|
Water Resources Data
New Jersey
Water Year 2007
Documentation
Since October 1, 1950, hydrologic-station records in USGS
reports have been listed in order of downstream direction
along the main stream. All stations on a tributary entering
upstream from a main-stream station are listed before that
station. A station on a tributary entering between two
mainstream stations is listed between those stations. A
similar order is followed in listing stations on first
rank, second rank, and other ranks of tributaries. The rank
of any tributary on which a station is located with respect
to the stream to which it is immediately tributary is
indicated by an indention in that list of stations in the
front of this report. Each indentation represents one rank.
This downstream order and system of indentation indicates
which stations are on tributaries between any two stations
and the rank of the tributary on which each station is
located.
As an added means of identification, each hydrologic
station and partial-record station has been assigned a
station number. These station numbers are in the same
downstream order used in this report. In assigning a
station number, no distinction is made between
partial-record stations and other stations; therefore, the
station number for a partial-record station indicates
downstream-order position in a list composed of both types
of stations. Gaps are consecutive. The complete 8-digit
(or 10-digit) number for each station such as 09004100,
which appears just to the left of the station name,
includes a 2-digit part number "09" plus the 6-digit (or
8-digit) downstream order number "004100." In areas of high
station density, an additional two digits may be added to
the station identification number to yield a 10-digit
number. The stations are numbered in downstream order as
described above between stations of consecutive 8- digit
numbers.
The USGS well and miscellaneous site-numbering system is
based on the grid system of latitude and longitude. The
system provides the geographic location of the well or
miscellaneous site and a unique number for each site. The
number consists of 15 digits. The first 6 digits denote the
degrees, minutes, and seconds of latitude, and the next 7
digits denote degrees, minutes, and seconds of longitude;
the last 2 digits are a sequential number for wells within
a 1-second grid. In the event that the latitude-longitude
coordinates for a well and miscellaneous site are the same,
a sequential number such as "01," "02," and so forth, would
be assigned as one would for wells (see fig. 1). The
8-digit, downstream order station numbers are not assigned
to wells and miscellaneous sites where only random
water-quality samples or discharge measurements are taken.
Figure 1. Example of system for numbering wells and miscellaneous sites (latitude and longitude).
In addition to the well number that is based on the
latitude and longitude for each well, another well number
may be provided which in many States is based on the Public
Land Survey System, a set of rectangular surveys that is
used to identify land parcels. This well number is familiar
to the water users in, for example, Utah and shows the
location of the well by quadrant, township, range section,
and position within the section (see fig. 2).
Figure 2. Example of system for numbering wells and miscellaneous sites (township and range).
Some Water Science Centers also identify each ground-water
site by a local number that consists of an abbreviation of
the county name as well as the township, range and section,
and a four-digit number assigned to the well. Naming
conventions specific to an individual Water Science Center
can be obtained locally from each USGS Water Science Center.
Data Collection and Computation
The base data collected at gaging stations consist of
records of stage and measurements of discharge of streams
or canals, and stage, surface area, and volume of lakes or
reservoirs. In addition, observations of factors affecting
the stage-discharge relation or the stage-capacity relation,
weather records, and other information are used to
supplement base data in determining the daily flow or
volume of water in storage. Records of stage are obtained
from a water-stage recorder that is either downloaded
electronically in the field to a laptop computer or similar
device or is transmitted using telemetry such as GOES
satellite, land-line or cellular-phone modems, or by radio
transmission. Measurements of discharge are made with a
current meter or acoustic Doppler current profiler, using
the general methods adopted by the USGS. These methods are
described in standard textbooks, USGS Water- Supply
Paper 2175, and the Techniques of Water-Resources
Investigations of the United States Geological Survey
(TWRIs), Book 3, Chapters A1 through A19 and Book 8,
Chapters A2 and B2, which may be accessed from http://water.usgs.gov/
pubs/twri/. The methods are consistent with the
American Society for Testing and Materials (ASTM) standards
and generally follow the standards of the International
Organization for Standardization (ISO).
For stream-gaging stations, discharge-rating tables for any
stage are prepared from stage-discharge curves. If
extensions to the rating curves are necessary to express
discharge greater than measured, the extensions are made on
the basis of indirect measurements of peak discharge (such
as slope-area or contracted-opening measurements, or
computation of flow over dams and weirs), step-backwater
techniques, velocity-area studies, and logarithmic
plotting. The daily mean discharge is computed from gage
heights and rating tables, then the monthly and yearly mean
discharges are computed from the daily values. If the
stage-discharge relation is subject to change because of
frequent or continual change in the physical features of
the stream channel, the daily mean discharge is computed by
the shifting-control method in which correction factors
that are based on individual discharge measurements and
notes by engineers and observers are used when applying the
gage heights to the rating tables. If the stage-discharge
relation for a station is temporarily changed by the
presence of aquatic growth or debris on the controlling
section, the daily mean discharge is computed by the
shifting-control method.
The stage-discharge relation at some stream-gaging stations
is affected by backwater from reservoirs, tributary
streams, or other sources. Such an occurrence necessitates
the use of the slope method in which the slope or fall in a
reach of the stream is a factor in computing discharge. The
slope or fall is obtained by means of an auxiliary gage at
some distance from the base gage. An index velocity is
measured using ultrasonic or acoustic instruments at some
stream-gaging stations, and this index velocity is used to
calculate an average velocity for the flow in the stream.
