspen has access to water. There is minimal water storage in the system, so if
anything interrupts these supplies, whether it be long-term drought events induced by climate change,
or short-term events such as floods or wildfires damaging critical infrastructure, the City’s water supply
is at risk.
In light of these increasing risks and growing demands, the City is assessing the adequacy and resiliency
of their current water supplies and water infrastructure. An initial step in this assessment involves
estimating the potential frequency and severity of water shortages to the Aspen water system over a
range of possible future hydrological and demand conditions. This is based on a concern that existing
water supply risks will significantly increase over time due to climate change’s impact on the timing and
volume of flows in Castle and Maroon Creeks.
This analysis estimates the frequency and severity of water shortages to the Aspen system assuming
water supply and demand conditions anticipated for the year 2065. It assesses upon Castle Creek’s and
Maroon Creek’s abilities to fully serve the City’s demands. At this point in time, it does not consider
mitigating measures to prevent or minimize shortages, such as conservation beyond measures currently
in effect, supplemental groundwater, or storage. The analysis focuses upon climate change’s potential
impact on the timing and volume of creek flows, and its potential impact on evapotranspiration (ET)
both upstream of the City’s water diversion points and on municipal irrigation water demands. In
addition to the uncertainties of climate change, this analysis directly addresses other important
uncertainties related to the volume of flow and to water demand.
The analysis uses Monte Carlo simulation to examine the combined effects of these numerous
uncertainties on the overall uncertainty behind the number and severity of potential water shortages. 1
A characteristic of this method is that there is no single “correct” number of shortages or severity of
shortage, the results are expressed in terms of probabilities, equivalently shown as frequency diagrams
(histograms), percentiles, or cumulative probability functions. These metrics are more valuable than
simple averages because they better describe the uncertainties and allow decision makers to decide
how much risk they are willing to take.
The following sections:
•
•

1

Describe what is meant by a water shortage for Aspen
Present and discuss an analytical spreadsheet-based model for estimating the number and
severity of shortages

Monte Carlo simulation is discussed in Appendix A.

3

 •
•

Identify the uncertain variables most significantly impacting long-term supply and demand, and
presents assumptions about their possible values
Present the results of the Monte Carlo simulation

Definition of a Water Shortage

A shortage occurs when combined flow at the City’s diversion points is insufficient to simultaneously
meet City demand, deliveries to three irrigation ditches below the City’s Castle Creek diversion, and
provide for instream flows. Since the City’s water rights are senior to the instream flow right, the City
and irrigation ditches can deplete the creeks before experiencing their own shortage. 2 Alternatively
stated, this analysis assumes that instream flows are already gone when the City experiences a shortage.

Analytical Model

An analytical spreadsheet model of the City of Aspen’s raw water supply system was developed to
identify possible shortages to municipal and industrial (M&I) or other demands. The model consists of
two components:
1. Hydrograph modification tools for Castle Creek and Maroon Creek,
2. An operations tool that uses the streamflows output by the hydrograph tools to meet Aspen’s
potable and non-potable water demands and identify any shortages.
Based on the availability of historical streamflow data, the period of record for the model is Water Years
(WY) 1970-1994 (October 1, 1969-September 30, 1994). The model simulations run on a weekly 3 time
step.

Historical Streamflow
Daily historical gaged streamflows for Castle Creek 4 and Maroon Creek 5 above Aspen were the
underlying input to the hydrograph tools. The USGS streamflow gages were located several miles
upstream of the city’s raw water diversion structures, and therefore the historical data were not directly
reflective of the water supply available to the city. Field measurements were used by Enartech (1994) to
estimate multipliers which can be used to transform the gage measurements to flows at the municipal
intakes. 6 Values for the multipliers are input by the model user; the assumed values were 2.43 for
Castle Creek and 1.27 for Maroon Creek, although other values can be entered within a specified range.
These adjustments are used to account for intervening ungaged tributary inflows, return flows, and
other reach gains and losses. The estimated daily streamflows at the municipal intakes were used to

2

It should be noted that the above definition may not reflect City policies that may be in effect when shortages
occur, such as possible decisions on how to allocate limited supplies between instream flows and City-controlled
irrigation demands on Castle Creek.
3
Daily and monthly models were also developed, but based on discussions with the City of Aspen, the project
team agreed on a weekly time step to achieve a reasonable balance between computation time and data density.
4
USGS 09074800 Castle Creek above Aspen, CO
5
USGS 09075700 Maroon Creek above Aspen, CO
6
Enartech Inc. 1994. City of Aspen Evaluation of Raw Water Availability. October.

4

 calculate a time series of weekly average streamflow during each year for the period of record. This
time series was then condensed into a single hydrograph of average weekly flow.

Hydrograph Modification Utility
The model does not incorporate specific climate change scenarios, but instead allows the user to input
and test modifications to the timing of the hydrograph peak and to the magnitude of the flows
represented by the hydrograph. For the present analysis, it was assumed that under future conditions
the peak flow week would occur earlier (a shift of 2 to 6 weeks depending on the model run) and that
flows over the entire hydrograph could range from +10% to -50%. These modifications to peak timing
and magnitude of flows were applied to adjust the hydrographs of average weekly flow. The same
modification factors were used for both Castle Creek and Maroon Creek. The patterns of historical
gaged streamflow on each creek were then used to distribute the modified average hydrographs to a
pair of modified 25-year weekly streamflow time series for use in the operations tool.

Operations Tool
The operations tool starts with the modified weekly streamflows at the municipal intakes on Castle
Creek and Maroon Creek as the water supply available to the City of Aspen, then applies a succession of
potable and non-potable demands to identify potential shortages. Non-potable demands are
considered first, including the city’s downstream irrigation demands on Castle Creek and the Herrick
Ditch upstream of the City’s Maroon Creek diversion. 7 8
Remaining flows on the two creeks are then combined and used meet the City’s water demands, which
are those that draw on Thomas Reservoir and are then met through the city’s distribution system; these
include variable indoor, outdoor, and non-potable water uses. Modeled municipal water shortages, if
they exist, are identified and quantified. Any water that is left is applied to meet instream flow (ISF)
demands. The ISFs are junior water rights held by the Colorado Water Conservation Board for 12.0 cfs
on Castle Creek 9 and 14.0 cfs on Maroon Creek 10. Aspen is committed to an additional 1.3 cfs on Castle
Creek, so a combined ISF flow rate of 27.3 cfs is used in the operations tool. Modeled ISF shortages are
identified and quantified.
Although the ISFs are decreed separately for the two creeks, the available supply, ISF demands, and
potential shortages are evaluated as aggregate quantities in the model because the timing and amount
of any shortage would be influenced by the city’s operational decisions regarding diversions from each
creek into Thomas Reservoir.
The headgate for the Herrick Ditch is located upstream of the city’s Maroon Creek diversion structure, but as a
gaged diversion, it is handled separately and is not a component of the factor used to transform flow from the
USGS gage location to the municipal intake.

