Surface Water
Conveyance
In nature, surface water moves along a network of waterways:
brooks, creeks, streams, and rivers. Generally speaking, these
systems consist of a channel, banks, a flood way, and a flood
plain. Water from rain events, snow and ice melt, and natural
springs is collected and conveyed naturally according to the
laws of hydrodynamics. Without human intervention, these
systems can work to efficiently move water across the
landscape. In addition, natural water conveyance systems
provide additional ecosystem service benefits such as
improved water quality, sediment conveyance, floodwater
storage, and habitat.
Increasing attention has been turned to placing all water
conveyance decisions within a watershed context as localized
flood control measures, such as concrete channelization in a
neighborhood, can result in increased flood risk downstream.
NHMP Benefits
Surface water conveyance can help to mitigate the
number and severity of localized and downstream flood
events.
Minimizing and slowing overland stormwater flow by sup-
porting soil and vegetation infiltration and roughness reduc-
es the speed and rate of stormwater delivered to water-
ways and stormwater infrastructure.
Decreasing the amount of runoff that reaches streams can
keep stream flow rates within the stream channels convey-
ance capacity and prevent downstream flood events.
Waterways are more resilient alternatives to hardened in-
frastructure such as pipes and culverts that are more sus-
ceptible to failure during flood and earthquake events.
Reducing the watershed's susceptibility to flood events is
goal of Gl and LID best management practices for water
conveyance.
Urban stream daylighting, the practice of uncovering some or
all of a previously covered waterway, can increase the water-
shed's resilience to flood events.
Channel stabilization, channel enlargement, bank protection,
and river diversion techniques are Gl approaches to preserv-
ing and enhancing stream channel conveyance.
There are many LID tools for reducing urban impacts on wa-
ter conveyance to reduce a stream channel's risk of flooding
such as water conveyance swales, rain gardens, soakage
trenches, vegetated rooftops, rain barrels, permeable pave-
ment, and removal of impervious surfaces.
Possible NHMP action items to support the ecosystem
service of surface water conveyance include:
Increasing vegetation along stream channels to reduce sedi-
mentation, mitigate bank erosion, and maintain channel
width and conveyance capacity.
Increase pervious surfaces and reduce impervious surfaces
in areas of developed areas to reduce runoff and increase
infiltration and absorption.
Plan Gl projects in concentrated conveyance areas to de-
tain, or slow the flow of water into Bear Creek and Ash-
land Creek during periods of heavy precipitation and peak
flow.
D UNIVERSITY OF OREGON CSC ฎ fema (S
G l/LID Best Management
NHMP Actions
Legend
Creeks
Culverts
Constructed Channels
Pipes
I I Ashland UGB
TAKEAWAY
Ashland is a hillside community
located in the upper portion of
the Ashland Creek Watershed.
Numerous first to third order
streams convey water from
above, and through, Ashland to
Bear Creek at the base of the
watershed. LID techniques may
be used to mitigate localized
flooding within the city, while Gl
approaches along Bear Creek
would have greater flood
reduction benefits to
downstream communities.
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Stormwater
Infiltration
In predevelopment conditions, a significant portion of
precipitation is intercepted by vegetation and evaporated
while the limited rainfall that does reach the ground can be
absorbed by pervious soils. Without human caused soil
compaction, impervious surface coverage, and reduction of
vegetation, stormwater can infiltrate resulting in minimal
surface runoff and increased groundwater recharge,
Stormwater infiltration is important for sustaining a healthy
water table that that sustains streainflow during summer and
fall months and after periods of low precipitation. Infiltration
further provides natural filtration that improves water quality.
While soil infiltration rates vary based on soil type and
topography, in general human development decreases
stormwater infiltration across a watershed due to an increase
in impervious surfaces and compaction of porous soils.
NHMP Benefits
Stormwater infiltration can help to mitigate the num-
ber and severity of localized and downstream flood
events while also contributing to a sustained water sup-
ply during periods of drought.
By infiltrating stormwater, overland flow is reduced and the
speed and rate of stormwater delivered to waterways and
stormwater infrastructure is minimized.
