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Susitna-Watana Hydroelectric Project Document
ARLIS Uniform Cover Page
Title:
Geomorphology study
SuWa 143
Author(s) – Personal:
Author(s) – Corporate:
Alaska Energy Authority
AEA-identified category, if specified:
Aquatic and fish resources study requests
AEA-identified series, if specified:
Series (ARLIS-assigned report number):
Susitna-Watana Hydroelectric Project document number 143
Existing numbers on document:
Published by:
[Anchorage] : Susitna-Watana Hydroelectric Project, [2012]
Date published:
5/15/12
Published for:
Date or date range of report:
Volume and/or Part numbers:
Final or Draft status, as indicated:
Document type:
Pagination:
34 p.
Related work(s):
Pages added/changed by ARLIS:
Notes:
All reports in the Susitna-Watana Hydroelectric Project Document series include an ARLIS-
produced cover page and an ARLIS-assigned number for uniformity and citability. All reports
are posted online at http://www.arlis.org/resources/susitna-watana/
Susitna-Watana Hydroelectric Project FERC #14241 Alaska Energy Authority
Geomorphology Study Request 5/15/12 Page 1
1.1. Geomorphology Study
1.2. Requestor of proposed study
AEA anticipates resource agencies will request this study.
1.3. Responses to Study Request Criteria (18 CFR 5.9(b))
1.3.1. Describe the goals and objectives of the study proposal and the information to be
obtained
The overall goal of the study is to evaluate the effects of the Project on the geomorphology of
the Susitna River. The results of this study, along with results of the Fluvial Geomorphology
Study below Susitna-Watana Dam, will be used in combination with geomorphic principles and
criteria/thresholds defining probable channel forms to predict the potential for alteration of
channel morphology.
Specific objectives of this study are as follows:
1. Geomorphically characterize the Project affected river channels;
2. Empirically characterize the Susitna River sediment supply and transport conditions;
3. Assess channel and study site stability/change (1980s versus current conditions);
4. Characterize the surface area versus flow relationships for riverine habitat types over a
range of flows (e.g., 5,100 to 23,000 cfs) in the Middle River;
5. Conduct a reconnaissance level geomorphic assessment of potential Project effects on
the Lower River channel;
6. Conduct a reconnaissance level riverine habitat assessment of potential Project effects
on the Lower River channel;
7. Characterize the proposed Watana Reservoir geomorphology (changes resulting from
conversion of the channel/valley to a reservoir);
8. Assess potential issues related to large woody debris transport and recruitment; and
9. Characterize geomorphic conditions at stream crossings along access road/transmission
line alignments;
1.3.2. If applicable, explain the relevant resource management goals of the agencies and
Alaska Native entities with jurisdiction over the resource to be studied
To be completed by requesting organization.
1.3.3. If the requester is a not resource agency, explain any relevant public interest
considerations in regard to the proposed study
Fisheries resources are owned by the State of Alaska, and the Project could potentially affect
these public interest resources by affecting geomorphologic conditions and, in turn, fish habitat.
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1.3.4. Describe existing information concerning the subject of the study proposal, and
the need for additional information
An analysis of the Middle Susitna River reach geomorphology and how aquatic habitat
conditions change over a range of stream flows was performed in the 1980s using aerial
photographic analysis (Trihey & Associates 1985). The AEA Susitna Water Quality and
Sediment Transport Data Gap Analysis Report (URS 2011) states that “if additional information
is collected, the existing information could provide a reference for evaluating temporal and
spatial changes within the various reaches of the Susitna River.” The gap analysis emphasizes
that it is important to determine if the conditions represented by the data collected in the 1980s
are still representative of current conditions and that at least a baseline comparison of current
and 1980s-era morphological characteristics in each of the identified sub-reaches is required.
An analysis of the Lower River reach and how riverine habitat conditions change over a range of
stream flows was performed in the 1980s using aerial photographic analysis (R&M Consultants,
Inc. and Trihey and Associates 1985a). This study evaluated the response of riverine aquatic
habitat to flows in the Lower River reach between the Yentna River confluence (RM 28.5) and
Talkeetna (RM 98) (measured at Sunshine gage RM~84) ranging from 13,900 cfs to 75,200 cfs.
The study also included an evaluation of the morphologic stability of islands and side channels
by comparing aerial photography between 1951 and 1983. As with the Middle River
information, it is important to determine if the conditions represented by the 1980s data and are
representative of current conditions. Such a comparison should include not only an identification
of change, but should consider if the relative proportion of the various meso-habitat types
remain constant within a reach.
Considerable information is available form a variety of sources that will support the development
and execution of the General Geomorphology Study. Much of the available information is from
the 1980 studies associated with the earlier efforts to develop the Susitna Hydroelectric Project
(FERC No. 7114). In some cases, the older information will need to be replaced or
supplemented with newer information as the Susitna River is a dynamic system and historical
data such as cross sections and aerial in many areas will likely have changed considerably
since they were collected in the 1980s. However, these data when compared with current
information provide valuable tools to understand the behavior and physical processes driving
the geomorphology of the Susitna River. Additional data and analyses are needed to determine
if historical data can be used to reflect current conditions and to address some of the data gaps
identified for AEA Susitna Water Quality and Sediment Transport Data Gaps Analysis Report
(URS 2011).
1.3.5. Explain any nexus between project operations and effects (direct, indirect, and/or
cumulative) on the resource to be studied, and how the study results would
inform the development of license requirements
Construction and operation of the Project as described in the Pre-application Document (PAD;
AEA 2011) will affect flow, sediment, and large woody debris (LWD) downstream and upstream
of Susitna-Watana Dam. Downstream of the dam (Middle River and Lower River) Project
operations have the potential to alter aquatic habitat and channel morphology as a result of
changes to flow timing and magnitude, sediment supply and sediment transport capacity, large
woody debris (LWD) recruitment and transport. Above the dam (Upper River), Project
operations would result in trapping of sediments and LWD, deposition of sediments at tributary
mouths, beach formation, and erosion and/or mass wasting of soils within the impoundment.
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Geomorphology Study Request 5/15/12 Page 3
Construction of project access roads and transmission lines would require stream crossing
structures which would have the potential to affect stream geomorphology. The various
components of this study will address the extent of the associated project effects and data
needed for design of any necessary PM&E measures to minimize effects.
1.3.6. Explain how any proposed study methodology (including any preferred data
collection and analysis techniques, or objectively quantified information, and a
schedule including appropriate field season(s) and the duration) is consistent with
generally accepted practice in the scientific community or, as appropriate,
considers relevant tribal values and knowledge
1.3.6.1. Study Component G-1.1: Delineate Geomorphically Similar (Homogeneous) River
Segments
The goal of the Delineate Geomorphically Similar (Homogeneous) River Segments study
component is to geomorphically characterize the project affected river channels. This effort is
being performed as part of the 2012 studies and is also described in the Study plan for G-2S
Aquatic Habitat and Geomorphic Mapping of the Middle River Using Aerial Photography. The
study area is the length of the Susitna River from its mouth at the Cook Inlet (RM 0), upstream
to the Susitna-Watana Dam (RM 184) and upstream of Susitna-Watana Dam including the
reservoir inundation zone and on upstream to the Maclaren River confluence. The tributary
mouths along the Susitna River and in the reservoir inundation zone potentially affected by the
project are also included in the study area.
Existing Information and Need for Additional Information
This effort will support the understanding of the conditions in the Susitna River by applying a
geomorphic classification system based on form and process. It will also support efforts by
other studies including Instream Flow, Instream Flow Riparian Study, Fish Studies and Ice
Processes by providing a basis to stratify the river into reaches based on current morphology
and their potential sensitivity to the Project. A delineation of the Susitna River into reaches was
performed in the 1980s for the Middle River (Trihey & Associates 1985) and the Lower River
(R&M Consultants, Inc. and Trihey & Associates 1985a).
Methods
This effort consists of identification of a geomorphic classification systems and conducting the
delineation of geomorphic reaches based on the identified classification system.
Identification of Geomorphic Classification System
The first step in geomorphic reach delineation effort will be the identification of the system to
classify and delineate the reaches. Numerous river classifications exist (Leopold and Wolman,
1957; Schumm, 1963, 1968; Mollard, 1973; Kellerhals et al., 1976; Brice, 1981; Mosley, 1987;
Rosgen, 1994, 1996; Thorne, 1997; Montgomery and Buffington, 1997; Vandenberghe, 2001),
but no single classification has been developed that meets the needs of all investigators.
Several factors have prevented the achievement of an ideal geomorphic stream classification,
and foremost among these has been the variability and complexity of rivers and streams
(Mosley, 1987; Juracek and Fitzpatrick, 2003). Problems associated with the use of existing
morphology as a basis for extrapolation (Schumm, 1991) further complicates the ability to
develop a robust classification (Juracek and Fitzpatrick, 2003). For purposes of classifying the
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Susitna River, available classification systems will be reviewed and it is anticipated that a
specific system will be developed that borrows elements from several classifications system.
The classification scheme will consider both form and process. Development of this system will
be coordinated with the Instream Flow Study, Instream Flow Riparian Study, Ice Processes
Study and Fish Study so it is consistent with their needs. These studies may require further
stratification to identify specific conditions of importance to their effort, in which case, these
studies will further divide the river into subreaches. However, the overall reach delineations
developed in the Geomorphology Study will be used consistently across all studies requiring
geomorphic reach delineations.
Geomorphic Reach Delineation
The Lower River (RM 0 to RM 98), the Middle River (RM 98 to RM 184) and the Upper River to
the Maclaren River confluence (RM 184 to RM 260) will be delineated into large-scale
geomorphic river segments (a few to many miles) with relatively homogeneous characteristics,
including channel width, entrenchment, ratio, sinuosity, slope, geology/bed material,
single/multiple channel, braiding index and hydrology (inflow from major tributaries) for the
purposes of stratifying the river into study segments.