7

8

Herrick Ditch diversions were assumed to be 16 cfs through the irrigation season ending in the second week of
October, representing the most water Herrick Ditch used on a daily (or weekly) basis across an entire irrigation
season in recent history. This occurred in 2003 and 2016. The portion of the Herrick water right senior to Aspen’s
is 9.3 cfs. However, for purposes of this planning study, 16 cfs was assumed based on precedent. Reducing
Herrick’s diversion to 9.3 cfs in the analysis would likely reduce the number of late season shortages.
9

Case No. W-2947, with appropriation date January 14, 1976
Case No. W-2945, with appropriation date January 14, 1976

10

5

 Model Output
Output from the model includes the frequency and magnitudes of M&I or ISF shortages. This
information is used to generate figures illustrating the likelihood of a given shortage magnitude as well
as plots that depict the timing and magnitude of ISF shortages on a grid representing the period of
record.
Appendix B shows screen shots of the model’s input and output tables, highlighting critical assumptions.
Figure 1 illustrates the operational component of the model through a schematic diagram.

Uncertainties Affecting Supply and Demand
The analysis considers four areas of uncertainty:
1.
2.
3.
4.

Annual flow; Period of Record
Flow adjustment factors
Climate Change
Demand

Period of Record
The hydrologic period of record defines the uncertainty surrounding the volume and timing of flow from
year to year. This study uses the period 1970 through 1994, corresponding to the years that gages were
continuously active on each of the creeks. Since Aspen is run-of-the-river system with minimal storage,
Figure 2 shows the estimated average monthly flows at the City’s diversion points for the two creeks
during this period and their combined flows.
This hydrologic period contains 1977, which is the driest year on record, and 1983 and 1984,
representing very wet years in the Colorado River basin. It should be noted that dry years did not occur
in succession during the 1970-94 period, like during the 1950’s. 11 Nor does the data contain the years
since 2000, when Colorado has experienced statistically significant higher average temperatures
compared to 1970 through 1994. Also, since the period 1970 through 1994 mostly pre-dates the
establishment of statistical trends showing warming in Colorado, any climate change-based impacts
occurring between 1994 and the present are likely not reflected in the data.
Extending the hydrological record to include the entire 1950 through present period would be desirable
to better quantify the variability of flows, the frequency of critical years, and the possibility of successive
critical years. However, for now, this analysis uses the 1970 through 1994 period with the above
caveats.

11
Precipitation data and snowfall data from the Aspen Station indicate that all years but one between 1952 and
1958 had less total precipitation than 1977. The year 1953 had substantially less snowfall than the 1977 water
year, but the remaining years had more snowfall than 1977.

6

 Figure 1. Schematic of the Castle Creek and Maroon Creek Operational Model

 

BYPASS
DEMAND:

Irrigation

 

I

 

 

    
  
       

 

 

Castle Creek
USG Gage,


Maroon Creek
USGS Gage,
1970?1994

 

 

 

 

 

 

l' I 
Impacts Climate 
I Chan I
I I
I I




I 

Adjustment for Intervenlng Flow Changes

I
saBueLD MOH Euguamalw .10} we 



I


 

 

 
 

COM BIN ED
FLOW at
Thomas

 
  
 

Flow 
Maroon
Creek Intake

Flow 
Castle Creek

Intake

  
 
 

 

  

Reservoir

 

 

 

 

DEMANDS:

Indoor Use,
7?4? Outdoor Use, 
a
5 Non-Potable 
(LI 3

U1 
EU TD


 

    
     
   
   

Combined
Flow after
Meeting 
Demands

Qu antify Shortage

  

 

 

DEMAND:
Castle Creek

DEMAND:
aro on
Creek ISF

 

 

Combined
Flow after ISF
Demands

Quantity I SF Shortage

   

 

 
 
   
    
 

  
  

 

DEMAND:
Herrick Ditch

 

 

Figure 2. Estimated monthly flows at Aspen’s Castle Creek and Maroon Creek diversions.

Flows in cfs
1,200
1,000

cfs

800
600
400
200

Castle Creek

Maroon Creek

Jun-94

Oct-93

Jun-92

Feb-93

Oct-91

Jun-90

Feb-91

Oct-89

Jun-88

Feb-89

Oct-87

Jun-86

Feb-87

Oct-85

Jun-84

Feb-85

Oct-83

Jun-82

Feb-83

Oct-81

Jun-80

Feb-81

Oct-79

Jun-78

Feb-79

Oct-77

Jun-76

Feb-77

Oct-75

Jun-74

Feb-75

Oct-73

Jun-72

Feb-73

Oct-71

Jun-70

Feb-71

Oct-69

0

Castle Creek + Maroon Creek

Flow Adjustment Factors
Stream gages used to measure flows over the period of record were located high in the Castle and
Maroon Creek systems, above the City’s diversion points and with intervening, ungaged tributaries. As a
result, adjustments had to be made to the gaged flows to approximate flows at the City’s diversions. For
purposes of this analysis, the factors were estimated for each creek incorporating a least squares
regression analysis that uses gaged flow as the independent variable and flow at the City diversion point
as the dependent variable.
For Castle Creek, an R-square of regression of 0.993 supports a flow adjustment factor of 2.43 for Castle
Creek and an R-square of 0.996 supports a flow adjustment factor of 1.27 for Maroon Creek. Although
the fit of the regression equation defining the factor is very good, the estimates are limited by a
relatively small number of observations primarily taken in 1994. However, subsequent paired
observations appeared to confirm these relationships. Also, despite, the good fit, there is still significant
uncertainty around the factors, as measured by the standard error of the regressions. Figures 3 and 4
illustrate the uncertainty around the estimates of the flow adjustment factors for Castle Creek and
Maroon Creek, respectively. In both cases, the uncertainty is assumed to be normally distributed, or
bell-shaped, centering around their expected values.

8

 Figure 3. Assumed uncertainty around the Castle Creek flow adjustment factor

Figure 4. Assumed uncertainty around the Maroon Creek flow adjustment factor

Climate Change
An important component of this effort is to assess the possible impacts of climate change. A previous
analysis by Wilson Water Group examined 5 climate change scenarios with varying levels of impact to
flow patterns, ranging from about +9% to -19%, concluding that climate change would adversely affect
9