A reduction in runoff above steep slopes can help to pre-
vent the saturation of soils that is a primary factor in trig-
gering landslides.
Reducing overall runoff by increasing stormwater infiltration
in a watershed can mitigate flash flooding during high vol-
ume rain events.
Reducing the watershed's susceptibility to flood events is
the goal of Gl and LID best management practices for
stormwater infiltration.
Amended soils, urban trees, rain gardens, bioswales, storm-
water planters, infiltration basins, and pervious pavers, pave-
ment, and asphalt are all LID best management practices sup-
porting stormwater infiltration.
Wetland restoration, constructed wetlands, and dry and wet
detention basins are all Gl best management practices for
supporting stormwater infiltration.
To minimize the impact of development, new development
can be required to maintain stormwater infiltration and not
increase the overland flow from the site.
Possible NHMP action items to support the ecosystem
service of stormwater infiltration include:
The use of LID best management practices (BMPs) within
the city right of way can reduce runoff from city streets and
parking lots. Retrofitting LID BMPs can be accomplished
during routine street maintenance or as part of a targeted
"green streets" program.
Incentives could be used to encourage private landowners
to implement LID BMPs that increase stormwater infiltra-
tion.
Gl projects can be designed to increase infiltration and re-
duce stormwater runoff into Ashland and Bear Creek.
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G l/LID Best Management
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Legend
Impervious Surfaces
~ Ashland UGB
TAKEAWAY
Ashland is a largely developed
within its urban growth
boundary (UGB) and there has a
been a significant reduction in
infiltration resulting in an
increased risk of flooding. Gl and
LID best management practices
can be used to increase
infiltration and reduce localized
flooding within Ashland. A
reduction in runoff that reaches
Bear Creek will further help to
mitigate the number and severity
of downstream floods.
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Sediment
Retention
In natural systems, sediment retention occurs via vegetated
land and streambanks that control both the rate of sediment
creation and slow surface water flow allowing sediment to
settle out prior to entering stream channels. Development can
disrupt these natural sediment retention systems by removing
vegetative cover and increasing surface flow rates. This can
lead to increased sediment deposition in stream channels that
can accrue faster than it can be flushed down stream. Large
amounts of sediment build up, or channel deposits, can cause
stream channels to expand or branch away from the buildup,
decreasing their water conveyance capacity and increasing
channel flood risk. Similarly, increased sedimentation impacts
the water quality of streams, lowering habit quality of stream
segments. In addition, sediment that builds up behind dams
can cause a dam breech during a flood event, aggregating the
extent of flood damage.
Legend
Asniand
Developed. Low Intensity
Developed, Medium Intensity
Developed, High Intensity
Barren Land
Deciduous Forest
Evergreen Forest
Mixed Forest
~ Shrub/Scrub
| Herbaceuous
Hay/Pasture
Cultivated Crops
| Woody Wetlands
Emergent Herbaceuous Wetlands
ฆI
TAKEAWAY
Ashland has a large number of
surface water conveyance
structures, both natural and
built, that are susceptible to
sedimentation that can increase
flood risk. Gl and LID best
management practices can be
used to decrease sediment
creation and to prevent
sediment from reaching the
surface water conveyances
structures. Maintaining sediment
further protects stabilizing steep
slope vegetation.
DRAFT
NHMP Benefits
Sediment retention can help to mitigate the number
and severity of localized and downstream flood events.
By minimizing the rate that sediment is created and deposit-
ed, the capacity of waterways to transport stormwater is
maintained and the risk of flooding is not increased.
Maintaining vegetative cover on steep slopes prevents the
release of sediment in landslide events.
Preventing the buildup of sediment behind dams maintains
the dam capacity and mitigates flood effects and risks.
Sediment accrual in hardened and piped water infrastruc-
ture decreases the stormwater infrastructure capacity and
can contribute to localized flooding.
Gl/LID Best Management
Reducing the watershed's susceptibility to flood events is
goal of Gl and LID best management practices for sedi-
ment retention.