Since there are several studies that will require a reach delineation for planning 2012 field
activities, an initial delineation that will be primarily based on readily available information (most
recent high quality aerials, bed profile from the 1980s, geomorphic descriptions form the 1980s)
will be developed in April 2012. As additional information is developed—such as current aerials
and transects—the delineation will be refined and the various morphometric parameters will be
determined. Coordination with the River Flow Routing Model Transect Data Collection Study will
occur in order to obtain cross-section channel/floodplain data. Coordination with the Instream
Flow Study, Instream Flow Riparian Study, Geomorphic Modeling Study and Ice Process Study
will occur to ensure that the river stratification is conducted at a scale appropriate for those
studies.
A reconnaissance-level site visit of the Susitna River will be conducted that will be coordinated
with other studies to take advantage of scheduled boat and helicopter trips as well as
opportunities to coordinate with other studies. The Study Lead, Geomorphology Lead and
Sediment Transport Modeling Lead, the erosion Study Lead and at least one other senior
member of the Geomorphology Study team will participate in the reconnaissance trip. The
purpose of this site visit will be to provide key team members an overview of the river system.
This will be extremely useful for all the Geomorphology Study components.
Information Required
The following available existing information will be needed to conduct this study:
• Historical aerial photographs.
• Information on bed material size.
• Location and extent of lateral and vertical geologic controls.
• Drainage areas of major tributaries.
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• Topographic mapping including USGS survey quadrangle maps and LiDAR.
The following additional information will need to be obtained to conduct this study:
• Current high resolution aerial photography.
• Field observations made during a site reconnaissance.
• Extended flow record for the Susitna River and tributaries being developed by the
USGS.
• Profile of the river (thalweg or water surface)
1.3.6.2. Study Component G-1.2: Bedload and Suspended Load Data Collection at Tsusena
Creek, Gold Creek and Sunshine Gage Stations
The goal of the Bedload and Suspended Load Data Collection at Tsusena Creek (RM 182),
Gold Creek (RM 136) and Sunshine Gage (RM 84) Stations study component is to empirically
characterize the Susitna River sediment supply and transport conditions. This effort is being
performed by the USGS. The effort described is for 2012 and may be modified in subsequent
years based on experience gained form the 2012 work. The study covers the Susitna River from
RM 84 (Sunshine Station) upstream to RM 182 (Tsusena Gage).
Existing Information and Need for Additional Information
The collection of the data described in this study will supplement sediment transport data
previously collected in the 1980s. The additional data is needed to determine if historical data
can be used to reflect current conditions and to address some of the data gaps identified for
AEA Susitna Water Quality and Sediment Transport Data Gaps Analysis Report (URS 2011).
This study will provide information on current sediment supply conditions and support
determination of project effects on sediment supply. This information will be used by several
study components in this study as well as the Geomorphology Modeling below Susitna-Watana
Dam Study.
Methods
The following scope of work was provided by the USGS to describe the original scope of work:
• Operate and maintain the stream gages;
• Maintain datum at the site;
• Record stage data every 15 minute;
• Make discharge measurements during visits to maintain the stage-discharge rating curve
and to define the winter hydrograph;
• Post near real-time stage and discharge data on the USGS web site
http://waterdata.usgs.gov/ak/nwis/;
• Store the data in the USGS databases;
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• Publish the data in our annual Water-Resources Data for the United States report
(http://wdr.water.usgs.gov/);
• Collect at least 5 suspended sediment samples at Susitna River above Tsusena Creek,
at Gold Creek, and at Sunshine during the year for concentration and size analysis;
• Collect at least 5 bed material samples during the year at Susitna River above Tsusena
Creek, at Gold Creek, and at Sunshine for bedload transport determination and size
analysis;
• Operate a stage-only gage at a site upstream from Deadman Creek. Logistics at this site
may preclude continuous operation or telemetry of the information; and
• Suspended and bedload data, including calculation of sediment transport ratings and
daily loads, will be compiled in a technical memorandum delivered to AEA during FFY
2013, and as early as March, 2013, if possible. Provisional results from sampling will be
available as soon as lab data are available. Provisional results from sediment load
computations will be made available as soon as possible.
The bed load and suspended sediment data will be combined with existing rating curves to
identify the differences and similarities between the historical and current data sets. This
information will be used to evaluate whether the historical data sets are representative of current
conditions for the Susitna River at Gold Creek and the Susitna River at Sunshine.
The sediment transport data available for the Chulitna and Talkeetna rivers will be reviewed.
This will be accomplished using the sampling results collected in 2012, to help determine
whether or not the historical rating curves are expected to be accurate. Since current data are
not being collected on the Chulitna and Talkeetna rivers, this will primarily be accomplished by
developing the mass balance of sediment above three rivers (Gold Creek data) and below
(Sunshine data) to estimate the contributions from the Chulitna and Talkeetna Rivers. The
estimate based on the mass balance developed from the current data will be compared against
estimates based on the historical Chulitna and Talkeetna sediment transport relationships. In
addition, the historical Chulitna and Talkeetna sediment transport relationships and their
applicability to current conditions will secondarily be evaluated comparing the historical versus
new sediment rating curves at Gold Creek and at Sunshine (two locations where new data are
being collected in 2012). Based on the results of the effort, a recommend whether or not
additional sediment transport sampling is necessary in the Chulitna or Talkeetna rivers will be
made.
1.3.6.3. Study Component G-1.3: Sediment Supply and Transport Middle and Lower River
The goal of the Sediment Supply and Transport Middle and Lower River is to empirically
characterize the sediment supply and transport conditions in the Susitna River below Susitna-
Watana Dam. The study consists of estimation of sediment supply and transport for the Middle
and Lower rivers. The effort for the Lower River will be conducted in 2012 as part of G-S4:
Reconnaissance Level Geomorphic and Aquatic Habitat Assessment of Project Effects on
Lower River Channel. The remaining efforts (Middle River sediment supply, bed material
mobilization and effective discharge) will be conducted in 2013. The study area for this effort is
from the Susitna Station Gage (RM 28) to Susitna-Watana Dam (RM 184).
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Existing Information and Need for Additional Information
Sediment transport data are available along the mainstem Susitna River and several of the
major tributaries between the proposed Susitna-Watana Dam (RM 184) downstream to Susitna
Station RM 28) (URS 2011). The Project will reduce sediment supply to the Susitna River as
well as alter the timing and magnitude of the flows that transport the sediment downstream. The
results of this study component will provide the initial basis for assessing the potential for
changes to the Lower River and Middle River sediment balance and the associated changes to
geomorphology. The studies will also support G-2: Fluvial Geomorphology Modeling below
Susitna-Watana Dam Study through development of sediment supply information that will be
required for input to the model.
Methods
The methods are divided into five sections analyses: Lower River Sediment Load, Middle River
Sediment Supply, Characterization of Bed Material Mobilization and Effective Discharge and
Information Required.
Lower River Sediment Load
The sediment transport measurements the USGS has collected, both historical and current, will
be used to develop bed load and suspended load rating curves to facilitate translation of the
periodic instantaneous measurements into yields over longer durations (e.g., monthly, seasonal,
and annual). Since gradations of transported material will be available, the data will allow for
differentiation of transport by size fraction. Previous studies have documented the potential for
bias in suspended load rating curves due to scatter in the relationship between sediment
concentration or load and flow (Walling 1977a). Specifically, the bias can result from the
construction of linear least-squares regression relationships of logarithmic transformed
concentrations or loads and flows (Walling 1977b, Thomas 1985, Ferguson 1986). Various
procedures are available to address the bias, including accounting for seasonal differences in
sediment transport, and accounting for hysteresis related to rising and falling limbs of flood
hydrographs (Guy 1964, Walling 1974). Koch and Smillie (1986) and Cohn and Gilroy (1991)
describe methods of handling the bias correction depending on the expected distribution of
errors. The USGS Office of Surface Water (1992) endorsed the recommendations in Cohn and
Gilroy (1992) to use the Minimum Variance Unbiased Estimator (MVUE) bias correction for
normally distributed errors, or the Smearing Estimator (Duan 1983) when a non-normal error
distribution is identified. Once the sediment measurements are available for review, the potential
for bias in the sediment rating curves will be considered and addressed as appropriate.
The total sediment load delivered to the Lower River for pre- and post-Project conditions will be
evaluated using the sediment rating curves developed from the historical data for the Sunshine
and Susitna Station gaging stations and any new sediment transport data being collected by the
USGS under Study G-S1: Determine Bedload and Suspended Sediment Load by Size Fraction
at Tsusena Creek, Gold Creek, and Sunshine Gage Stations (if the 2012 data is available from
the USGS in time for this analysis). If the 2012 Tsusena Creek data are available, it will be
compared against the 2012 Gold Creek data to estimate the sediment inflow between Tsusena
and Gold Creek (see “Middle River Sediment Supply” below). This will allow development of a
sediment rating curve from the 1985 data for the Susitna at Tsusena Creek (representative of
sediment transport at the Susitna-Watana dam site). Similarly, the sediment transport rating
curves at Gold Creek, Sunshine and the Chulitna Rivers will be used to determine the combined
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sediment contribution of the Talkeetna and other sediment inflows between Gold Creek and
Sunshine. Moving downstream, the sediment rating curves at Sunshine, Yentna River and
Susitna Station can be used to determine the sediment contribution between Sunshine and
Susitna Station.