 Aspen’s water supply, but not to a level requiring additional infrastructure, such as a storage reservoir. 12
Since the development of these 5 climate change scenarios, there have been questions as to whether a
wider range of impacts should now be considered, especially those based on the greater resolution
provided by more recent research. It should be noted that much of this recent research has not yet
been downscaled to a level readily applicable to Castle or Maroon Creeks, or the Roaring Fork Valley.
Although various efforts are underway at the State and major water provider level to adapt this data at
a basin level, it is not currently available. 13
To best incorporate current climate change knowledge, this effort is working with the City’s climate
change staff and their associates to incorporate recent data and plausible ranges of data into the current
modeling framework. The potential impacts of climate change will remain highly uncertain, but the
effort described below is an attempt to bracket the possible range of impacts for purposes of assessing
the number and severity of possible future water shortages.
More recent climate change research indicates that impacts to flows in the Colorado River and its
tributaries may be much more severe than previously thought. Recent research suggests the following:
“Recently published estimates of Colorado River flow sensitivity to temperature combined with a large
number of recent climate model-based temperature projections indicate that continued business-asusual warming will drive temperature-induced declines in river flow, conservatively −20% by midcentury
and −35% by end-century, with support for losses exceeding −30% at midcentury and −55% at endcentury. Precipitation increases may moderate these declines somewhat, but to date no such increases
are evident and there is no model agreement on future precipitation changes. These results, combined
with the increasing likelihood of prolonged drought in the river basin, suggest that future climate change
impacts on the Colorado River flows will be much more serious than currently assumed, especially if
substantial reductions in greenhouse gas emissions do not occur”. 14
Climate change and its uncertain impacts will ultimately affect Castle and Maroon Creeks through the
timing and quantity of their future flows. Snowmelt run-off will likely occur earlier in the year over time
and the total volume of flow may or may not decline over time. These impacts will be reflected in their
hydrographs that show flows over the course of a representative year, at a specific point in the basin.
It should be noted that the existing hydrographs account for existing water use, or evapotranspiration
(ET), based on current upstream land uses. With warming associated with climate change, upstream ET
will likely increase and further impact the resulting hydrograph, regardless of the precipitation impacts.
This increase in ET may also affect Aspen’s customers through an increase in outdoor water demand.
To assess overall possible impacts of climate change to the hydrographs, a utility was embedded in the
modeling framework which allows the user to specify changes to the hydrographs’ timing and shape. By
12

Wilson Water Group. 2016. City of Aspen Water Supply Availability Study 2016 Update. June. It should be noted
that the Wilson analysis assumed an operating supplemental groundwater system.
13

http://onlinelibrary.wiley.com/doi/10.1002/joc.4594/full

14

Udall, et al. http://onlinelibrary.wiley.com/doi/10.1002/2016WR019638/abstract, l

10

 specifying variables related to the timing of peak flows and the impact to total flow volume, a wide
range of possible impacts are considered.
For purposes of incorporating this utility into the analysis, assumptions were made about the
uncertainty of the timing and volume of flows. For timing, it was assumed that peak flows could occur
anywhere from 2 to 6 weeks earlier by 2065, with equal probability, relative to the 1970 through 1996
data (Figure 5).
Figure 5. The timing of peak run-off relative to 1970 through 1994, number of weeks earlier and the
assumed probability for each week.

The combined impact to flows in Castle and Maroon Creeks, and associated upstream ET, are assumed
to range from +10% to -55% from the 1970-96 baseline levels. It was further assumed that the probable
value is likely skewed towards the low side of this range, as shown in Figure 6. This results in a mode, or
most likely value, near -35%. The assumption about skew is based on recent literature, such as that
cited above, stating that impacts may be worse than previously thought.

11

 Figure 6. Assumptions regarding the probability of flow and ET impacts to Castle and Maroon Creek
flows resulting from climate change, relative to 1970 through 1994.

Figure 7 illustrates the baseline hydrograph for Castle Creek and a modified hydrograph based on a
single set of alternative assumptions about long-term timing and flow impacts associated with climate
change. For this figure, it was assumed that peak runoff occurs 4 weeks earlier and flow is uniformly
reduced by 35%, both relative to the period 1970 through 1994. Monte Carlo simulation will examine
the probability-weighted range of possible timing and flow impacts, as represented by Figures 5 and 6.
Figure 7. Example of Existing and Alternative Modified Hydrograph

12

 Demand

During the course of this analysis, it became apparent that a land use-based estimate of future water
demand would be more useful than simple extrapolations of historical data. This is due to Aspen’s
relatively high degree of land use control and limited remaining lands to develop. There is wide
agreement that a land use approach is desirable and the City is currently taking steps to develop longterm land use maps that incorporate a water demand component. However, at this point in time, there
is not a future land use map to base demand estimates upon or plans that can be readily translated to a
map. As a result, this analysis uses existing data and previous analyses to develop a probable range of
future demand.
It should also be noted that the City of Aspen’s water system consists of the City itself, plus territory
outside the City limits to the east and to the west, primarily along the Highway 82 corridor. In
perspective, in 2010, the City was estimated to have permanent population of about 6,700, but the
water service area had a permanent population of about 10,000.
The City has land use controls over a major portion of the water service area but not the entirety. Pitkin
County policies will also impact future demand growth. Overall, the City’s water service area population
is estimated to grow to about 12,000 in 2025 and 13,500 in 2035, based on a 1.2% rate of planned
population growth. It is likely that much of this growth, if it occurs, will target areas outside the City’s
current boundaries with future land use requirements between the City and Pitkin County influencing
future demands on the City’s water system.

Previous Water Demand Estimates and Water Production
The water demand portions of three previous studies have been evaluated with respect to their
applicability to this analysis, as summarized in Table 1.
As indicated above, full-time, or permanent, population within the City of Aspen was approximately
6,700 in 2010. It was estimated that Aspen Water served a permanent population of slightly over
10,000 within the Urban Growth Boundary (UGB) when extra-territorial service is included. 15 An issue
frequently brought-up while discussing the previous demand studies was the use of a compound
population growth rate over a long period of time. For instance, a 1.2% population growth rate over 50
years applied to the City of Aspen would result in a 2065 population in the 12,000 to 13,000 range and a
total service area population nearing 20,000, nearly doubling of current levels. These levels of
population may be untenable to many Aspen area residents for quality of life reasons. Based on this,
there is a probability that measures will be taken through the City’s and County’s land use processes to
limit new single and multi-family housing development. The ultimate limit to these land uses is
unknown, as is whether these limits might similarly apply to non-residential land uses, and how these
limits might be allocated between the City and County.

15

Element Water Consulting and Water DM. 2015. Aspen Municipal Water Efficiency Plan.

13

 Table 1. Summary of Previous Demand Studies
Previous study
Enartech, 1994

Summary
Examined a range of land
use build-out scenarios;
based on the most
expansive, estimated
total system buildout
would be 19,800
Equivalent Capacity Units
(ECU’s). There are
currently about 17,300
ECU’s in the system. This
implies that the service
area can only growth
another 15% to reach
buildout.

Wilson Report, 2016

Estimated that demand at
the water treatment plant
would grow from its 2012
level at a baseline rate of
1.2% per year based on
population growth trends.
Alternative scenarios of
slightly less than 1.2% and
1.8% were also examined.

Water Efficiency Plan, 2015

Used same baseline
demand growth rate as
Wilson Report, 1.2%;
examined passive and
active conservation
measures that reduce
indoor and outdoor usage
for certain customer
classes. Period of analysis
was 2016-2035.

Aspen and regional land
use plans

This includes the Aspen
Area Community Plan and
Pitkin County’s West of
Castle Creek and West of
Maroon Creek Master
Plans

14

Estimated Demand
Build-out demand is
estimated to be about
4,300 acre-feet per year,
as estimated by
Headwaters, based on a
15% increase from its
current level; current
annual demand at the
water treatment plant is
about 3,725 acre-feet; a
proportional increase in
the number of permanent
residents would imply a
buildout population of
about 7,820 in the City and
about 11,500 in the City
and County combined.
2065 demand is estimated
to be in the range of 6,300
acre-feet per year, as
estimated by Headwaters;
implied population for the
City is over 12,100, a 77%
increase over current
levels; implied population
for Aspen service area
would be approximately
20,000.
Essentially same baseline
demand through 2035 as
Wilson Report, with minor
reductions due to passive
water conservation. With
active conservation and
focus on outdoor
irrigation, demand is
reduced significantly,
estimated to grow at a
rate of 0.50% between
2015 and 2035.
These documents discuss
future development trends
that would ultimately
affect water demand
within, or adjacent to,
Aspen Water’s service
area.