Soakage trenches, bioswales, vegetated filter strips, and tree
protection and planting are all LID best management practic-
es for increasing sediment retention by decreasing sediment
creation and decreasing surface water flow rates allowing
sediment to fall out prior to reaching surface water convey-
ance structures.
Constructed wetlands, restored and connected floodplains,
and vegetated stream buffers are all Gl best management
practices that can maximize sediment retention and protect
water conveyances systems from sediment buildup.
NHMP Actions
Possible NHMP action items to support the ecosystem
service of sediment retention include:
Continue support for the Ashland Forest All-Lands Resto-
ration (AFAR) project that manages the upper Ashland Wa-
tershed for wildfire mitigation, steep slope stability, and
sediment retention
Increased development and maintenance of vegetative buff-
ers along surface water conveyance channels can protect
steam channels from sediment buildup.
Bioretention facilities can be constructed alongside highly
developed areas to prevent sediment from reaching water
conveyance systems.
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Floodwater
Storage
The capacity of the ecosystem to store water and the extent of
riparian zones for retention of stormwater is a measure of
floodwater storage. Floodwater storage occurs in all locations
that retain stormwater, and the greatest floodwater
ecosystem service is provided by wetlands, particularly
floodplain wetlands. Wetlands and floodplains within and
downstream of urban areas are an effective tools for capturing
the increased volume and rate of surface water runoff and
channeled water from upland impervious surfaces and
buildings. Successful floodwater storage detains and retains
floodwater slowly releasing it as the flood risk decreases.
Localized floodwater storage with dry and wet detention
ponds can provide localized floodwater storage that can
protect against localized flooding in developed areas.
NHMP Benefits
Floodwater storage can help to mitigate the number
and severity of localized and downstream flood events.
Successful floodwater storage strategies protect urbanizing
floodplains and mitigates localized flooding by absorbing
rainfall and keeping water from burdening pipe networks or
causing damage by pooling in streets or basements.
Adequate floodwater storage allows for groundwater re-
charge and the overall regulation of water flows, reducing
instances of flooding.
Floodwater storage sites help to recharge groundwater and
support year-round stream flow that protects against the
effects of drought and contributes to healthy and more fire
resistant vegetation.
Reducing the watershed's susceptibility to flood events is
the goal of Gl and LID best management practices for
floodwater storage.
Rain gardens, infiltration strips, bioswales, stormwater plant-
ers, and soakage trenches are all LID best management prac-
tices that can be applied at the site level to decrease storm-
water runoff that reaches floodwater storages sites.
Dry and wet detention ponds, constructed wetlands, flood-
plain benching, and restored and reconnected floodplains are
all Gl best management practices that can detain, retain, and
slowly release floodwater.
Possible NHMP action items to support the ecosystem
service of floodwater storage include:
Restored and constructed wetlands along Bear and Ashland
Creek in the lower portions of the Ashland city limits can
increase the floodwater storage capacity of the Ashland
Watershed.
Similarly, floodplain benching and restored and reconnected
floodplains along Bear and Ashland Creek can also increase
the floodwater storage capacity of the Ashland Watershed.
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ASHLAND ST
Legend
GI/LID Best Management
NHMP Actions
TAKEAWAY
Ashland currently has two types
of wetland protection zones:
locally significant wetlands and
other possible wetlands. These
areas are currently protected by
buffer zones. The largest wetland
areas are located along Ashland
Creek and Bear Creek. Gl
approaches such as wetland
restoration and floodplain
connections can expand
Ashland's floodwater storage
helping to protect downstream
communities from flooding.
Water Resource Protection Areas
FEATURE GROUP
Wetland Protection Areas
~ WETLAND
~ PW
~ POND
Superceded Wetlands
50 ft Wetland buffer
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Wildfire
Resilience
Wildfire resilience is achieved through a healthy forest
ecosystem, making a healthy forest a valuable ecosystem
service. Fires are a normal occurrence in a healthy forest,
leaving stronger, older, and healthier trees. Natural fire cycles
support animal and plants that are adapted to, or even
require, the effects of fire. The reduction of fire events due to
fire suppression tactics has led to the accumulation of larger
fuel loads from younger and less healthy trees, invasive and
fire prone plants that can outcompete native wildfire resistant
species, and vegetation that has been weakened or killed by
invasive insects or drought.
