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Chapter 10
Water Resources
10.1 River Basin Hydrologic Units
Under the federal system, the New River basin is made up of hydrologic areas referred to as
cataloging units (USGS 8-digit hydrologic units). Cataloging units are further divided into
smaller watershed units (14-digit hydrologic units or local watersheds) that are used for smaller
scale planning like that done by NCEEP (Chapter 12). There are 20 local watershed units in the
basin, all of which are listed in Table 16. A map identifying the hydrologic units and subbasins
can be found in Appendix I.
Table 16 Hydrologic Subdivisions in the New River Basin
Watershed Name
and
Major Tributaries
DWQ
Subbasin
6-Digit
Codes
USGS
8-Digit
Hydrologic
Units
USGS
14-Digit Hydrologic Units
Local Watersheds*
South Fork New River
Middle Fork South Fork New River
East Fork South Fork New River
Winkler Creek
Howard Creek
Meat Camp Creek
Pine Orchard Creek
Old Field Creek
Pine Swamp Creek
South Beaver Creek (Lake Ashe)
Obids Creek
Roan Creek
Naked Creek
Peak Creek
Cranberry Creek
North Fork New River
Hoskin Fork
Three Top Creek
Big Laurel Creek
Buffalo Creek
Big Horse Creek
Helton Creek
Little River
Pine Swamp Creek
Bledsoe Creek
Elk Creek
Glade Creek
Brush Creek
Crab Creek
05-07-01
05-07-02
05-07-03
05050001 020010, 020020, 020030, 020040, 020050,
020060, 020070, 030010
010010, 010020, 010030, 010040, 010050,
010060, 010070, 010080
030015, 030020, 030030, 040040
* Numbers from the 8-digit and 14-digit column make the full 14-digit HU.
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10.2 Minimum Streamflow
Conditions may be placed on dam operations specifying mandatory minimum releases in order to
maintain adequate quantity and quality of water in the length of a stream affected by an
impoundment. One of the purposes of the Dam Safety Law is to ensure maintenance of
minimum streamflows below dams. The Division of Water Resources (DWR), in conjunction
with the Wildlife Resources Commission (WRC), recommends conditions related to release of
flows to satisfy minimum instream flow requirements. The Division of Land Resources (DLR)
issues the permits.
Under the authority of the Federal Power Act, the Federal Energy Regulatory Commission
(FERC) licenses all non-federal dams located on the navigable waters in the United States that
produce hydropower for the purposes of interstate commerce. The license may include
requirements for flows from the project for designated in-stream or off-stream uses.
Under the authority of Section 404 of the Clean Water Act, the U.S. Army Corps of Engineers
issues permits for the discharge of fill material into navigable waters. The permit may include
requirements for flows for designated in-stream or off-stream uses. A 404 permit will not only
apply to dams under state and federal regulatory authorities mentioned above but will also cover
structures that are not under their authority such as weirs, diversions and small dams. Table 17
presents selected minimum streamflow projects in the New River basin. It should be noted that
this is not necessarily a complete list of minimum streamflow requirements in the basin.
Absence from this list should not be interpreted as relief from fulfilling existing permit flow
requirements.
Table 17 Selected Minimum Streamflow Projects in the New River Basin
Name Location Waterbody
Drainage
Area
(sq. mi.)
Minimum
Release
(cu.ft./sec)
Hydroelectric Dams
Sharpe Falls Near Dresden, Ashe County North Fork New River 112 None a
Impoundment Dams/Weirs
Roaring Gap Golf course, Alleghany County Laurel Branch 1.06 1.4
Old Beau Upper Golf course, Alleghany County Laurel Branch 1.33 None b
Old Beau Lower Golf course, Alleghany County Laurel Branch 1.54 1.6
Water Supply Weir Near Boone, Watauga County South Fork 19.5 4.0 c
Water Supply Dam Near Boone, Watauga County Winkler Creek 5.7 2.4 c
a Even though there is no minimum flow, the project must operate in a run-of-river mode; i.e., instantaneous inflow
equals instantaneous outflow. Note: A noncompliant project can noticeably alter the streamflow. b The upper and lower ponds were built in series so that the system will provide 1.6 cubic feet/second (cfs)
downstream. c The Section 404 permit, issued by the U.S. Army Corp of Engineers, also states “the Town of Boone will in all
cases be permitted to withdraw a maximum of 4.6 cfs from the combined sources.”