The rating curves for the mainstem Susitna stations, gaged (tributary stations and those
developed for contributing ungaged (in terms of sediment data collection) areas between
stations will be used to develop the sediment balance for the pre-Project hydrology for a wet,
average and dry year. This will include the contributions from the gaged tributaries and the
ungaged contributing areas. The latter will be calculated based on the assumption that the
sediment load in the Susitna is currently in a state of equilibrium. To develop the sediment
balance for the post-Project condition, the historical (pre-Project) sediment rating curve
developed for below the Susitna-Watana Dam (Tsusena Creek) will be reduced by 100 percent
for the bed load and 90 percent for the suspended load. This sediment inflow as well as the
inflows from the gaged tributaries and the ungaged contributing areas (determined from the pre-
Project sediment balance) will be added together to determine the sediment balance for the
post-Project condition for representative wet, average and dry years. The overall sediment
balance below the dam for the Post-Project condition for representative wet, average and dry
years will then be calculated based on adding the gaged and ungaged contributions for the pre-
project condition to the reduced sediment below the Susitna-Watana Dam. The results of the
pre- and post-Project sediment balance determinations will be used to identify the relative
influence of the trapping of sediments in the Susitna Watana reservoir on the overall sediment
balance along the Susitna River.
Middle River Sediment Supply
The sediment supply inputs in the Middle River downstream of Susitna-Watana Dam will be
estimated. Contributions from identified mass wasting locations or tributary sediment sources
downstream of the dam will be estimated. Potential procedures to estimate the Middle River
sediment supply include: 1) the use of watershed area and regional sediment supply
relationships and 2) the determination of the difference between Tsusena Creek and Gold
Creek sediment transport. Past USGS sediment data may be available for Indian and Portage
Creek which could also be used to assist in the estimation of the Middle River sediment supply
inputs.
Characterization of Bed Material Mobilization
The approximate discharge that bedload transport begins, incipient motion, in the Susitna River
near the dam and at selected locations in the Middle and Lower rivers will be estimated using
the USGS empirical sediment rating curves, incipient motion calculations, and field
observations. The determination of the discharge at which incipient motion occurs will be used
to estimate and compare the frequency, number of days, of bed mobilization for the pre- and
post-project condition hydrology. This will be performed on both a monthly and annual basis and
the selected locations for a range of flow years.
The concept of incipient motion as advanced by Shields (1936) relates the critical shear stress
for particle motion (τc) to the dimensionless critical shear stress (τ*c) and the unit weight of
sediment (γs), the unit weight of water (γ), and the median particle size of the bed material (D50).
One key limitation of this relation is the specification of τ*c, for incipient motion, which can range
by a factor of three (Buffington and Montgomery 1997). To work around this limitation, Parker
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(Parker et. al. 1982) proposed relating the reference Shields stress (τ*r) to the dimensionless
transport rate W* = 0.002, which represents flow conditions that are just high enough to begin
mobilization of the bed material (i.e., incipient motion conditions). For this relationship, W* is a
function of the unit bed load and the total boundary shear stress, both of which are relatively
simple parameters to calculate from field data if bed load and discharge measurements are
included.
Consistent with the work of Mueller (Mueller et. al. 2005), bed material mobilization at various
locations along the project reach will be characterized using this procedure. Data collected by
the USGS, which will include the necessary series of coupled flow and bed load transport
measurements, will be used to formulate a series of bed load rating curves. These curves will
then provide a basis for estimating τ* that corresponds to a dimensionless transport rate W* =
0.002 for bed material mobilization.
Effective Discharge
The concept of effective discharge, as advanced by Wolman and Miller (1960), related the
frequency and magnitude of various discharges to their ability to do geomorphic work by
transporting sediment. They concluded that events of moderate magnitude and frequency
transported the most sediment over the long-term, and that these flows were the most effective
in forming and maintaining the planform and geometry of the channel. Andrews (1980) defined
the effective discharge as “the increment of discharge that transports the largest fraction of the
annual sediment load over a period of years.”
Alluvial rivers adjust their shape in response to flows that transport sediment, and numerous
authors have attempted to relate the effective discharge to the concepts of dominant discharge,
channel-forming discharge and bankfull discharge, and it is often assumed that these
discharges are roughly equivalent and correspond to approximately the mean annual flood peak
(Benson and Thomas, 1966; Pickup, 1976; Pickup and Werner, 1976; Andrews, 1980, 1986;
Nolan et al., 1987; Andrews and Nankervis, 1995). Quantification of the range of flows that
transport the most sediment provides useful information to assess the current state of
adjustment of the channel, and to evaluate the potential effects of increased discharge and
sediment delivery to channel behavior. Although various investigators have used only the
suspended-sediment load and the total sediment load to compute the effective discharge, the
bed-material load should generally be used when evaluating the linkage between sediment
loads and channel size because it is the bed-material load that has the most influence on the
morphology of the channel (Schumm, 1963; Biedenharn et al., 2000).
For purposes of this study, the effective discharge will be computed by dividing the range of
flows into 30 logarithmic classes (Biedenharn et al., 2000) and then computing the total quantity
of bed material load transported by the flows within each class to determine the discharge that
transports the most sediment. The total quantity of bed material transport will be based on
sediment rating curves developed from the USGS measurements, and multiplying the bed
material transport rate for the average discharge in each class by the corresponding duration
using information from mean daily flow duration curves. The effective discharge will be
determined for both the pre- and post-project conditions.
Information Required
The following available existing information will be needed to conduct this study:
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• Current aerial photographs.
• Historical suspended sediment and bed load data for the Susitna River.
• Flow records for the Susitna River.
The following additional information will need to be obtained to conduct this study:
• Suspended and bed load data for the Susitna River at Tsusena Creek and Gold Creek
being performed by the USGS.
• Extended flow record for the Susitna River and gaged tributaries within the study area
being developed by the USGS.
• Estimated flows for the ungaged tributaries within the study area.
• Extended flow record for the Susitna River and tributaries being developed by the
USGS.
• Collection of bed material samples throughout the Middle and Lower Rivers.
• Hydraulic conditions form the Hydraulic Routing Model
1.3.6.4. Study Component G-1.4: Assess Geomorphic Change Middle and Lower Rivers
The goal of the Assess Geomorphic Change Middle and Lower Rivers study component is to
compare existing and 1980s geomorphic feature data from aerial photo analysis to characterize
the relative stability of the 1980s study sites and river morphology under unregulated flow
conditions. The effort for the Middle River will be conducted in 2012 as part of G-S2: Aquatic
Habitat and Geomorphic Mapping of the Middle River Using Aerial Photography and for the
Lower River as part of G-S4: Reconnaissance Level Geomorphic and Aquatic Habitat
Assessment of Project Effects on Lower River Channel. The study area extends from the mouth
of the Susitna River (RM 0) at Cook Inlet to Susitna-Watana Dam (RM 184).
Existing Information and Need for Additional Information
An analysis of the Middle Susitna River reach geomorphology and how aquatic habitat
conditions changed over a range of stream flows was performed in the 1980s using aerial
photographic analysis (Trihey & Associates 1985). A similar analysis was performed for the
Lower River (R&M Consultants, Inc. and Trihey and Associates 1985a). The1980s Lower River
study also included an evaluation of the morphologic stability of islands and side channels by
comparing aerial photography between 1951 and 1983. The AEA Susitna Water Quality and
Sediment Transport Data Gap Analysis Report (URS 2011) states that “if additional information
is collected, the existing information could provide a reference for evaluating temporal and
spatial changes within the various reaches of the Susitna River.” The gap analysis emphasizes
that it is important to determine if the conditions represented by the data collected in the 1980s
are still representative of current conditions and that at least a baseline comparison of current
and 1980s-era morphological characteristics in each of the identified subreaches is required.
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Understanding existing geomorphic conditions, changes over a range of stream flows, and how
stable/unstable the geomorphic conditions have been over recent decades provides a baseline
set of information needed to provide a context for predicting the likely extent and nature of
potential changes that will occur due to the Project. Results of this study may also be used in
the Instream Flow Riparian and Ice Processes studies to provide the surface areas of bars likely
to become vegetated in the absence of ice-cover formation.
Methods
This study component has been divided into the Middle and Lower Rivers since the available
information differs. The analysis of geomorphic change will be conducted for a single
representative discharge.
Middle River
Coordination with AEA’s Spatial Data Contractor to digitize the riverine geomorphic features
from RM 98 to RM 150 defined in the 1980s from hard copy maps as found in the Middle River
Assessment Report (Trihey & Associates 1985) will occur. Each feature will be a polygon
(without slivers). Geomorphic features that are visible between the 1980s and current images,
including the main channel, side channels, the presence and extent of mid-channel bars,
vegetated bar areas, and changes at tributary deltas will be digitized for a single representative
flow. (Note: the AEA Spatial Data Contractor will complete the digitizing and develop associated
metadata for the 1980s digitizing.) From RM 98 to RM 184 the geomorphic features at a single
representative stream flow on the 2012 aerial photographs will also be digitized and delineated
using the orthorectified photography and ArcGIS software (each geomorphic feature will be a
polygon without slivers. (Note: the Study Contractor will complete the digitizing and develop
associated metadata for the 1980s digitizing.)
The information developed from digitizing the aerials will be used to analyze and compare the
geomorphology for 1980s and current conditions. From RM 98 to RM 150 GIS software will be
used to compare the 2012 versus 1980s total surface area associated with each geomorphic
feature. Data results will be compiled into tables and graphs, as appropriate, to show the
difference in surfaces area of the feature types between 2012 and the 1980s photography. The
lead geomorphologist will provide training to ensure appropriate application of the geomorphic
definitions. Since this 34-mile river segment below the proposed Susitna-Watana Dam site (RM
150 to RM 184) was not analyzed in the 1980s, this portion of the river will be a new
assessment (2012 photography only) that will not be compared to past studies. However, the
methods for analyzing riverine geomorphic features will remain the same.