Wildfire resilient communities help manage risk through the
reduction of fire loads in the watershed, the selection of
drought-tolerant and fire resistant vegetation, landscaping
standards, and defensible space standards.
'lossom View
Estates
17.3 Ac
Thornton
9.8 Ac
Sunnyvtew
W.6 A
Mountain
Meadows
27.5 Ac |
Meadow
Hawk HOA
4 Ac
E3
#FIIME
Wr COMMUNITIES
in Ash land
Strawbei _ .
Lane Meadows
rl'j Granite St
Lithia Creek j
Estates
40.6 Ac
Ravenwood
Place
1.2 Ac
Chautauqua
Trace HOA
11 Ac
Merrill
Circle
3.7 Ac
a
Tres Clay
1 Ac
B irchwogd
Lane
3 Ac
Quail
Wildfire Hazard Zone
Canyon
3 ,9 Ac
Blackberry
Ross Lane
2.8 Ac
8.2 Ac
y- ^eachy Rd
Canyon
Park
Ac
.6 Ac
Lane
38.2 Ac
Tamarack
Place r /
8.1 Ac
The Oaks
of Ashland
^1 Ac
1/
Royal Oaks
Estate
2 Ac
Oak Knoll
Meadows
rfK3I.7Ac
Mountain
Ranch HOA
6.4 Ac
0
TAKEAWAY
Ashland has undertaken
significant efforts to improve
wildfire resilience of the
watershed with the Ashland
Forest All-Lands Restoration
Project (AFAR) and with its 24
recognized Firewise
Communities within the city
limits. Continued expansion of
Ashland's wildfire resilience can
be accomplished with city wide
utilization of Firewise standards,
landscaping, and defensible
space.
DRAFT
NHMP Benefits
Wildfire resilience can decrease the occurrence and
severity of wildfire events and protects vegetation that
stabilized steep slopes and decrease post fire sedimen-
tation of water conveyance systems.
The use of fire resistant vegetation and the creation of de-
fensible space around structures can mitigate the damage to
property from wildfire events.
Managing the greater watershed to reduce the occurrence
of large scale and severe wildfires by reducing the fuel load
with strategic thinning and other active forest management
techniques helps to prevent wildfires from encroaching on
the Urban-Wildland Interface region of Ashland.
Gl/LID Best Management
Decreasing watershed's susceptibility to fire is the goal of
Gl and LID best management practices for wildfire resili-
ence.
Wildfire resilience requires the participation of all, or the
vast majority of land owners, to undertake creation of defen-
sible space and planting of fire resistant landscaping as part of
LID best management practices for increasing wildfire resili-
ence.
Active forest management techniques including thinning, fuel
load reduction, and slope stabilization are Gl best manage-
ment practices for increasing wildfire resilience in the Ash-
land Watershed.
NHMP Actions
Possible NHMP action items to support the ecosystem
service of wildfire resilience include:
Continue support for the Ashland Forest All-Lands Resto-
ration (AFAR) project that manages the upper Ashland Wa-
tershed for wildfire mitigation, steep slope stability, and
sediment retention.
Expand the Wildfire Hazard Zone (WHZ), Development
Standards for Wildfire Lands, and Fuel Break Prohibited
Plant List to cover all of Ashland to increase the overall
communities resiliency to wildfire events.
Continue to expand neighborhood participation and certifi-
cation through the Firewise Communities program to sup-
port wildfire resilient neighborhoods.
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Steep Slope
Stability
Steep slope stability is a valuable ecosystem service for
controlling sedimentation and for decreasing the size and
number of landslides. Landslides occur when heavy rains
dislodge and eventually destabilize the soil on steep slopes.
Landslides can be exacerbated, or even caused by, human
development near steep slopes that decrease slope stability.