Applicability
Data point in identifying the
possible range of demand
growth. It implies that
demand would only grow a
total of 15% above its
current level. This growth
could occur anytime over the
2017-2065 period, but
implies a compound growth
rate of 0.3%.

Data point in the range. The
implied population of 20,000
in the Urban Growth
Boundary in 2065 may be
untenable to those
supporting growth
management.

Since the study has a 20-year
time horizon, whether the
reduced growth in demand
attributable to active
conservation can be
maintained past 2035 is not
addressed.

Currently, there are no
future land use maps to
directly link future land uses
to demand, although they
will likely evolve in the near
future.

 By examining water demand on a customer class basis, such as single family residential, multi-family
residential, commercial, and other types of usage, different rates of growth could be applied to different
customer classes. In response to the above population concerns, the number of customers and
associated demand for residential customer classes was assumed to grow at slower rate than for nonresidential customer classes.
For this analysis, it was assumed that the rates of growth in residential water usage and non-residential
water usage are random variables with a range of possible outcomes.
•

•

Residential water usage is assumed to increase between 0.3% and 0.5%, corresponding to a
2065 Aspen permanent population ranging from about 7,800 to 8,800, or a service area
population ranging from 11,600 to about 13,000. The distribution is assumed to be triangular,
centering around 0.4%, as shown in Figure 8.
Non-residential water usage is assumed to increase over time at an annual rate of 1.2%, similar
to the rate assumed in previous demand studies, but may vary between 0.8% to 2.0% to reflect
uncertainties regarding future growth policies. This distribution is assumed to be slightly
skewed to the low side of the range, indicating that it is more likely that non-residential growth
will be below 1.2% than above this rate (Figure 9).

Figure 8. Assumed growth rate for residential water service

15

 Figure 9. Assumed growth rate for non-residential water service

The above assumptions would result in a greater proportion of Aspen’s water being used for nonresidential purposes. However, at this point, whether these non-residential uses are for commercial
enterprises, industries, or extra-territorial service is not specified.

Evapotranspiration Impacts
Although the climate-change induced impacts to flow discussed above are intended to include the
impacts of increased upstream ET, there will likely be additional ET-related impacts to Aspen’s future
outdoor water usage and increased irrigation consumptive use along the three irrigation ditches on
Castle Creek. The increase in ET would likely translate to an increase in municipal treated outdoor water
demand but irrigation diversions are assumed to remain at their current levels.
Research is still being conducted to estimate the possible ET impacts. However, to provide a
placeholder until this research is complete, it is assumed that potential ET impacts may vary from 10% to
30%, with municipal treated outdoor irrigation increasing in the same proportion. It is assumed that
the ET impacts are distributed in a triangular manner, centered at 20%, as shown in Figure 10. It is
further assumed that ET impacts as applied to outdoor irrigation are correlated to climate change
impacts. For instance, if streamflow impacts of climate change are highly adverse, ET impacts are also
highly adverse.

16

 Figure 10. Potential ET impacts to outdoor water usage.

Results of the Uncertainty Analysis

As previously stated, there is not a single result or set of results associated with this analysis. Results are
expressed in probabilities. However, for presentation purposes, the adequacy of the Aspen water
system to satisfy demands is discussed under three conditions:
1. Current supply and demand conditions
2. Assumed year 2065 conditions assuming the period of record and expected values for uncertain
variables. Alternatively stated, no uncertainty is considered
3. Year 2065 conditions assuming the period of record and uncertainty with respect to flow
uncertainty, utilizing Monte Carlo simulation

Current Supply and Demand Conditions
Under current water supply and demand conditions, and no climate change, there are no estimated
shortages to the Aspen water system and very minor impacts to the instream flows (Figure 11). The
impacts to instream flows primarily occur during simulated 1977 drought conditions.

17

 Figure 11. Shortages associated with current supply and demand conditions.

Annual Shortages
160
140

Acre-feet

120
100
80
60
40
20

1994

1993

1992

1991

1990

1989

1988

1987

1986

1985

1984

1983

1982

1981

1980

1979

1978

1977

1976

1975

1974

1973

1972

1971

1970

-

Hydrologic year
Annual shortage to Aspen

Annual instream flow shortage

Year 2065 Conditions With No Uncertainty
Other than the uncertainty associated with the hydrological period of record, Figure 12 shows possible
shortages assuming year 2065 supply and demand conditions. This assumes that uncertain variables
identified in previous sections, specifically flow adjustment factors, climate change, and demand
variables are set at their expected values with no uncertainty.
•
•
•

Flow adjustment factors are fixed at 2.43 and 1.27 for Castle and Maroon Creeks, respectively.
Climate change is expected to move peak flows back by 4 weeks and reduce flows by 35% when
ET impacts are considered, both compared to 1970-94 conditions
Residential water demand is expected to increase at an annual rate of 0.4% and non-residential
water demand is expected to increase at an annual rate of 1.2%.

18

 Figure 12. Estimated shortages for year 2065, no uncertainties considered.

Annual Shortages
9,000
8,000
7,000

Acre-feet

6,000
5,000
4,000
3,000
2,000
1,000

1994

1993

1992

1991

1990

1989

1988

1987

1986

1985

1984

1983

1982

1981

1980

1979

1978

1977

1976

1975

1974

1973

1972

1971

1970

-

Hydrologic year
Annual shortage to Aspen

Annual instream flow shortage

Figure 13 shows that instream flows are estimated to be adversely affected in nearly every year but the
City’s supply is affected in just one, the 1977 hydrologic year.
The impact to instream flows may be severe under the climate change and demand conditions assumed
here, even without considering uncertainty. This is shown in Figure 14, which shows combined instream
flow levels in Castle and Maroon Creeks. These combined flows should be 27.3 cfs or greater to ensure
that minimums can be met for each creek. 16 The impacts appear to be most severe during the fall
months, but are also chronic during the winter months.

16

Negative values in Figure 13 should be interpreted as 0, or no instream flow.

19

 Figure 13. Impact to Instream Flows with no Uncertainties Considered.