The geomorphic change over the length of the river (main channel location, side channel
location, bars, channel and side channel width, channel and side channel location) will be
qualitatively assessed between the 1980s and 2012. Reaches will be identified that are
relatively stable versus those that are more dynamic. Reaches that would be most susceptible
to channel change (e.g., width or planform change) with changes in the flow or sediment regime
resulting from the Project or Project operations will be qualitatively identified. Depending upon
the results of the riverine geomorphic analysis, additional historical photographic analysis may
be requested as part of future geomorphic studies, but this additional analysis is not included at
this time. Additional analysis of historical aerial photographs and the corresponding flows that
occurred between 1985 and 2012 could be pertinent if substantial changes in the riverine
habitat types (surface area, locations, etc.) were identified during comparison of the 2012 and
1980s photography. This type of additional aerial photo analysis could provide more specific
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information on the flow magnitude(s) and other conditions (for example ice formation) that may
cause substantial geomorphic channel adjustments. If additional analysis is identified, it will be
performed under the 2103/2014 studies.
Lower River
The 36,600 cfs September 6, 1983 set of Lower River aerial photographs and current satellite
images or aerial photographs will be obtained to compare historical and present-day channel
planform and pattern from RM 28 to RM 99. Planform shifts of the main channel and side
channels will be identified between the 1983 and current aerial photography. The three rivers
confluence area is also a part of the analysis (extended to RM 99). Geomorphic features that
are visible between the 1983 and current images, including the presence and extent of side
channels, vegetated bar areas, and changes at tributary deltas will be mapped and
characterized. In areas where the mainstem channel consists of a dynamic braid plain mostly
void of stabilizing vegetation, the effort will be directed to defining the edges of the active
channel rather than detailing the myriad of channels within the active area. Major sloughs and
side channel along the lower river margins will be included in the digitizing effort.
The rest of the Lower River effort will be similar to the Middle River. The geomorphic change
over the length of the river (main channel location, side channel location, bars, channel and side
channel width, channel and side channel location) will be qualitatively assessed between the
1980s and current. Reaches will be identified that are relatively stable versus those that are
more dynamic. Reaches that would be most susceptible to channel change (e.g., width or
planform change) with changes in the flow or sediment regime resulting from the Project or
Project operations will be qualitatively identified. Depending upon the results of the riverine
geomorphic analysis, additional historical photographic analysis may be requested as part of
future geomorphic studies, but this additional analysis is not included at this time. Additional
analysis of historical aerial photographs and the corresponding flows that occurred between
1985 and 2012 could be pertinent if substantial changes in the riverine habitat types (surface
area, locations, etc.) were identified during comparison of the 2012 and 1980s photography.
This type of additional aerial photo analysis could provide more specific information on the flow
magnitude(s) and other conditions (for example ice formation) that may cause substantial
geomorphic channel adjustments.
Information Required
The following available existing information will be needed to conduct this study:
• Historical 1980s orthorectified aerial photographs for the Middle and Lower rivers.
The following additional information will need to be obtained to conduct this study:
• Obtain recent or fly 2012 orthorectified aerial photos (or satellite imagery) in the Middle
and Lower Rivers at a flow similar to the historic aerials.
• Acquire historic orthorectified aerial photos and digitized geomorphic features from the
AEA Spatial Data Contractor (SDC) for the Middle and Lower Rivers for a single
discharge.
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1.3.6.5. Study Component G-1.5: Riverine Habitat Versus Flow Relationship Middle River
The goal of the Riverine Habitat Versus Flow Relationship Middle River study component is to
develop existing and 1980s riverine habitat type area data over a range of flows in order to
quantify riverine habitat versus surface area relationships. The study area extends from the
three rivers area (RM 98) to Susitna-Watana Dam (RM 184). Up to 20 study sites not exceeding
fifty percent of the reach will be studied in the 2012 study G-S2: Aquatic Habitat and
Geomorphic Mapping of the Middle River Using Aerial Photography. All or part of the remaining
portion may be studied in 2103/2014 depending on the outcome and recommendations from the
2012 study as well as the selection of instream flow study sites.
Existing Information and Need for Additional Information
Understanding existing geomorphic conditions, how aquatic habitat changes over a range of
stream flows, and how stable/unstable the geomorphic conditions have been over recent
decades provides a baseline set of information needed to provide a context for predicting the
likely extent and nature of potential changes that will occur due to the Project. Results of this
study will also provide the basis for macro-habitat mapping to support the Instream Flow Study
and will be used in the Ice Processes Study to provide the surface areas of bars likely to
become vegetated in the absence of ice-cover formation.
Methods
New aerial photography obtained in 2012 will be combined with 1980s and other information to
create a digital, spatial representation (i.e., GIS database) of riverine habitat. The result will be a
quantification of the area of the riverine habitat types for three flows conditions for the historical
1980s condition and the current 2012 condition. The results will be presented as riverine habitat
versus area relationships for the Middle River, reaches in the Middle River and individual habitat
study sites. Comparison between the results from the 1980s and 2012 can be made. The
historical information will only be developed for the Reach from RM 98 to RM 150 as the
delineation of habitat in the Devil Canyon section, RM 150 to RM 184, was not performed.
The methods for this study component have been divided into three tasks: aerial photography,
digitize riverine habitat types, and riverine habitat analysis.
Aerial Photography
New (2012) color aerial photography of the Middle River (RM 98 to RM 184) at stream flows
corresponding to those analyzed in the Trihey & Associates study (1985) (stream flow at the
Gold Creek gage [15292000]) will be obtained in order to provide the foundation for the aquatic
habitat and geomorphic mapping the Middle River, as well as to provide a resource for other
studies.
Three sets of aerial photography will be obtained in 2012 at the following approximate
discharges: 23,000 cfs, 12,500 cfs, and 5,100 cfs. (Note: seven sets of aerial photographs were
flown and evaluated in the 1985 study at the stream flows of 5,100 cfs, 7,400 cfs, 10,600 cfs,
12,500 cfs, 16,000 cfs, 18,000 cfs, and 23,000 cfs). If hydrologic conditions will not allow
obtaining the aerials at 5,100 cfs in 2012, the lowest flow for which aerials can be obtained,
either 7,400 cfs or 10,600 cfs, will be substituted.
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Determination of the scale of the aerial photography (i.e., flying elevation) and the digital scan
resolution will be coordinated with AEA’s Spatial Data Contractor, AEA, the Instream Flow Study
Lead, and licensing participants. The Geomorphology Study Lead will coordinate with the
Spatial Data Contractor who will both obtain (fly) the aerial photography and orthorectify the
aerial photography.
The flow record for the previous 10 years at the USGS Gold Creek gage will be reviewed. The
river typically rises from about 2,000 cfs to over 15,000 cfs during the ice break-up period in late
April to mid-May in a matter of a few days. Because of the influence of ice and ice break-up on
water surface elevations during this period, it is unlikely that aerial photographs to make a valid
comparison with the 1980s habitat mapping can be collected in the spring. The river does not
recede to 12,500 cfs until mid-August to mid-September and to 5,100 cfs until sometime in
October. The river is intermittently in the 23,000 cfs range in the June through August
timeframe. For developing the schedule, it is assumed that the orthorectified aerial photographs
for 23,000 cfs will be available in August 1, 2012, aerials for 12,500 cfs will be available by
October 15, 2102, and aerials for 5,100 cfs will be available by November 15, 2012. Analysis of
riverine habitat for flows at which aerials are not obtained in 2012 will need to be completed in
2013/2104. It should be noted that snowfall in the project area for 2012 is close to an all-time
record, and this may influence the timing and magnitude of the discharges this year. If it does
not appear that the Susitna River will recede to 5,100 cfs prior to ice and/or snow cover
becoming a potential issue with the quality of the photographs in the fall, a decision will be made
to obtain aerial photographs for the low-flow discharge in 2012 at either 7,400 cfs or 10,600 cfs.
Digitize Riverine Habitat Types
The Geomorphology Study will coordinate with the Instream Flow Study, the Instream Flow
Riparian Study, Ice Processes Study, and other pertinent studies to identify large-scale (typically
many miles) aerial photography analysis study reaches for the riverine habitat digitizing. For this
initial work, the number of study sites to be analyzed is assumed to not exceed 20 detailed
study sites from the 1980s effort or more than 50 percent of the reach. In addition to
consideration of habitat and geomorphic characteristics of the reach, a visual qualitative side-
by-side comparison of the aerials will be performed to ensure that the selected reaches are also
representative of the level of change that has occurred over the period of comparison. Aerial
photography will be obtained for the entire reach so that additional areas may be digitized in the
future if warranted.
Coordination with AEA’s Spatial Data Contractor to digitize (within the aerial photography
analysis study reaches) the riverine habitat types from RM 98 to RM 150 defined in the 1980s
from hard copy maps as found in the Middle River Assessment Report (Trihey & Associates,
1985) will occur. Each habitat type must be a polygon (without slivers). The habitat types were
classified into the following categories: main channel, side channel, side sloughs, upland
sloughs, and tributary mouths.
Riverine habitat types for the identified study sites will be delineated and digitized from the 2012
aerials at each of the three stream flows used for the 1980s digitizing effort. Sites will include
those identified for the 1980s digitization effort as well as up to six additional sites between RM
150 and RM 184, identified in coordination with the Instream Flow Study, the Riparian Instream
Flow Study, Ice Processes Study, and other pertinent studies. The habitat types will be digitized
from the orthorectified photography using ArcGIS software (each habitat type must be a polygon
without slivers). Riverine habitat will be classified using the same classification categories used
in the Trihey & Associates study (1985) main channel, side channel, side sloughs, upland
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sloughs, and tributary mouths. Note: the digitizing (and associated metadata) will be completed
by Contractor during this study.