Development increases impervious surface cover and during
rain events increases flow, especially if the drainage systems
are insufficient or direct water toward the slopes. When the
soil of steep slopes are saturated, soil can dislodge and cause a
landslide. Therefore, steep slope stability depends greatly on
decreased impacts of development near steep slopes, on the
strength of the slope vegetation and soil, and on effective
stormwater management
NHMP Benefits
Steep slope stability can support sediment retention
and decrease the occurrence and size of landslide
events.
Steep slope stability decreases sedimentation of surface wa-
ter conveyance systems that can lead to increased risk of
flooding.
Vegetation helps to prevents sedimentation by increasing
the soils ability to resist movement and decreases soil satu-
ration with evapotranspiration mitigating the risk of land-
slide events.
Decreasing watershed's susceptibility to landslides is the
goal of Gl and LID best management practices for steep
slope stability
The use of LID best management practices such as amended
soils, urban trees, rain gardens, bioswales, stormwater plant-
ers, infiltration basins, and pervious pavers, pavement, and
asphalt above steep slopes to increase infiltration and de-
crease runoff promotes steep slope stability.
To stabilize steep slopes vegetation and trees can be planted
and maintained at both the site and landscape scale to pro-
tect steep slopes from landslide events.
Possible NHMP action items to support the ecosystem
service of steep slope stability include:
Continue support for the Ashland Forest All-Lands Resto-
ration (AFAR) project that manages the upper Ashland Wa-
tershed for wildfire mitigation, steep slope stability, and
sediment retention.
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ASHLANti ST\
Legend
DRAFT
GI/LID Best Management
Physical and Environmental Constraints
Severe Constraints, slope
~ 0-15
~ 16-25
I I 26-30 (hillside lands)
I I 31-35 (hillside lands)
B > 35 (severe constraints)
Hillside Lands
~
TAKEAWAY
Ashland is a hillside community
with slopes exceeding 35% in the
South-West portion of the city
and within the greater Ashland
Watershed that lies above the
city. Supporting steep slope
stability by minimizing runoff
and stabilizing slopes with
vegetation not only mitigates the
risk of landslides, but also
supports sediment retention and
protects surface water systems
from damage.
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Cultural &
Livability
Services
Landscapes provide aesthetic and recreational features which
promote livability among residents and visitors. These services
can be protected and enhanced as stream and wetland buffers,
parks, open space, trails, or nature preserves. There is often a
strong overlap between landscapes of high cultural value,
landscapes with high ecological value, and landscapes with
existing or potential natural hazard risk reduction benefits.
Ashland's extensive park and trail system supports steep slope
stability, wildfire resiliency, protects surface water conveyance
systems, and provides for floodwater storage that all contribute
to Ashland's natural hazard resiliency.
NHMP Benefits
Landscapes with cultural and livability services can
support numerous ecosystem services that have
natural hazard mitigation benefits.
Surface water conveyance (e.g. stream and trail networks)
Surface water storage (e.g. wetlands, ponds, park fields)
Permanent open space buffers between mapped hazard and
development areas
Create multi-objective, multi-use, trail, pathway, and
evacuation systems
Improve the aesthetic of risk reduction structures and
projects (i.e. green vs. gray infrastructure)
Enhancing the overall resiliency of the Ashland Water-
shed to natural hazards is the goal of Gl and LID best
management practices for cultural and livability services.
Utilize park and open space as a mechanism to preserve
floodplains
Establish flood plain preservation areas within park
boundaries (e.g. Ashland's Vogel Park)
Reduce hardscape
Plant native trees and vegetation
Protect, preserve, or restore wetland functions
Cultural service maintenance techniques
Conserve fast draining soils
Protect trees
Reduce runoff
Possible NHMP action items to support the ecosystem
service of cultural services include:
Include Gl- and LID-based natural hazard mitigation plan-
ning actions as a component of parks and recreation master
planning as was done with the Lithia Parks Master Plan Re-
quest for Proposal (RFP).
Consider hazard objectives in the planned restoration of
the Vogel Creek property.