13. I5 Plat - Periuds when Combined Castle Creek Maruun Creek Flaw 1:213 aHer Meetin all but ISF Demands
Jan Feb Mar Jun Jul Au Oct Nov Dec
CVUVR 1969 2D 26 25 25
19?0 26 2 23 23
19?1 2 2 21 26
1919?3 25 18 24
19?4 26 23 25
19?5 25 23 23 25
19?6 21
19?? 2D
19?3 21
19?9 13 21
1930
1931 19
1932
1933
1934
1935
1936
193?
1933
1939
1990
1991
1992 23 23 23

1993
1994

 

20

Year 2065 Conditions With Uncertainty
The Monte Carlo simulation examined about 10,000 different, probability-weighted combinations of
climate change, flow adjustment factors, and demand.
Municipal Shortages
In contrast to the “certain” case above, the presence of uncertainties associated with climate change,
the flow adjustment factors, and demand reveals a significant probability that there may be more than
just one shortage to the Aspen water system. Figure 14 shows the following probabilities in a
cumulative manner:
•
•
•

The number of years with shortages to the City of Aspen over the 25-year hydrologic period of
record
The number of years with shortages exceeding 100 acre-feet
The number of years with shortages exceeding 1,000 acre-feet

For the first panel of Figure 14, the cumulative plot shows that with a probability of 0.80, or 80%, there
are one or more shortages over the 25-year period of record; with a probability of 0.10, or 10%, there
are 12 or more shortages over this period; and so on.
For the second panel of Figure 14, the cumulative plot shows that with a probability in the range of 0.40
to 0.50, there will be one or more shortages of 100 acre-feet or more; with a probability of 0.10, or 10%,
there are 5 or more shortages over 100 acre-feet during this period; and so on.
The third panel shows that with something less than 5% probability, there may be several shortages
greater than 1,000 acre-feet.

21

 Figure 14. Summary of shortages to the City of Aspen municipal supply over the 1970-1994 hydrologic
period of record (3 panels).

`
22

 Table 2 summarizes these frequencies and severities of shortages in terms of probabilities.
Table 2. Frequency and severity of shortages to the Aspen Water system.

•

•

•
•

With a probability of 0.002, or 1/500 odds, there may be as many as 22 shortages to Aspen’s
water system over the 25-year hydrologic period of record, with 18 of those exceeding 100 acrefeet and 8 exceeding 1,000 acre-feet.
With a probability of .01, or 1/100, there may be as many as 19 shortages over the 25-year
hydrologic period of record, with 15 exceeding 100 acre-feet, and 5 exceeding 1,000 acre-feet.
This is the level of risk that many water supply managers plan for.
With a probability of 0.10, or 1/10 odds, there is still estimated to be 12 shortages over the 25year hydrologic period of record, with 1 over 1,000 acre-feet.
At even odds, or 50-50, there may still be as many as 2 shortages over the 25-year hydrologic
period of record, with 1 over 1,000 acre-feet.

Instream Flows
A shortage to the City of Aspen means that instream flows have been depleted. So, with whatever
frequency municipal shortages are experienced, Castle and Maroon Creeks are dewatered at
approximately the same frequency. To graphically illustrate this, Figure 15 shows instream flows for the
1 in 100 outcome from above, where the creeks are dewatered 19 years out of 25. The impact to the
ecosystem is not estimated but would appear to be very severe.

23

 Figure 15. Impact to Flows with Uncertainty (1 in 100 occurrence).

Jan lab I'llar Jun Jul ?31131 12 333-1 15 3-5 Elf2-Sensitivity of the Results to Risk Assumptions
Figure 16 shows the contribution to variance attributable to the sources of uncertainty. Assumptions
about climate change account for 70% of the overall uncertainty surrounding the number and severity
of shortages, with assumptions about the flow adjustment factors and demand contributing 20% and
10% to the overall variability, respectively. This indicates that climate change may be the most effective
area in which to develop better data. It is notable that demand plays a relatively small role in the overall
variability, although it plays a more significant role in the severity of the shortage.

Figure 16. Sensitivity of the results to risk assumptions.

25

 Appendix A: Monte Carlo Simulation as a Tool for Assessing Supply and
Demand Uncertainties
What is Monte Carlo Simulation?
Monte Carlo simulation performs risk analysis by building models of possible outcomes by substituting a
range of values—a probability distribution—for any factor that has inherent uncertainty. It then
calculates results over and over, each time using a different set of random values from the probability
functions. Depending upon the number of uncertainties and the ranges specified for them, a Monte
Carlo simulation could involve thousands or tens of thousands of recalculations before it is complete. 17
For Aspen, factors containing inherent uncertainty include the flows of Castle Creek and Maroon Creek,
how those flows are statistically adjusted at the City’s diversion points, the possible impact of climate
change, and future municipal water demands. The results are estimates of the frequency and severity
of potential future water shortages.
This brief definition of Monte Carlo simulation will be further developed in subsequent sections.

The Benefit of Monte Carlo Simulation
The analysis contained in this document differs from Aspen’s previous analyses in how it deals with longterm water supply demand uncertainties, including potential future climate change impacts. Previous
analysis followed a traditional path of defining a limited number of plausible supply and demand
scenarios incorporating various combinations of these uncertainties and comparing the impacts of each.
Although this type of scenario analysis is common, and is a useful starting point for planning, it is not
without some shortcomings.
•

•
•

17

The number of scenarios are generally limited in number. For instance, the previous WWG
analysis of Aspen’s water needs considered about 15 different combinations of climate change
impacts and demand growth, with the assumptions underlying each appearing within
reasonable bounds. Although reasonable, in general this scenario building leaves a lot to the
analyst and doesn’t consider the full probable range of combinations of the uncertainties,
especially those combinations that might have a low probability of occurring yet may have
significant consequences to the water provider.
Unless otherwise noted, there are no insights about the probability of the outcomes. That is,
the scenarios are often weighted the same because they are assumed to have the same
probability of occurring.
A limited and unweighted range of possible outcomes is not useful for determining thresholds,
or tipping points, where the risk of an action, or inaction becomes critical.

http://www.palisade.com/risk/monte_carlo_simulation.asp

26

 In response to these shortcomings, combined with the substantial uncertainties associated with climate
change, this analysis uses Monte Carlo simulation to consider a much wider range of assumptions and
possible outcomes. The assumptions are probability-weighted in the sense that their underlying
uncertainties are explicitly addressed and incorporated into the analysis. As a result, there is not a
single point estimate of underlying water needs, or in Aspen’s case, the number of possible municipal
water shortages over a 25-year period. Instead of a single outcome, or point estimate, the outcomes
are expressed in terms of probabilities. As an example, the outcome could be:
… “there is a 40% probability that there will no shortages over the 25-year period of analysis; there is a
10% probability that the City will experience shortages in 12 years or more and experience at least one
shortage in excess of 1,000 acre-feet in 2 years out of 25; there is a 1% probability that there will be
shortages in 15 years or more, with shortages in excess of 1,000 acre-feet in 4 years out of 25”.
Although more complicated than simply asserting whether supplies are adequate or not over a limited
range of assumptions, expressing results in terms of probabilities is a realistic format more useful for
decision-making. It focuses discussion to where it belongs: the impacts of inherent risks and
uncertainties, and the willingness of decision-makers to accept these risks or take measures to hedge
against them.