Riverine Habitat Analysis
The information developed in the previous task will be used to develop relationships for riverine
habitat versus flow for the specified reaches and habitat study sites. The relationships will be
developed for both 1980s and 2012 aerials. The riverine habitat type surface area versus flow
relationships between the 1980s and current conditions will be compared at both a site and
reach scale to determine if changes in the relationships have occurred. The comparison can
only be performed for a portion of the reach, since the 1980s study did not cover the entire
Middle River.
From RM 98 to RM 150 GIS software will be used to compare the 2012 versus 1980s total
surface area associated with each delineated riverine habitat types at each measured flow. Data
results will be compiled into tables and graphs, as appropriate, to show the difference in
surfaces area of the feature types between 2012 and the 1980s photography and to show the
change in riverine habitat types versus flow. To ensure accurate comparison to the 1980s data
set, not only will the same approximate flows be compared, but the same definitions will be used
for each of the riverine habitat features that are delineated (see above). The lead
geomorphologist will provide training to ensure appropriate application of the habitat definitions.
Since the 34-mile river segment below the proposed Susitna-Watana Dam site (RM 150 to RM
184) was not analyzed in the 1980s, this portion of the river will be a new assessment (2012
photography only) that will not be compared to past studies. However, the methods for
analyzing riverine habitat types over the range of flows will remain the same as for the
downstream reach (23,000 cfs, 12,500 cfs and 5,100 cfs). Because this reach has a high level
of lateral and vertical control, the areas associated with riverine habitat types has likely
experienced little change. Results of the study component Assess Geomorphic Change will
determine whether there has been change in geomorphic features in this portion of the Middle
River.
Habitat features will be compared and contrasted quantitatively and a qualitative assessment
will be made of the similarity of the sites in 2012 compared to the 1980s in order to assess the
stability of the study sites. A decision will also be made as to whether the remaining portions of
the Middle River beyond the original selected study sites analyzed in 2012 will be also be
digitized and analyzed in 2013/2014.
Information Required
The following available existing information will be needed to conduct this study:
• Historical 1980s orthorectified aerial photographs for the Middle River.
• USGS flow record for the past 10 years for the Susitna River at Gold Creek.
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The following additional information will need to be obtained to conduct this study:
• Obtain (fly) 2012 orthorectified aerial photos in the Middle River at 5,100, 12,500, and
23,000 cfs (corresponds to 1980s flow).
• Acquire historical 1980s digitized riverine habitat features from the AEA Spatial Data
Contractor (SDC) for the Middle River for flows of 5,100, 12,500, and 23,000 cfs.
1.3.6.6. Study Component G-1.6: Reconnaissance Level Assessment of Project Effects on
Lower River Channel
The goal of the Reconnaissance Level Assessment of Project Effects on Lower River Channel
study component is to utilize comparison of pre- and post-project flows and sediment transport
conditions to estimate the likelihood for potential post-project channel change in the Lower
River. The study area for this effort is the Lower River from RM 98 to RM 0. This effort will be
conducted in 2012 as part G-S4: Reconnaissance Level Geomorphic and Aquatic Habitat
Assessment of Project Effects on Lower River Channel. The results of this effort will help
determine what additional analysis of Project effects may be warranted in the Lower River for
the 2013/2104 studies.
Existing Information and Need for Additional Information
An analysis of the Lower River reach and how riverine habitat conditions change over a range of
stream flows was performed in the 1980s using aerial photographic analysis (R&M Consultants,
Inc. and Trihey and Associates 1985a). This study evaluated the response of riverine aquatic
habitat to flows in the Lower River reach between the Yentna River confluence (RM 28.5) and
Talkeetna (RM 98) (measured at Sunshine gage RM~84) ranging from 13,900 cfs to 75,200 cfs.
The study also included an evaluation of the morphologic stability of islands and side channels
by comparing aerial photography between 1951 and 1983.
In another study, 13 tributaries to the lower Susitna River were evaluated for access by
spawning salmon under existing and with proposed stream flows for the original hydroelectric
project (Trihey and Associates, 1985b). The study contains information regarding run timing,
mainstem and tributary hydrology, and morphology. Based on the results of this study, it was
concluded that passage for adult salmon was not restricted under natural flow conditions nor
was it expected to become restricted under the proposed Project operations.
The AEA Susitna Water Quality and Sediment Transport Data Gap Analysis Report (URS 2011)
states that “if additional information is collected, the existing information could provide a
reference for evaluating temporal and spatial changes within the various reaches of the Susitna
River.” The gap analysis emphasizes that it is important to determine if the conditions
represented by the data collected in the 1980s are still representative of current conditions, and
that at least a baseline comparison of current and 1980s morphological characteristics in each
of the identified subreaches is required.
Results of this study will provide the initial basis for assessing the potential for changes to the
Lower River reach morphology due to the Project. Additional studies will be planned for 2013-
2014 if the results of this study plan identify a potential for important aquatic habitat and channel
adjustments in response to the Project.
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Issues associated with geomorphic resources in the Lower River reach for which information
appears to be insufficient were identified in the PAD (AEA 2011), including:
• G16: Potential effects of reduced sediment load and changes to sediment transport as a
result of Project operations within the Lower River.
• F19: The degree to which Project operations affect flow regimes, sediment transport,
temperature, water quality that result in changes to seasonal availability and quality of
aquatic habitats, including primary and secondary productivity.
Methods
Stream Flow Assessment
Pre-Project and available post-Project hydrologic data will be compared. This will include a
comparison of the monthly and annual flow duration curves (exceedance pots) and plots/tables
of flows by month (maximum, average, median, minimum) for the Susitna River at the Sunshine
and Susitna Station gaging stations. Additional hydrologic indicators may be used to further
illustrate and quantify the comparison between pre- and post-project stream flows. The pre-
Project data analysis will include the extended record being prepared by the United States
Geological Survey (USGS).
Using the extended record currently being prepared by the USGS, a flood-frequency and flood-
duration analysis for pre- and post-Project annual peak flows will be performed. The flood-
frequency analysis will be performed using standard hydrologic practices and guidelines as
recommended by USGS (1982).
Sediment Transport Assessment
The sediment transport measurements USGS has collected will be used to develop bedload
and suspended load rating curves to facilitate translation of the periodic instantaneous
measurements into yields over longer durations (e.g., monthly, seasonal, and annual). This
information will be used to perform an overall sediment balance for both the suspended
sediment load and the bed load. The development of this information will be performed in Study
G-3: Sediment Supply and Transport Middle and Lower River (see Section 1.3.6.3).
Integrate Sediment Transport and Flow Results into Analytical Framework
Based upon the above analyses, an assessment of anticipated Project effects on the Lower
River channel type and morphology will be developed. Using the data developed for the pre-
and post-Project flood frequency, flood duration, and sediment load, the geomorphic response
of the Susitna River in an analytic framework along the longitudinal profile of the river system
from the three rivers confluence through Lower River reach will be predicted. The analytical
framework developed by Grant et al. (2003) that relies on the dimensionless variables of (1) the
ratio of sediment supply below the dam to that above the dam, and (2) the fractional change in
frequency of sediment transporting flows will be used to predict the nature and magnitude of the
Lower River geomorphic response. Other analytical approaches may be considered to
demonstrate potential for geomorphic adjustments in the river reaches due to the Project.
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Information Required
The following available existing information will be needed to conduct this study:
• Historical suspended sediment and bed load data for the Susitna River.
• Flow records for the Susitna River.
• Characterization of bed material from previous studies.
The following additional information will need to be obtained to conduct this study:
• Suspended and bed load data for the Susitna River at Tsusena Creek and Gold Creek
being performed by the USGS.
• Extended flow record for the Susitna River and gaged tributaries within the study area
being developed by the USGS.
• Extended flow record for the Susitna River and tributaries being developed by the USGS
1.3.6.7. Study Component G-1.7: Riverine Habitat Area Versus Flow Lower River
The objective of the Riverine Habitat Area Versus Flow Lower River study component is to
conduct a reconnaissance level assessment of potential for Project effects associated with the
change in stage to change Lower River riverine habitat. This effort will be conducted in 2012.
Existing Information and Need for Additional Information
An analysis of the Lower River reach and how riverine habitat conditions change over a range of
stream flows was performed in the 1980s using aerial photographic analysis (R&M Consultants,
Inc. and Trihey and Associates 1985a). This study evaluated the response of riverine aquatic
habitat to flows in the Lower River reach between the Yentna River confluence (RM 28.5) and
Talkeetna (RM 98) (measured at Sunshine gage RM~75) ranging from 13,900 cfs to 75,200 cfs.
Results of this study will provide the initial basis for assessing the potential for changes to the
Lower River reach morphology due to the Project. Additional studies will be planned for 2013-
2014 if the results of this study and other studies identify a potential for important aquatic habitat
and channel adjustments in response to the Project.
Methods
This study component is divided into three tasks: Riverine Habitat-Flow Relationship
Assessment, Synthesis of the 1980s Aquatic Habitat Information, and Contingency Analysis to
Compare Wetted Channel Area. The third task is optional and dependent on a determination if
comparison of riverine habitat in the Lower River under pre- and post-Project flows is warranted
for additional flow conditions.
Riverine Habitat-Flow Relationship Assessment
A tabular and graphical comparison of the change in water surface elevations associated with
the results of the pre- and post-Project stream flow assessment (above) will be developed using
the stage-discharge relationships (rating curves) for the Sunshine and Susitna Station gaging
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stations. This comparison will include monthly and annual stage duration curves (exceedance
plots) and plots/tables of stage by month (maximum, average, median, minimum). Additional
parameters to describe and compare the pre- and post-Project water surface elevations may be
performed. A graphical plot of a representative cross section at each gaging station will be
developed with a summary of the changes in stage (water surface elevation) for the two flow
regimes. If possible, the location of the active channel and the floodplain will also be identified
on the cross section.