Expand the Ashland Lawn Replacement program
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LITHIA PARK 19.
HUNTER PARK 20.
CAR FIELD PARK 21.
RAILROAD PARK 22.
YMCA PARK 23.
GARDEN WAY PARK 24.
GLENWOO D PARK 25.
TRIANGLE PARK 26.
CLAY S T PARK 27.
DOG PARK 28.
SI SKI YOU MO UNTA IN PARK 29.
OR EDS ON TODD WOODS 30.
NORTH MOUNTAIN PARK 31.
BEAR CREEK GREENWA Y 32.
HALD S TR AW BERRY PARK 33.
ASHLAND COMMUNITY SKATE PARK 34.
BLUEBIRD PARK 35.
SHERWOOD PARK
OAK KNOLL GOLF COURSE
ASHLAND CREEK PARK
SCENIC PARK
CALLE GUANAJUATO
ASHLAND PONDS
CHI TWO OD PROPER TY
EVERGREEN
ASHLAND GUN CLUB
WESTWOOD PARK
KEENER PROPERTY
GRANITE STREET PROPERTY
BURNSON PROPERTY
LA WRENCE PROPERTY
COTTLE-PHILIPS PROPERTY
LIBERTY STREET ACCESS
RIVERWALK
BRISCOE GEOL OG Y PARK
WIMER
E MAIN.
ASHLAND ST
G l/LID Best Management
NHMP Actions
PARKS PROPERTIES
ฉ
Note:
Some of Ashland's parks
are treated with organic,
non-synthetic pesticides
TAKEAWAY
Ashland is well known for its
parks and trail system. These
provide important cultural and
livability services that enhance
the quality of life for visitors and
residents. Stream and wetland
buffers, parks, open space, trails,
and nature preserves are also
important city controlled assets
for Gl and LID projects that
support numerous ecosystem
services with natural hazard
mitigation benefits.
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Freshwater
Provisioning
The 15,000 acre Ashland Creek Watershed begins on the
slopes of Mt. Ashland and drains into Reeder Reservoir, the
source of the City's municipal water supply. The main sources
of fresh water are precipitation and the snowpack from the
surrounding mountains. The naturally filtrated water emerges
in local streams, most prominently in Ashland Creek that feeds
the Reeder Reservoir. Ashland's Water Treatment plant is
currently located below Reeder Reservoir.
The ability of the ecosystem to provide clean freshwater is a
key benefit to the city and the region. According to the
Freshwater Trust, freshwater encompasses agriculture,
industry, fisheries, drinking water, recreation, and more. In
Neil Creek alone, restoration efforts have resulted in a 16,000
percent increase in documented Coho and Chinook salmon
over a two-year period.
NHMP Benefits
kAGWE* \
SlSKWou
a mm
TAKEAWAY
Ashland's location means it is
inextricably linked to water. A
significant portion of the City's
infrastructure is tied to water:
drinking water, storm and
floodwater control, wastewater,
and habitat. Secondary benefits
derived from the utilization of Gl
and LID approaches to risk
reduction include habitat
preservation, recreation, water
quality, and tourism.
DRAFT
Freshwater provisioning
Many of the techniques used to protect water quality - vegetated
streamside buffers, wetlands, detention basins, groundwater re-
charge, etc. - also provide important erosion control, flood reduc-
tion and drought mitigation services
Gl/LID Best Management
Improving freshwater quality while decreasing hazard
impacts is the goal of Gl and LID best management prac-
tices for freshwater provisioning.
Reduce runoff
Employ infiltration solutions to reduce flow volumes while
increasing water quality
NHMP Actions
Possible NHMP action items to support freshwater
provisioning include:
Maintain and enhance existing water department policies
related to installing culverts, detention ponds, and filtration
ponds throughout the city to direct runoff and filter water,
as well as store water.
Maintain and enhance the Water Advisory Committee's
efforts to hold runoff during the wet season, construct new
dams, reuse water and irrigate with wastewater effluent.
These could involve more GI/LID solutions.
Relocate the water treatment plant.
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