Monte Carlo Simulation and Climate Change
An issue like climate change is well-matched for Monte Carlo simulation because little is certain about
the potential climate change impacts to Castle Creek and Maroon Creek. Despite the attention given to
the subject of climate change in municipal water supply planning, models adapting the results of larger
climate change models to local basins are still under development for many Colorado basins and have
inherent uncertainties of their own. Information to date reflects a degree of certainty that
temperatures are rising and peak run-off dates are getting earlier in the year. Plant evapotranspiration
(ET) rates appear to be increasing as a result of the higher temperatures. However, climate change’s
potential impact to the long-term timing and volume of run-off remains highly uncertain.
In response to these major uncertainties, including the uncertainties about the shape of the underlying
probability distribution itself, available information was used to define the likely distributions around
the timing of run-off, in terms of weeks relative to the period 1970-1994, and average weekly flows, also
relative to 1970-1994. Discussion of this process is contained in the main body of this report. In
combination with the other uncertain variables, Monte Carlo simulation was then used to assess a very
wide range and large number of combinations of climate change-induced timing and flow combinations,
approximately 10,000 different combinations, weighted by probability. The results of this process are
also contained in the main body of this report, but it should be noted that sensitivity analysis associated
with the Monte Carlo simulations indicated that the uncertainties of climate change was the major
driver behind uncertainties in the number of possible shortages, much more so than demand
uncertainties.

Implementing Monte Carlo Simulation

27

 Although the term Monte Carlo suggests a gaming application, this method of simulation has wide
application and acceptance, including for water resources planning, financial planning, and energy
exploration.
The benefit of Monte Carlo simulation is its ability to simultaneously consider a large number of
combinations and uncertainties, far more than the number considered in previous analyses. As a
greater number of combinations are created through Monte Carlo simulations, a statistical picture
begins to develop regarding the probability and severity of shortages over the hydrological period of
record. That is, how often does demand exceed supply given these various combinations of uncertain
supply, demand, and climate change values?
How these combinations are “matched-up” depends on the assumptions made about the uncertain
variables. Input values used in a Monte Carlo analysis are, in technical terms, probability-weighted
because the analyst assigns probabilities to their frequency of occurrence. These probabilities describe
how the variable might range around its estimated value. Some probabilities can be described with a
normal, bell-shaped, distribution, meaning that it is equally likely that the value might fall below or
above its estimated value. Figure A-1, below, is a depiction of a normal distribution for a hypothetical
example. As can be seen, the distribution is symmetric around the expected value of 180 in this
example.
Figure A-1. Hypothetical Example of a “Normal” Statistical Distribution

Figure A-2 illustrates an alternative depiction of this variable as having skewed characteristics. The
mean is the same, 180, but there is a higher probability that the value is higher than 180 than below it.
Alternatively stated, the distribution in Figure A-2 has a long tail, indicating that although the probability
is small, a large impact is possible.

28

 Figure A-2. Hypothetical Example of a Non-Normal Skewed Statistical Distribution

Variability in time series and cross-sectional data is often used to assist in developing these distributions,
although informed judgment may also play a role when data is lacking. Many uncertainties in water
planning are non-normal, or skewed, in nature because they are influenced by sometimes erratic
weather patterns with periodic extreme events. Monte Carlo simulation is the best tool available for
incorporating combinations of these skewed characteristics.
Given assumptions about the uncertainties affecting a municipality’s water supply reliability and their
statistical characteristics, what sort of output can be expected? Figure A-3 is an example of the type of
output that Monte Carlo simulation can create. It shows a hypothetical output that summarizes the
number of shortages over a 25-year period of record. As a result of variables that have non-normal
distributions, the graphic shows that most of the time there are only 2 shortage years of the 25
considered. However, it is much more likely that there will be more shortages of this magnitude rather
than fewer. There may be as many as 16 to 18. Again, the example is hypothetical, but this type of data
tells decision makers that reliance upon averages and most likely values does not always paint the full
picture.

29

 Figure A-3. Example Monte Carlo Output for Hypothetical Example

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

425 Trials View 425 Displayed
Number ufyaar? with MiG-l Elulages
12.312
- 1212

[1.24 - 111-11
[121
- an
{1.13 

1115 

J3 - an 
12.12 *9
{1.129? - 443'

r1125 
- 2D
[1123 
1111Years
5 Certainty: 11111111] 1: 4 .,

 

 

 

 

30

Appendix B: Model Screenshots

31

Figure B-1. Screen shot of Maroon Creek assumptions: flow adjustments between the Maroon Creek gage and City diversion; adjustments
for climate change.
Note, green highlighted cells represent uncertain variables examined with Monte Carlo simulation

32

 Figure B-2. Screen shot of Castle Creek assumptions: flow adjustments between the Castle Creek gage and City diversion; adjustments for
climate change
Note, green highlighted cells represent uncertain variables examined with Monte Carlo simulation

User Interface

Output Graphs

Castle Creek at Aspen Diversion - WY 1970-1994
Properties of Average Weekly Hydrograph
*52-week hydrograph
*Leap year days excluded from calculations
*December 24-31 treated as an 8-day week (arbitrary)
23.6 cfs
479.4 cfs
38
18-Jun
to

500.0
475.0
450.0
425.0

Castle Creek at Aspen Diversion, Average Weekly Flow Water Year 19701994
Average Weekly Hydrograph, WY 1970-1994
Modified Hydrograph

400.0

24-Jun

375.0

Average Weekly Flow [cfs]

Min Weekly Flow =
Max Weekly Flow =
Peak Week of Water Year =
Dates of Peak Flow =

525.0

350.0

User Inputs

325.0

(1) Enter a multiplier ratio to translate flows at the upstream USGS stream gage to flows at the downstream municipal intake

Gage Flow Ratio, Castle Creek =

2.43 Example: Enartech 1994 assumed a ratio of 2.30
NOTE: If gage values are desired, enter a value of 1

(2) Enter value between -6 weeks (earlier peak) and +6 weeks (later peak)
Peak Shift =

-4 weeks

OK!

(3) Select Option from Pull-down Menu Below (Click yellow box and pull-down will appear)
Flow Modification Options = Modify Entire Hydrograph
(4) Enter percent flow modification as a decimal value between -1 and 1
Peak Modification Factor =

-0.35

2.43

300.0
275.0
250.0
225.0
200.0
175.0
150.0
125.0
100.0
75.0
50.0
25.0
0.0

(5) For Modify Peak Flow Only option enter a value between MIN = 23.6 cfs and MAX = 479.4 cfs.
Peak Modification Threshold =

50 cfs

1 2 3 4 5 6 7 8 9 10111213141516171819202122232425262728293031323334353637383940414243444546474849505152

Week of water year (starts October 1)

OK!

OK!

33

 Figure B-3. Screen shot of operations routing component.
City of Aspen
Water Supply System Model
Castle Creek and Maroon Creek

Herrick Diversion Rate =
Herrick IRR start week =
Herrick IRR stop week =

Developed by HWC/smt
REVISED July 17, 2017
ISF Right
Castle Creek
Maroon Creek

Flow [cfs]
13.3
14.0

7
Thomas Reservoir Demands

WY
1970
1970
1970
1970
1970
1970
1970
1970
1970
1970
1970
1970
1970
1970
1970
1970
1970
1970
1970

16
35 start May 28
2 end October 14

Week

Indoor Use Outdoor
Use [cfs]
[cfs]
1
3.6
0
2
3.6
0
3
3.6
0
4
3.6
0
5
4.8
0
6
4.8
0
7
4.8
0
8
4.8
0
9
4.8
0
10
5.1
0
11
5.1
0
12
5.1
0
13
5.1
0
14
4.6
0
15
4.6
0
16
4.6
0
17
4.6
0
18
4.9
0
19
4.9
0