The availability of USGS winter gage data with respect to discharge and ice elevation/thickness
will be investigated. Coordination with the WR-S2: Documentation of Susitna River Ice Breakup
and Formation Study will occur to obtain information on ice elevation/thickness, as appropriate.
The potential need for an analysis of discharge effects on ice elevation will be identified and
conducted, if feasible.
Synthesis of the 1980s Aquatic Habitat Information
A synthesis/summary of the 1980s Response of Aquatic Habitat Surface Area to Mainstem
Discharge Relationships in the Yentna to Talkeetna Reach of the Susitna River (R&M
Consultants, Inc. and Trihey & Associates 1985a) will be provided. A synthesis/summary of the
Assessment of Access by Spawning Salmon into Tributaries of the Lower Susitna River (R&M
Consultants, Inc. and Trihey & Associates, 1985b) will also be provided. Data will be
summarized with respect to the anticipated pre- and post-Project flow changes, where
applicable (see Stream Flow Assessment section above).
Site Selection and Stability Assessment
Up to eight sites in the Lower River will be selected from the Yentna to Talkeetna reach map
book (R&M Consultants, Inc. and Trihey and Associates 1985a) at the ~36,600 cfs flow at
Sunshine Gage to study in 2012. These sites will be selected in coordination with the Instream
Flow Study, the Instream Flow Riparian Study, the Ice Processes Study and the stakeholders.
A side-by-side comparison of the sites using the 1983 36,600 cfs aerials and the most
appropriate current aerials or satellite imagery will be performed to qualitatively assess site
stability. Sites which have been substantially reworked by the Susitna River since the 1980s will
not be selected for comparison of riverine habitat in the 1980s versus the present. Only sites
that have been relatively stable during the period will be selected.
Aerial Photography Analysis, Riverine Habitat Study Sites (RM 28 to RM 98)
Using GIS and the September 6, 1983 aerials for the 36,600 cfs flow, mainstem and side
channel riverine habitat will be digitized from the 1985 map book (R&M Consultants, Inc. and
Trihey and Associates 1985a) for the selected sites. Each area associated with a habitat type
will be a polygon (without slivers). To provide a comparison with current conditions, either
recent satellite imagery at a flow similar to 36,600 cfs or aerials obtained in 2012 (if appropriate
satellite imagery is not available) will be used to delineate the current wetted areas within the
riverine and side-channel habitats for the selected sites.
The difference in wetted surface area of the main channel and side-channel riverine habitats (as
defined in R&M Consultants, Inc. and Trihey & Associates 1985a ) will be compared between
the 1983 and current conditions. The areas of the riverine habitat types, along with the
Geomorphic Assessment of Channel Change subtask (see below) will be compared and
contrasted quantitatively and a qualitative assessment will be made of the similarity of the 1980s
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sites compared to the 2012 sites. The assessment of site stability will help determine the
applicability of Lower River riverine habitat information developed in the 1980s to supplement
information being developed in the current Project studies.
Optional: Additional Aerial Photography Analysis, Riverine Habitat Study Sites (RM 28 to RM
98)
Based on the results of the comparison of riverine habitat areas at the selected study sites for
the Lower River and results of the Geomorphic Assessment of Channel Change subtask (see
below), a determination of whether to perform a similar effort and comparison for up to two
additional discharges will be made (discharges corresponding to the analysis of wetted habitat
areas in the Lower River include 75,200 cfs, 59,100 cfs, 36,600 cfs, 21,100 cfs and 13,900 cfs).
This decision will be made in coordination with the Instream Flow Study, Instream Flow Riparian
Study, Ice Processes Study, Fish Study and stakeholders. If the decision is made to analyze
riverine habitat at two additional discharges, the flows will be selected and the associated
habitat areas digitized from the 1985 map book. Satellite imagery at similar discharges or new
aerial photographs will be obtained (if appropriate satellite imagery is not available). The
riverine habitat types will be delineated and digitized on these images to represent the current
condition. The difference in wetted surface area of the main channel and side channel riverine
habitats will be compared between the 1983 and current conditions for the two additional
discharges.
Information Required
The following available existing information will be needed to conduct this study:
• Historical 1980s orthorectified aerial photographs for the Lower River.
• USGS flow record for the Sunshine and Susitna Station gages including measurement
notes, rating curves, stage shifts, cross sections, and information on ice thickness.
The following additional information will need to be obtained to conduct this study:
• Results of study component G-1.4 Assess Geomorphic Change Middle and Lower
Rivers
1.3.6.8. Study Component G-1.8: Reservoir Geomorphology
The goal of the Reservoir Geomorphology study component is to characterize changes resulting
from conversion of the channel and portions of the river valley to a reservoir. The study area
extends from Susitna-Watana Dam (RM 184) upstream to include the reservoir inundation zone
and the portion of the river potentially affected by backwater and delta formation in the river
which is currently assumed to correspond to approximately 5 miles above the reservoir
maximum pool (≈RM 238). Specific objectives of this study component include:
• Estimate reservoir sediment trap efficiency and reservoir longevity.
• Estimate the Susitna River and inflow tributary delta formation with respect to potential
effects on upstream fish passage.
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Existing Information and Need for Additional Information
The construction and operation of the proposed Susitna-Watana Project will impound a
reservoir for approximately 39 miles upstream from the dam. The reservoir will trap coarse and
much of the fine sediment load of the upstream Susitna River that enters the impoundment.
The coarse sediment load that enters the reservoir will form a delta where the river enters the
reservoir. This material will be re-worked as the reservoir elevation fluctuates seasonally.
Similar to the situation that is expected to occur where the Susitna River enters Watana
Reservoir, sediment deposition is expected to occur where tributaries enter the reservoir. The
amount and distribution of sediment deposition may impact the connectivity between the
reservoir and the tributary channels. The formation of deltas may lead to flows conditions that
do not permit upstream fish passage. The reviewed information does not contain data
describing the annual loads and the gradations of the sediment that could be transported to and
deposited at the mouth of tributaries that enter the reservoir, and therefore this is a data gap.
Operation of the Project would result in seasonal and daily water level fluctuations in the
Watana Reservoir, which will result in beach formation and erosion and/or mass wasting of soils
within the impoundment. The results of the erosion potential portion of this study will provide
information on the extent of these processes and the potential for any alterations to project
operations or erosion control measures to reduce erosion and mass wasting.
Methods
The methods are divided into three areas: reservoir trap efficiency and sediment accumulation
rates, delta formation and reservoir erosion.
Reservoir Trap Efficiency and Sediment Accumulation Rates
Inflowing sediment loads will be determined by integrating the extended hydrologic record for
the Susitna River against the bed load and suspended load equations developed for the Susitna
River at Tsusena Creek. Due to the short record at this station, use of the information collected
at Vee Canyon and the bed load and suspended load data collected at Gold Creek to further
refine Tsusena sediment rating curves will be used. The methods described in Empirically
Characterize Susitna River Sediment Supply and Transport will be used to develop the
incoming sediment load.
Methods of calculating trapping efficiency to be considered include Churchill (1948), Brune
(1953), and Einstein (1965). These methods will provide a basis for estimating the amounts of
various size fractions that either pass through or are trapped in the proposed reservoir. Due to
the storage capacity of the proposed reservoir, it is reasonable to assume that all sands and
coarser size fractions delivered to the reservoir will be trapped. When applied over a long-term
horizon, the amount of trapped sediment, coupled with estimates of consolidation (Miller 1953,
Lara and Pemberton 1965), can be used to evaluate the impacts of sedimentation on reservoir
storage capacity.
Delta Formation
While the USGS measurements in Study G-S1 target three locations along the Susitna River,
there will be need for sediment transport estimates at additional locations, including ungaged
tributaries. Ungaged tributaries that may require study will be identified in coordination with the
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Fish Studies. In these locations, reconnaissance will be performed to characterize the sediment
transport regime, and to identify appropriate methods of calculating yields. For example, in
cases where bed material delivery to the proposed reservoir could produce deltas with the
potential to affect upstream fish migration, surveys of tributary channel geometry and gradations
based on bed material samples can be coupled with selected bed material transport functions to
calculate sediment yield rating curves. Long-term flow hydrograph synthesized for the ungaged
tributaries will be needed from other studies for each of the selected tributaries to calculate
sediment yields. Alternate approaches to quantifying sediment yield, such as previous studies
of regional sediment yields (Guymon 1974), may also be considered. The yield and the
topography in the area of the expected delta will provide a basis for characterizing how Project
operations affect the formation of deltas. Specifically the physical constraints imposed by
Project operations on the topset and foreset slopes of the deltas can be incorporated to simulate
growth and development of deltas (USBR 1987, Morris and Fan 1998).
Reservoir Erosion
Erosion and mass wasting potential will be assessed within the reservoir fluctuation zone and
along the shoreline for 100 vertical feet from full pool elevation. The following potential erosion
processes will be evaluated:
• Mass wasting.
• Surface erosion from sheetwash.
• Wave erosion (wind and boat wakes if motorized boat recreation is permitted).
• Solifluction, freeze-thaw, and melting of permafrost.
• Beach/bank development at full pool.
• Erosion by ice movement on the reservoir surface.
The following spatial data will be collected, either from existing data sources or through field
mapping:
• Topography (LiDAR).
• Geo-rectified aerial photography.
• Geologic and soil mapping; soil properties of interest include texture, depth, permafrost
presence/absence, infiltration capacity, cohesion. Existing mass wasting features will
also be mapped on recent (2011) aerial photographs for comparison with 1982 studies.