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10.3 Interbasin Transfers
In addition to water withdrawals, water users in North Carolina are also required to register
surface water transfers with DWR if the amount is 100,000 gallons per day or more. In addition,
persons wishing to transfer two million gallons per day (MGD) or more, or increase an existing
transfer by 25 percent or more, must first obtain a certificate from the Environmental
Management Commission (General Statute 143-215.22I). The basin boundaries that apply to
these requirements are designated on a map entitled Major River Basins and Sub-Basins in North
Carolina, on file in the Office of the Secretary of State. These boundaries differ from the 17
major river basins delineated by DWQ. Table 18 summarizes interbasin transfers within the
New River basin.
In determining whether a certificate should be issued, the state must determine that the overall
benefits of a transfer outweigh the potential impacts. Factors used to determine whether a
certificate should be issued include:
Necessity, reasonableness and beneficial effects of the transfer;
Detrimental effects on the source and receiving basins, including effects on water
supply needs, wastewater assimilation, water quality, fish and wildlife habitat,
hydroelectric power generation, navigation and recreation;
Cumulative effect of existing transfers or water uses in the source basin;
Reasonable alternatives to the proposed transfer; and
Any other facts and circumstances necessary to evaluate the transfer request.
A provision of the interbasin transfer law requires that an environmental assessment or
environmental impact statement be prepared in accordance with the State Environmental Policy
Act as supporting documentation for a transfer petition. For more information on interbasin
transfers, visit the website at http://www.ncwater.org/or call DWR (919) 733-4064.
Table 18 Estimated Interbasin Transfers in the New River Basin (1997)
Supplying
System
Receiving
System
Source
Subbasin
Receiving
Subbasin
Estimated
Transfer (MGD)
Blowing Rock Blowing Rock New Catawba Unknown
Blowing Rock Blowing Rock New Yadkin Pee-Dee Unknown
Town of Boone Town of Boone New Watauga Unknown
10.4 Water Quality Issues Related to Drought
Water quality problems associated with rainfall events usually involve degradation of aquatic
habitats because the high flows may carry increased loadings of substances like metals, oils,
herbicides, pesticides, sand, clay, organic material, bacteria and nutrients. These substances can
be toxic to aquatic life (fish and insects) or may result in oxygen depletion or sedimentation.
During drought conditions, these pollutants become more concentrated in streams due to reduced
flow. Summer months are generally the most critical months for water quality. Dissolved
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oxygen is naturally lower due to higher temperatures, algae grow more due to longer periods of
sunlight, and streamflows are reduced. In a long-term drought, these problems can be greatly
exacerbated and the potential for water quality problems to become catastrophic is increased.
This section discusses water quality problems that can be expected during low flow conditions.
The frequency of acute impacts due to nonpoint source pollution (runoff) is actually minimized
during drought conditions. However, when rain events do occur, pollutants that have been
collecting on the land surface are quickly delivered to streams. When streamflows are well
below normal, this polluted runoff becomes a larger percentage of the water flowing in the
stream. Point sources may also have water quality impacts during drought conditions even
though permit limits are being met. Facilities that discharge wastewater have permit limits that
are based on the historic low flow conditions. During droughts these wastewater discharges
make up a larger percentage of the water flowing in streams than normal and might contribute to
lowered dissolved oxygen concentrations and increased levels of other pollutants.
As streamflows decrease, there is less habitat available for aquatic insects and fish, particularly
around lake shorelines. There is also less water available for irrigation and for water supplies.