14.1

Bypass Demands

TOTAL
Estimated
Thomas
Depletion Flow at
Reservoir
Castle
between
NonCastle
Downstream
Demand Creek at Gage and
Creek
Potable
Irrigation
[cfs]
Use [cfs]
Gage [cfs] Intake [cfs] Intake [cfs] Demand [cfs]
0.1
3.7
27.3
2
27.3
13.2
0.1
3.7
25.1
2
25.1
13.2
0.1
3.7
23.8
2
23.8
13.2
0.1
3.7
22.6
2
22.6
13.2
0.4
5.2
21.4
0.5
21.4
0
0.4
5.2
21.2
0.5
21.2
0
0.4
5.2
20.2
0.5
20.2
0
0.4
5.2
19.4
0.5
19.4
0
0.4
5.2
17.3
0.5
17.3
0
0.2
5.3
15.7
0.5
15.7
0
0.2
5.3
15.8
0.5
15.8
0
0.2
5.3
16.9
0.5
16.9
0
0.2
5.3
16.4
0.5
16.4
0
0
4.6
17.9
0.5
17.9
0
0
4.6
17.3
0.5
17.3
0
0
4.6
17.6
0.5
17.6
0
0
4.6
17.7
0.5
17.7
0
0
4.9
16.6
0.5
16.6
0
0
4.9
16.3
0.5
16.3
0

Available
to City at
Available
Castle
to City at
TOTAL
Creek
Maroon Available
Intake
Creek
at Both
Estimated
after IRR
Intake
Intakes
Flow at
Herrick
and AUG Maroon
after
before
Ditch
bypass
M&I and
Creek
Diversion Herrick
[cfs]
[cfs]
ISF [cfs]
Intake [cfs]
[cfs]
14.1
26.5
16
10.5
24.5
11.9
23.8
16
7.8
19.7
10.6
22.3
0
22.3
32.9
9.4
20.5
0
20.5
30.0
21.4
18.9
0
18.9
40.3
21.2
18.0
0
18.0
39.2
20.2
18.5
0
18.5
38.7
19.4
18.3
0
18.3
37.7
17.3
17.2
0
17.2
34.4
15.7
16.2
0
16.2
32.0
15.8
15.3
0
15.3
31.1
16.9
14.3
0
14.3
31.2
16.4
13.3
0
13.3
29.6
17.9
13.6
0
13.6
31.5
17.3
14.0
0
14.0
31.3
17.6
14.4
0
14.4
32.0
17.7
13.0
0
13.0
30.6
16.6
12.3
0
12.3
28.8
16.3
12.1
0
12.1
28.4

34

17

17

ISF Bypass Demand

Combined
Flow
Remaining
after
Meeting
Magnitude
M&I
of M&I
Castle
Maroon
Demands
Shortage Creek ISF Creek ISF
M&I
[cfs]
[cfs]
[cfs]
[cfs]
Shortage?
20.8 NO
0.0
13.3
14.0
16.0 NO
0.0
13.3
14.0
29.2 NO
0.0
13.3
14.0
26.3 NO
0.0
13.3
14.0
35.1 NO
0.0
13.3
14.0
34.0 NO
0.0
13.3
14.0
33.5 NO
0.0
13.3
14.0
32.5 NO
0.0
13.3
14.0
29.2 NO
0.0
13.3
14.0
26.7 NO
0.0
13.3
14.0
25.8 NO
0.0
13.3
14.0
25.9 NO
0.0
13.3
14.0
24.3 NO
0.0
13.3
14.0
26.9 NO
0.0
13.3
14.0
26.7 NO
0.0
13.3
14.0
27.4 NO
0.0
13.3
14.0
26.0 NO
0.0
13.3
14.0
23.9 NO
0.0
13.3
14.0
23.5 NO
0.0
13.3
14.0

456

456

Combined
Flow
Remaining
after
Meeting
Magnitude
ISF
of ISF
Demands
Shortage
ISF
[cfs]
[cfs]
Shortage?
-6.5 YES
6.5
-11.3 YES
11.3
1.9 NO
0.0
-1.0 YES
1.0
7.8 NO
0.0
6.7 NO
0.0
6.2 NO
0.0
5.2 NO
0.0
1.9 NO
0.0
-0.6 YES
0.6
-1.5 YES
1.5
-1.4 YES
1.4
-3.0 YES
3.0
-0.4 YES
0.4
-0.6 YES
0.6
0.1 NO
0.0
-1.3 YES
1.3
-3.4 YES
3.4
-3.8 YES
3.8

 Figure B-4. Screen shot of Demand assumptions
Note, green highlighted cells represent uncertain variables examined with Monte Carlo simulation

35

 Figure B-5. Screen shot of shortage estimates with expected values for demand, flow adjustments, and climate change
Note: Monte Carlo simulation examined about 10,000 different combinations of plausible demands, flow adjustment factors, and climate change impacts.
The following graphic represents results from a single combination.

Annual Shortages
9,000
8,000
7,000
6,000
5,000
4,000
3,000
2,000
1,000

Hydrologic year
Annual shortage to Aspen

Annual instream flow shortage

36

1994

1993

1992

1991

1990

1989

1988

1987

1986

1985

1984

1983

1982

1981

1980

1979

1978

1977

1976

1975

1974

1973

1972

1971

-

1970

Annual
instream
flow
shortage
719
215
2,418
1,466
3,696
1,971
2,710
7,994
6,410
3,569
1,700
4,023
2,264
176
33
500
2,710
2,804
5,444
2,446
1,020
292
1,635

Acre-feet

WY
1970
1971
1972
1973
1974
1975
1976
1977
1978
1979
1980
1981
1982
1983
1984
1985
1986
1987
1988
1989
1990
1991
1992
1993
1994

Annual
shortage
to Aspen
39
1,922
103
3
-

 Number of years with M&I shortages
Number of years M&I shortage exceeds 100 acre-feet
Number of years M&I shortage exceeds 1000 acre-feet

4
2
1

Figure B-6. Screen shot of estimated impacts to instream flows with expected values for demand, flow adjustments, and climate change
Note: Monte Carlo simulation examined about 10,000 different combinations of plausible demands, flow adjustment factors, and climate change impacts.
The following graphic represents the results from a single combination.