• Vegetation mapping.
In addition, the following information will be obtained from other resource studies:
• Expected reservoir surface elevation fluctuations (seasonal, daily, maximum hourly
lowering rate).
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• Expected motorized watercraft recreational use data.
• Daily air temperature (maximum/minimum) and wind (speed, direction) data.
• Expected ice development and movement within the reservoir
The spatial data will be used to prepare an erosion and mass wasting hazard map of the
reservoir shoreline and inundation area. Areas with similar slope, soil, aspect, and potential
wave fetch will be delineated. Areas above and below the full pool elevation will be mapped
separately.
The erosion potential for representative erosion/mass wasting hazard polygons will be
evaluated as follows:
• Mass wasting – evaluate potential for mass wasting based on slope gradient, soil
properties, and anticipated pore pressures/fluctuations. Possibly use a GIS-based
model such as SHALSTAB.
• Surface erosion from sheetwash – estimate surface erosion potential using WEPP
and/or RUSLE.
• Wave erosion (wind and boat wakes if motorized boat recreation is permitted) – estimate
erosive energy of waves based on methods in Finlayson (2006) and Sherwood (2006).
• Solifluction, freeze-thaw, and melting of permafrost – evaluate potential based on soil
properties, seasonal reservoir water elevations, and daily max/min temperatures.
• Beach/bank development at full pool – use the beach development model in Penner
(Penner 1993, Penner and Boals 2000).
• Erosion by ice movement on the reservoir surface – evaluate potential for ice erosion
based on reservoir elevation and coordination with Ice Processes Study.
Information Required
The following available existing information will be needed to conduct this study:
• Historical aerial photographs.
• Suspended sediment data for the Susitna River at Vee Canyon (RM 223) and Gold
Creek (RM 137).
• Bedload data for the Susitna River at Gold Creek (RM 137).
• Flow records for the Susitna River.
• Topographic mapping including USGS survey quadrangle maps and LiDAR.
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• Reconnaissance-level mapping of surficial geology and permafrost in the Watana
Reservoir area was done from aerial photographs and limited ground surveys during
studies for the original Susitna license (WCC 1982).
• An analysis of the potential for mass wasting was completed (Acres 1982).
The following additional information will need to be obtained to conduct this study:
• Suspended and bed load data for the Susitna River at Tsusena Creek being performed
by the USGS.
• Extended flow record for the Susitna River and gaged tributaries within the study area
being developed by the USGS.
• Estimated flows for the ungaged tributaries within the study area.
• Estimation of upstream mainstem sediment loads by size fractions.
• Estimation of tributary bed load supply.
• Field observations of the mainstem and tributary confluence areas made during a site
reconnaissance.
• Extended flow record for the Susitna River and tributaries being developed by the
USGS.
• Vegetation mapping.
• Expected reservoir surface elevation fluctuations (seasonal, daily, maximum hourly
lowering rate).
• Expected motorized watercraft recreational use data.
• Daily air temperature (maximum/minimum) and wind (speed, direction) data.
• Expected ice development and movement within the reservoir.
1.3.6.9. Study Component G-1.9: Large Woody Debris
The goal of the Large Woody Debris study component is to assess the potential for project
construction and operations to affect the input, transport, and storage of large woody debris in
the Susitna River. Specific objectives include:
• Evaluate large woody debris recruitment in the Middle and Lower River channels
(including upstream of Watana Reservoir).
• Characterize the presence, extent, and function of large woody debris downstream of
Susitna-Watana Dam.
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• Estimate the amount of large woody debris that will be captured in the reservoir and
potential downstream effects of project operation.
The study area for the Large Woody Debris Study includes the Susitna River from the mouth to
the confluence with the Maclaren River.
Existing Information and Need for Additional Information
The role of large woody debris in the development of channel morphology and aquatic habitat
has been widely studied in meandering and anastomosing channels. Large wood and wood
jams can create pool habitat, affect mid-channel island and bar development, create and
maintain anastomosing channel patterns and side channels (Abbe and Montgomery 1996 and
2003, Fetherston et al. 1995, Montgomery et al. 2003, Dudley et al. 1998). In addition, large
wood can provide cover and holding habitat for fish and help create habitat and hydraulic
diversity (summary in Durst and Ferguson 2000). Despite the wealth of large woody debris
research, little is known of the role of large woody debris in the morphology and aquatic biology
of braided, glacial rivers. Large woody debris likely plays an important role in island formation
and stabilization, as well as side channel and slough avulsion and bank erosion. Construction
and operation of the Susitna-Watana project has the potential to change the input, transport,
stability, and storage of large woody debris downstream of Susitna-Watana Dam by changes to
the flow regime, ice processes and riparian stand development, and interruption of wood
transport through the reservoir. An assessment of the source, transport, and storage of large
woody debris in the Susitna River and the role of large woody debris in channel form and
aquatic habitat is needed to assess the magnitude of these effects. Construction and operation
of the Susitna-Watana Project will likely alter large woody debris input and transport
downstream of Susitna-Watana Dam. An assessment of the source, transport, and storage of
large woody debris in the Susitna River and the role of large woody debris in channel form and
aquatic habitat would provide data on the current status of large wood in the river which, in
conjunction with data from the studies of hydrology, geomorphology, riparian and aquatic
habitat, and ice processes, would be used to determine the potential effects of project operation
on large wood resources. The information can also be used to determine appropriate PM&E
measures such as a large woody debris management plan and handling of wood that
accumulates in the reservoir.
Methods
Available recent and historic high-resolution aerial photography will be used to assess large
woody debris characteristics in the Susitna River between the mouth and the Maclaren River. It
is anticipated that large woody debris input, transport, and storage characteristics will vary along
the length of the river; four reaches have been initially delineated with distinct characteristics:
downstream of the 3 rivers junction; between the 3 rivers junction and Devil’s Canyon, Devil’s
Canyon, and upstream of Devil’s Canyon. Large woody debris will be inventoried to the extent
practical on the aerial photographs. Information regarding the sources of large woody debris,
locations of large woody debris in the river channel, and the relationship of large woody debris
to channel or slough habitat will be collected and correlated with bank erosion and riparian
vegetation mapping from the geomorphology mapping and riparian habitat mapping studies to
identify potential recruitment methods (Mouw 2011, Ott et al. 2001). If adequate historic aerial
photographs are available, the stability of large wood pieces and jams between photo years will
be assessed in representative areas of the river.
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It is likely that not all wood will be able to be identified on the aerial photographs. As a
supplement to large woody information obtained from aerial photographs, a reconnaissance
assessment of large woody debris in the Susitna River will be made in coordination with
aquatic/riparian habitat mapping in the summer of 2012. This assessment will be useful to
direct more detailed field data collection in representative portions of the study area are during
the 2013-2014 study seasons. The objective of the 2013-2014 field studies will be to verify the
large wood data collected from the aerial photographs and to provide more detailed field
information on large wood input and storage. It is anticipated that the following types of large
woody debris data will be collected as part of a field inventory of large wood in 2013-2014:
• GPS location (to correlate with geomorphology, aquatic, and riparian habitat mapping
from other studies).
• Wood size class (based on diameter, length).
• Root wad status of attachment.
• Single piece, accumulation, or log jam.
• Decay class.
• Species if known.
• Input mechanism if known (windthrow, bank erosion, ice processes, etc.).
• Channel location (side; mid channel; side channel inlet, middle, outlet; associated with
island or bar – and where on island or bar, etc.).
• In wetted or bankfull channel or potential input (leaning over bankfull channel).
• Function (scour pool, bar forming, island forming, side channel inlet protection, bank
protection, aquatic cover, etc.).
• For log accumulations and jams: key piece size.
The aerial photograph and field inventories of large wood will be used to determine large wood
input processes and source areas, large wood transport and storage, and how large wood is
functioning in the Susitna River to influence geomorphic, riparian, and aquatic habitat
processes. Based on estimated large wood input and transport upstream of the Susitna-
Watana Dam site, the potential effects of reservoir operation on trapping upstream large wood
will be assessed. In addition, the potential for operation of the project to alter large wood input
and transport downstream of the dam site will be analyzed. The analysis will require
coordination with the geomorphology, sediment transport, ice processes, riparian habitat,
aquatic habitat, and instream flow studies.
The results of the large woody debris study will be used to determine appropriate PM&E
measures for the project and a large wood management plan.
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1.3.6.10. Study Component G-1.10: Geomorphology of Stream Crossings along Transmission
Lines and Access Alignments
The goal of the Geomorphology of Stream Crossings along Transmission Lines and Access
Alignments study is to characterize the existing geomorphic conditions at stream crossings
along access road/transmission line alignments and to determine potential geomorphic changes
resulting from construction, operation, and maintenance of the roads and stream crossing
structures.
Existing Information and Need for Additional Information
Development of the Susitna-Watana Dam would require road and/or rail transportation from
existing roads (either the George Parks Highway or the Denali Highway) to the dam site as well
as a transmission line from the powerhouse to an existing transmission line intertie.
Construction, use, and maintenance of the roads and transmission lines have the potential to
affect stream geomorphology if stream crossing structures constrict flow or alter transport of
sediment or large wood, or if sediment is delivered to the streams from erosion of the road
prism.
Three different access/transmission alignments are currently being considered. The alignments
are designated as Denali, Chulitna and Gold Creek. The ADOT&PF evaluated potential access
corridors, including the Denali and Chulitna River options (HDR 2011). The analysis considered
the number of stream crossings as one criterion, among many others, during the screening
process, but a detailed analysis of the geomorphic effects of the stream crossings on bedload
transport, large woody debris, and channel functions was not conducted.