The dry conditions and increased removal of water for these uses further increases strain on the
resource. With less habitat, naturally lower dissolved oxygen levels and higher water
temperatures, the potential for large kills of fish and aquatic insects is very high. These
conditions may stress the fish to the point where they become more susceptible to disease and
where stresses that normally would not harm them result in mortality.
These are also areas where longer retention times due to decreased flows allow algae to take full
advantage of the nutrients present resulting in algal blooms. During the daylight hours, algae
greatly increase the amount of dissolved oxygen in the water, but at night, algal respiration and
die off can cause dissolved oxygen levels to drop low enough to cause fish kills. Besides
increasing the frequency of fish kills, algae blooms can also cause difficulty in water treatment
resulting in taste and odor problems in finished drinking water.
10.5 Source Water Assessment of Public Water Supplies
10.5.1 Introduction
The Federal Safe Drinking Water Act (SDWA) Amendments of 1996 emphasize pollution
prevention as an important strategy for the protection of ground and surface water resources.
This new focus promotes the prevention of drinking water contamination as a cost-effective
means to provide reliable, long-term and safe drinking water sources for public water supply
(PWS) systems. In order to determine the susceptibility of public water supply sources to
contamination, the amendments also required that all states establish a Source Water Assessment
Program (SWAP). Specifically, Section 1453 of the SDWA Amendments require that states
develop and implement a SWAP to:
Delineate source water assessment areas;
Inventory potential contaminants in these areas; and
Determine the susceptibility of each public water supply to contamination.
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In North Carolina, the agency responsible for the SWAP is the Public Water Supply (PWS)
Section of the DENR Division of Environmental Health (DEH). The PWS Section received
approval from the EPA for their SWAP Plan in November 1999. The SWAP Plan, entitled
North Carolina’s Source Water Assessment Program Plan, fully describes the methods and
procedures used to delineate and assess the susceptibility of more than 9,000 wells and
approximately 207 surface water intakes. To review the SWAP Plan, visit the PWS website at
http://www.deh.enr.state.nc.us/pws/index.htm.
10.5.2 Delineation of Source Water Assessment Areas
The SWAP Plan builds upon existing protection programs for ground and surface water
resources. These include the state’s Wellhead Protection Program and the Water Supply
Watershed Protection Program.
Wellhead Protection (WHP) Program
North Carolinians withdraw more than 88 million gallons of groundwater per day from more
than 9,000 water supply wells across the state. In 1986, Congress passed Amendments to the
SDWA requiring states to develop wellhead protection programs that reduce the threat to the
quality of groundwater used for drinking water by identifying and managing recharge areas to
specific wells or wellfields.
Defining a wellhead protection area (WHPA) is one of the most critical components of wellhead
protection. A WHPA is defined as “the surface and subsurface area surrounding a water well or
wellfield, supplying a public water system, through which contaminants are reasonably likely to
move toward and reach such water well or wellfield.” The SWAP uses the methods described in
the state's approved WHP Program to delineate source water assessment areas for all public
water supply wells. More information related to North Carolina’s WHP Program can be found at
http://www.deh.enr.state.nc.us/pws/swap.
Water Supply Watershed Protection (WSWP) Program
DWQ is responsible for managing the standards and classifications of all water supply
watersheds. In 1992, the WSWP Rules were adopted by the EMC and require all local
governments that have land use jurisdiction within water supply watersheds adopt and implement
water supply watershed protection ordinances, maps and management plans. SWAP uses the
established water supply watershed boundaries and methods established by the WSWP program
as a basis to delineate source water assessment areas for all public water surface water intakes.
Additional information regarding the WSWP Program can be found at
http://h2o.enr.state.nc.us/wswp/index.html.
10.5.3 Susceptibility Determination – North Carolina’s Overall Approach
The SWAP Plan contains a detailed description of the methods used to assess the susceptibility
of each PWS intake in North Carolina. The following is a brief summary of the susceptibility
determination approach.