Figure 13. Spells Plot - Periods when Combined Castle Creek + Maroon Creek Flow <=27.3 cfs after Meeting all but ISF Demands
CY Wk
WY Wk
1969
1970
1971
1972
1973
1974
1975
1976
1977
1978
1979
1980
1981
1982
1983
1984
1985
1986
1987
1988
1989
1990
1991
1992
1993
1994

Jan
Feb
Mar
Apr
May
Jun
Jul
Aug
Sep
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40
14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52
1
21
27 27 28 27 24 24 24 25 25 28 31 34 39 56 77 ## ## ## ## ## ## ## ## ## 259 238 154 104 75 62 43 41 41 50 39 76 93 66 45 38
29 30 31 30 31 30 29 28 28 26 28 34 51 77 ## ## ## ## ## ## ## ## ## ## 335 206 145 118 103 73 52 41 42 49 53 50 32 25 19 22
25 27 27 26 25 24 24 24 25 27 32 42 56 82 ## ## ## ## ## ## ## ## ## ## 154 85 54 30 22 15 16 12 18 14 13 22 16 21 16 16
26 29 24 23 23 21 20 18 20 22 23 29 38 55 76 98 ## ## ## ## ## ## ## ## 168 272 170 134 110 77 66 67 56 48 40 35 31 21 17 19
27 26 26 25 24 22 21 20 20 21 26 31 43 63 83 ## ## ## ## ## ## ## ## ## 249 136 79 39 40 32 22 21 18
8 1.7 4.2 1.2 0.8 -1.8 4.4
26 23 23 24 23 23 23 21 22 25 24 31 35 55 72 96 ## ## ## ## ## ## ## ## 133 159 277 251 211 119 85 65 63 46 34 32 31 24 16 15
25 23 24 24 23 22 25 23 25 25 29 35 45 81 ## ## ## ## ## ## ## ## ## ## 112 88 78 49 41 31 29 20 20 18 14 12 8.6 7.7 14 17
21 20 20 19 18 17 16 16 17 18 20 25 33 52 80 ## ## ## ## ## ## ## ## 89 16 -11 -11 -19 -18 -14 -15 -15 -11 -8.4 -10 -7 -4.3 -9 -11 -6
15 16 15 15 15 14 15 15 15 17 18 24 31 48 70 93 ## ## ## ## ## ## ## ## 289 218 140 128 121 74 52 31 30 16 11 14 10 7.3 3.7
5
19 18 18 18 18 18 18 18 19 20 23 28 37 54 73 ## ## ## ## ## ## ## ## ## 214 264 212 164 164 146 95 76 90 56 38 32 20 15 13 14
23 23 23 23 23 22 23 23 24 25 27 33 39 56 73 ## ## ## ## ## ## ## ## ## 345 237 169 121 86 69 55 43 49 37 34 35 43 25 20 22
30 29 26 23 22 21 19 19 19 20 22 28 35 52 84 ## ## ## ## ## ## ## ## ## 94 50 35 23 16 13 6.1 4.9 10 4.5 5.8 14 14 8.6 5.8 8.3
13 14 17 23 24 23 22 25 26 25 27 29 37 55 84 ## ## ## ## ## ## ## ## ## 227 221 177 140 141 150 127 84 89 64 49 49 48 53 55 52
29 28 29 29 28 26 26 26 26 27 31 38 48 72 96 ## ## ## ## ## ## ## ## ## 357 323 246 224 178 141 162 153 122 93 83 65 39 31 26 30
33 32 29 31 32 31 30 31 30 29 30 40 53 75 ## ## ## ## ## ## ## ## ## ## 420 390 334 325 239 229 164 125 140 127 106 87 67 62 56 56
48 46 45 45 43 41 40 38 36 36 40 49 57 79 ## ## ## ## ## ## ## ## ## ## 424 232 208 166 142 113 97 85 68 52 48 58 52 51 41 40
37 37 36 36 36 33 32 33 32 35 41 52 69 ## ## ## ## ## ## ## ## ## ## ## 362 247 266 161 138 111 81 75 80 92 78 65 67 53 54 50
37 36 33 30 29 29 30 28 27 34 33 40 47 76 ## ## ## ## ## ## ## ## ## ## 173 97 79 55 48 59 56 57 51 58 33 31 19 17 14 16
29 29 27 25 27 27 27 28 32 32 33 45 61 79 ## ## ## ## ## ## ## ## ## ## 151 98 58 23 13 12 22 14 14 14 12 11 17 16 13 14
24 23 25 27 27 24 26 27 24 23 28 35 49 68 94 ## ## ## ## ## ## ## ## ## 178 112 108 76 44 70 52 34 34 17 9.3 12 9.3 11 9.4 12
17 18 16 17 18 19 19 21 24 24 26 32 46 68 90 ## ## ## ## ## ## ## ## ## 193 127 79 57 28 20 12 6.1 16 7.2 3.6 7.8 0.7 8.9 6.2 15
22 22 21 19 19 19 20 18 19 21 22 27 35 70 84 ## ## ## ## ## ## ## ## ## 247 138 128 93 72 54 42 31 29 18 18 26 35 27 18 26
26 25 26 23 23 24 24 24 25 24 29 36 49 71 ## ## ## ## ## ## ## ## ## ## 161 118 95 83 58 62 37 43 38 39 39 33 19 24 21 20
28 30 32 30 31 31 31 33 34 34 37 46 65 90 ## ## ## ## ## ## ## ## ## ## 408 328 228 239 167 135 130 120 99 86 71 69 56 43 33 31
32 29 30 27 24 26 25 26 26 25 27 30 39 54 75 ## ## ## ## ## ## ## ## ## 239 118 72 40 28 25 25 21 26 15 13 25 13 12 9.2

37

Oct
41 42
2 3
16 29
35 45
17 32
18 42
13 26
3.2 19
13 27
12 24
-6.8 8
1.7 16
11 26
18 33
7 23
41 52
26 40
50 58
42 49
45 56
14 29
9 21
6.5 19
13 26
18 29
16 29
31 44

43
4
26
43
29
38
24
20
25
21
8
17
25
30
20
45
37
55
46
51
28
18
17
24
26
28
39

44
5
36
51
38
43
34
32
35
30
19
26
34
39
32
50
47
60
55
59
41
29
26
33
36
39
48

45
6
35
49
38
39
33
31
34
28
17
26
35
38
30
46
45
57
53
54
38
28
25
32
35
38
45

Nov
46 47
7 8
34 33
46 43
36 34
36 33
31 30
31 32
33 31
26 25
16 16
26 25
32 28
35 33
28 27
41 39
42 40
56 53
49 48
50 47
33 30
29 29
25 25
29 28
34 34
35 33
43 40

48
9
30
40
32
31
28
29
28
23
15
23
26
32
25
37
37
49
46
43
29
26
23
25
32
30
37

49
10
27
36
30
28
26
29
27
23
14
21
25
31
23
34
35
49
43
42
27
24
23
25
31
30
35

Dec
50 51
11 12
26 27
36 34
29 27
29 28
27 25
27 26
27 26
23 22
15 14
22 22
23 22
31 30
23 20
33 31
34 31
48 46
39 38
39 37
25 29
25 25
21 20
29 22
28 29
29 29
32 29

52
13
25
32
25
27
26
25
26
22
15
20
23
30
15
28
33
47
37
35
27
24
18
22
27
30
32

 Appendix C: Service Area Map of the Aspen Water System

38







fin?rd!

veer;


d??n





 

 

Aspen Water
Billing, Pump
Zones 
Electric
Service Area

 

 

For intemal use only

 

 

Legend

Roads Pumpzone


- Structures

Parcels

- 
I I: City of Aspen 4

Eledn'c Service Area - 5

6

 

7

 

 



1 inch 887 feet
When printed at 24"x36?

0 445 890 1.780

Feet

 

 

Date: 5/4/2016

City of Aspen 111g Cm Asa-r24
Utilities

Geographic Information Systems

This map/drawing?mage is a graphical
representation of the features
depicted and is not a legal representation.
The accuracy may change

depending on the enlargement or reduction.

Copyright 201 5 City cfAspen GIS