A road in the Denali Alignment would cross Seattle Creek and Brushkana Creek, two major
drainages within the Nenana River watershed and Deadman Creek within the Susitna River
watershed. A road in this alignment would require a total of 15 stream crossings. A Gold Creek
access alignment would require 23 stream crossings. The major streams that would be crossed
by the Gold Creek access alignment include Gold Creek, Fog Creek, and Cheechako Creek.
Smaller streams crossed include tributaries to Prairee and Jack Long creeks, and a number of
unnamed tributaries to the Susitna River. A road in the Chulitna alignment would require about
30 stream crossings including the Indian River, and Thoroughfare, Portage, Devils, Tsusena,
and Deadman creeks. The Chulitna River alignment would also cross 10 small, unnamed
tributaries of Portage Creek, three small tributaries of Devils Creek, seven smaller tributaries to
the upper Susitna River and two tributaries of Tsusena Creek.
Construction of project access roads and transmission lines would require stream crossing
structures. Stream crossing structures have the potential to affect stream geomorphology by:
• Altering hydraulics upstream and downstream of the crossing if flow is constricted. This
can lead to sediment deposition upstream of the crossing or bank erosion/channel
incision downstream.
• Altering migration of streams across a floodplain.
• Inhibiting movement of large woody debris.
• Increasing sediment delivered to a stream if road erosion is occurring near stream
crossings.
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Data collected during this study would help to determine the potential for proposed stream
crossings to affect stream hydraulics, morphology, sediment transport, and large woody debris
transport. This analysis would also provide data needed for design of appropriate stream
crossing structures and PM&E measures to minimize effects.
Methods
The following data would be obtained, either from existing sources or from field studies:
• LiDAR or topography at stream crossings.
• Stream characteristics – gradient, substrate size, wetted and bankfull width/depth, large
woody debris, Rosgen channel type, and bank erosion would be measured or evaluated
for a minimum of 100 feet upstream and downstream of each proposed crossing.
• Crossing design – information on the culvert or bridge characteristics planned at each
crossing would be obtained from project engineering designs (HDR 2011).
• Road design – information on the road prism in the vicinity of stream crossings would be
obtained from project engineering designs, including surfacing, gradient, expected traffic
levels, and road prism width.
The potential effects of stream crossings on geomorphology will be analyzed based on stream
characteristics and the proposed design of crossing structures.
• Channel morphology, sediment dynamics – the hydraulic characteristics and bedload
transport capacity of existing channel and of proposed crossing structures will be
computed and compared. Guidelines in the existing stream crossing design MOU will be
considered (ADOT&PF 2001).
• Channel migration zone – the existing channel migration zone will be mapped for alluvial
channels that show evidence of migration across the floodplain. Effects of proposed
crossing structures on channel migration will be analyzed.
• Large woody debris transport- potential effects on large woody debris transport will be
evaluated based on channel crossing type and width. The potential for culvert plugging
will be ranked based on observed large woody debris size in the stream and proposed
culvert size.
• Erosion and delivery of road sediment to stream – erosion from any unpaved roads will
be estimated using the WEPP or SEDMODL algorithms.
1.3.7. Describe considerations of level of effort and cost, as applicable, and why any
proposed alternative studies would not be sufficient to meet the stated
information needs
Specific details for the study components will be determined when Study Plans are further
developed. Initial planning level estimates of the costs to perform the components of the
Geomorphology study are provided in the table below along with the expected quarter the study
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will be completed. The total effort for the Geomorphology Study, excluding Sediment Data
Collection, is estimated to cost between approximately $0.8 million and $1.3 million.
Study Component Estimated Cost Range Estimated Completion
Geomorphic River Segment Delineation $60k to $80k Summer 2012
Sediment Data Collection USGS will provide Summer 2012
Sediment Supply and Transport Assessment $60k to $90k Sum 2012/ Fall 20132
Geomorphic Change Middle and Lower River $80k to $120k1 Summer 2012
Riverine Habitat Middle River $200k to $300k1 Winter 2012
Recon Assessment Lower River Project Effects $40k to $60k Summer 2012
Riverine Habitat Lower River $100k to $150k1 Winter 2012
Reservoir Geomorphology $140k to $180k Spring 2014
Large Woody Debris $80k to $120k Summer 2014
Geomorphology of Stream Crossings $80k to $140k Summer 2014
1 Includes acquisition of orthorectified aerial imagery 2 Lower River sediment supply and transport to be completed in summer 2012, remainder of study
component to be completed by fall 2013
The USGS is developing a cost estimate for the 2012 portion of the study. The data collection
effort will be conducted in the late spring and summer of 2012. Provisional results of the data
collection effort will be delivered to the other studies as soon as they are available from the lab
during fall of 2012. Suspended and bedload data, including calculation of sediment transport
ratings and daily loads, will be compiled in a technical memorandum delivered to AEA during
FFY 2013, and as early as March, 2013, if possible.
Performing the digitization of the 2012 aerial photography is dependent on the AEA SDC being
able to fly the aerials at the appropriate discharge. The only portions of this effort that can be
completed in 2012 are for flows for which the current aerial photographs are supplied in
orthorectified format by November 15, 2012. The most critical discharge in regard to schedule
is the 5,100 cfs since there are years when the Susitna at Gold Creek does not fall to this level
until late October or early November.
1.3.8. Literature Cited
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formation in large rivers. Regulated Rivers: Research & Management 12, 201–221.
Abbe, T.B., Montgomery, D.R. 2003. Patterns and processes of wood debris accumulation in
the Queets River basin, Washington. Geomorphology 51, 81–107.
ADFG/ADOT&PF. 2001. Memorandum of agreement between Alaska Department of Fish and
Game and Alaska Department of Transportation and Public Facilities for the design,
permitting, and construction of culverts for fish passage. Signed 8/7/2001.
Alaska Energy Authority (AEA). 2011. Pre-Application Document: Susitna-Watana Hydroelectric
Project FERC Project No. 14241. December 2011. Prepared for the Federal Energy
Regulatory Commission by the Alaska Energy Authority, Anchorage, Alaska.
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Andrews, E.D., 1980. Effective and Bankfull Discharges of Streams in the Yampa River Basin,
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Andrews, E.D., 1986. Downstream Effects of Flaming Gorge Reservoir on the Green River,
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Andrews, E.D. and Nankervis, J.M., 1995. Effective discharge and the design of channel
maintenance flows for gravel-bed rivers. American Geophysical Union, v. 89, pp. 151-
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Benson, M.A. and Thomas, D.M., 1966. A definition of dominant discharge. Bulletin of the
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2000. Effective Discharge Calculation: A Practical Guide. Coastal and Hydraulics
Laboratory, U.S. Army Engineer Research and Development Center, Vicksburg,
Mississippi, ERDC/CHL TR-00-15, August.
Brice, J.C., 1981. Stability of relocated stream channels. Federal Highway Commission Report
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Brune, G.M. 1953. Trap efficiency of reservoirs. Transactions of the American Geophysical
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Buffington, J. M., and D. R. Montgomery (1997), A systematic analysis of eight decades of
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Churchill, M.A. 1948. Discussion of “Analysis and Use of Reservoir Sedimentation Data” by
L.C. Gottschalk. Proceedings of the Federal Interagency Sedimentation Conference,
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Cohn, T.A., and E.J. Gilroy. 1991. Estimating Loads from Periodic Records. U.S. Geological
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Collins, B.D., D.R. Montgomery, K.L. Fetherston, and T.B. Abbe. 2012. The floodplain large-
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Duan, N. 1983. Smearing Estimate: A Nonparametric Retransformation Method. Journal of the
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for the Region III Forest Practices Riparian Management Committee. Compiled for
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Einstein, H.A. 1965. Final Report Spawning Grounds. University of California Hydrologic
Engineering Laboratory. 16 pages, 2 tables, 10 figures.
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riparian forest development in montane river networks of the Pacific Northwest.
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Finlayson, D.P., 2006. The Geomorphology of Puget Sound Beaches. Ph.D. Dissertation,
University of Washington, Seattle, WA. 216pp. Available at
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Guymon, G.L. 1974. Regional Sediment Yield Analysis of Alaska Streams. ASCE Journal of
the Hydraulics Division, Vol. 100(1). 41 – 51.
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the Alaska Department of Transportation and Public Facilities. November 29, 2011.
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Montgomery, D.R. and Buffington, J.M., 1997. Channel-reach morphology in mountain
drainage basins. Geological Survey America, Bulletin, v. 109, pp. 596-611.
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Management of Wood in World Rivers. American Fisheries Society, Bethesda, MD, pp.
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gravel-bed streams, J. Hydraul. Div. Am. Soc. Civ. Eng., 108(HY4), 544– 571.
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Around Lakes and Reservoirs, Canadian Dam Association, pp 75 – 84.
Penner, L. A., 1993. Shore Erosion and Slumping on Western Canadian Lakes and Reservoirs,
A Methodology for Estimating Future Bank Recession Rates, Environment Canada,
Monitoring Operations Division.
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of dominant discharge. Journal of Hydrology, v. 29, pp. 51-75.
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Pickup, G., 1976. Adjustment of stream channel shape to hydrologic regime. Journal of
Hydrology, v. 30, pp. 365-373.
R&M Consultants, Inc. and Trihey & Associates. 1985a. Response of Aquatic Habitat Surface
Areas to Mainstem Discharge in the Yentna to Talkeetna Reach of the Susitna River.
Prepared under contract to Harza-Ebasco, for Alaska Power Authority, document No.
2774, June.
R&M Consultants, Inc. and Trihey & Associates. 1985b. Assessment of access by spawning
salmon into tributaries of the Lower Susitna River. Prepared under contract to Harza-
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