Overall Susceptibility Rating
The overall susceptibility determination rates the potential for a drinking water source to become
contaminated. The overall susceptibility rating for each PWS intake is based on two key
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components: a contaminant rating and an inherent vulnerability rating. For a PWS to be
determined “susceptible”, a potential contaminant source must be present and the existing
conditions of the PWS intake location must be such that a water supply could become
contaminated. The determination of susceptibility for each PWS intake is based on combining
the results of the inherent vulnerability rating and the contaminant rating for each intake. Once
combined, a PWS is given a susceptibility rating of higher, moderate or lower (H, M or L).
Inherent Vulnerability Rating
Inherent vulnerability refers to the physical characteristics and existing conditions of the
watershed or aquifer. The inherent vulnerability rating of groundwater intakes is determined
based on an evaluation of aquifer characteristics, unsaturated zone characteristics and well
integrity and construction characteristics. The inherent vulnerability rating of surface water
intakes is determined based on an evaluation of the watershed classification (WSWP Rules),
intake location, raw water quality data (i.e., turbidity and total coliform) and watershed
characteristics (i.e., average annual precipitation, land slope, land use, land cover, groundwater
contribution).
Contaminant Rating
The contaminant rating is based on an evaluation of the density of potential contaminant sources
(PCSs), their relative risk potential to cause contamination, and their proximity to the water
supply intake within the delineated assessment area.
Inventory of Potential Contaminant Sources (PCSs)
In order to inventory PCSs, the SWAP conducted a review of relevant, available sources of
existing data at federal, state and local levels. The SWAP selected sixteen statewide databases
that were attainable and contained usable geographic information related to PCSs.
10.5.4 Source Water Protection
The PWS Section believes that the information from the source water assessments will become
the basis for future initiatives and priorities for public drinking water source water protection
(SWP) activities. The PWS Section encourages all PWS system owners to implement efforts to
manage identified sources of contamination and to reduce or eliminate the potential threat to
drinking water supplies through locally implemented programs
To encourage and support local SWP, the state offers PWS system owners assistance with local
SWP as well as materials such as:
Fact sheets outlining sources of funding and other resources for local SWP efforts.
Success stories describing local SWP efforts in North Carolina.
Guidance about how to incorporate SWAP and SWP information in Consumer Confidence
Reports (CCRs).
Information related to SWP can be found at http://www.deh.enr.state.nc.us/pws/swap.
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10.5.5 Public Water Supply Susceptibility Determinations in the New River Basin
In April 2004, the PWS Section completed source water assessments for all drinking water
sources and generated reports for the PWS systems using these sources. A second round of
assessments were completed in April 2005. The results of the assessments can be viewed in two
different ways, either through the interactive ArcIMS mapping tool or compiled in a written
report for each PWS system. To access the ArcIMS mapping tool, simply click on the “NC
SWAP Info” icon on the PWS web page (http://www.deh.enr.state.nc.us/pws/swap). To view a report,
select the PWS System of interest by clicking on the “SWAP Reports” icon.
In the New River Basin, 199 public water supply sources were identified. Six are surface water
sources, and 193 are groundwater sources. Of the193 groundwater sources, five have a Higher
susceptibility rating and 188 have a Moderate susceptibility rating. Table 19 identifies the six
surface water sources and the overall susceptibility rating. It is important to note that a
susceptibility rating of Higher does not imply poor water quality. Susceptibility is an indication
of a water supply's potential to become contaminated by the identified PCSs within the
assessment area.
Table 19 SWAP Results for Surface Water Sources in the New River Basin
PWS ID
Number
Inherent
Vulnerability
Rating
Contaminant
Rating
Overall
Susceptibility
Rating
Name of Surface
Water Source
PWS Name
0105015 H L M South Fork New River Town of Jefferson
0195010 H L M Winklers Creek Town of Boone
0195010 H L M South Fork New River Town of Boone
0195020 M L M Town Lake Town of Blowing Rock
0195101 M L M Norris Branch App. State University WTP
0195101 H L M Howards Creek App. State University WTP
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