This average velocity along with a stage-area relation is
then used to calculate average discharge. At some stations,
the stage-discharge relation is affected by changing stage.
At these stations, the rate of change in stage is used as a
factor in computing discharge.
At some stream-gaging stations in the northern United
States, the stage-discharge relation is affected by ice in
the winter; therefore, computation of the discharge in the
usual manner is impossible. Discharge for periods of ice
effect is computed on the basis of gage-height record and
occasional winter-discharge measurements. Consideration is
given to the available information on temperature and
precipitation, notes by gage observers and hydrologists,
and comparable records of discharge from other stations in
the same or nearby basins.
For a lake or reservoir station, capacity tables giving the
volume or contents for any stage are prepared from
stage-area relation curves defined by surveys. The
application of the stage to the capacity table gives the
contents, from which the daily, monthly, or yearly changes
are computed.
If the stage-capacity curve is subject to changes because
of deposition of sediment in the reservoir, periodic
resurveys of the reservoir are necessary to define new
stage-capacity curves. During the period between reservoir
surveys, the computed contents may be increasingly in error
due to the gradual accumulation of sediment.
For some stream-gaging stations, periods of time occur when
no gage-height record is obtained or the recorded gage
height is faulty and cannot be used to compute daily
discharge or contents. Such a situation can happen when the
recorder stops or otherwise fails to operate properly, the
intakes are plugged, the float is frozen in the well, or
for various other reasons. For such periods, the daily
discharges are estimated on the basis of recorded range in
stage, prior and subsequent records, discharge
measurements, weather records, and comparison with records
from other stations in the same or nearby basins. Likewise,
lake or reservoir volumes may be estimated on the basis of
operator's log, prior and subsequent records,
inflow-outflow studies, and other information.
Data Presentation
The records published for each continuous record
surface-water discharge station (stream-gaging station)
consist of five parts: (1) the station manuscript or
description; (2) the data table of daily mean values of
discharge for the current water year with summary data; (3)
a tabular statistical summary of monthly mean flow data for
a designated period, by water year; (4) a summary
statistics table that includes statistical data of annual,
daily, and instantaneous flows as well as data pertaining
to annual runoff, 7-day low-flow minimums, and flow
duration; and (5) a hydrograph of discharge.
Station Manuscript
The manuscript provides, under various headings,
descriptive information, such as station location; period
of record; historical extremes outside the period of
record; record accuracy; and other remarks pertinent to
station operation and regulation. The following
information, as appropriate, is provided with each
continuous record of discharge or lake content. Comments
follow that clarify information presented under the various
headings of the station description.
LOCATION.-Location information is obtained from the most
accurate maps available. The location of the gaging station
with respect to the cultural and physical features in the
vicinity and with respect to the reference place mentioned
in the station name is given. River mileages, given for
only a few stations, were determined by methods given in
"River Mileage Measurement," Bulletin 14, Revision of
October 1968, prepared by the Water Resources Council or
were provided by the U.S. Army Corps of Engineers.
DRAINAGE AREA.-Drainage areas are measured using the most
accurate maps available. Because the type of maps available
varies from one drainage basin to another, the accuracy of
drainage areas likewise varies. Drainage areas are updated
as better maps become available.
PERIOD OF RECORD.-This term indicates the time period for
which records have been published for the station or for an
equivalent station. An equivalent station is one that was
in operation at a time that the present station was not and
whose location was such that its flow reasonably can be
considered equivalent to flow at the present station.
REVISED RECORDS.-If a critical error in a published site
data sheet is discovered, a revision is included (where?)
in the next publishing cycle following discovery of the
error.
GAGE.-The type of gage in current use, the datum of the
current gage referred to a standard datum, and a condensed
history of the types, locations, and datums of previous
gages are given under this heading.
REMARKS.-All periods of estimated daily discharge either
will be identified by date in this paragraph of the station
description for water discharge stations or flagged in the
daily discharge table. (See section titled Identifying
Estimated Daily Discharge.) Information is presented
relative to the accuracy of the records, to special methods
of computation, and to conditions that affect natural flow
at the station. In addition, information may be presented
pertaining to average discharge data for the period of
record; to extremes data for the period of record and the
current year; and, possibly, to other pertinent items. For
reservoir stations, information is given on the dam forming
the reservoir, the capacity, the outlet works and spillway,
and the purpose and use of the reservoir.
COOPERATION.-Records provided by a cooperating organization
or obtained for the USGS by a cooperating organization are
identified here.
EXTREMES OUTSIDE PERIOD OF RECORD.-Information here
documents major floods or unusually low flows that occurred
outside the stated period of record. The information may or
may not have been obtained by the USGS.
REVISIONS.-Records are revised if errors in published
records are discovered. Appropriate updates are made in the
USGS distributed data system, NWIS, and subsequently to its
Web-based national data system, NWISWeb (http://water.usgs.gov/nwis/nwis).
Users are encouraged to obtain all required data from NWIS
or NWISWeb to ensure that they have the most recent data
updates. Updates to NWISWeb are made on an annual basis.
Although rare, occasionally the records of a discontinued
gaging station may need revision. Because no current or,
possibly, future station manuscript would be published for
these stations to document the revision in a REVISED
RECORDS entry, users of data for these stations who
obtained the record from previously published data reports
may wish to contact the USGS Water Science Center in the
state where the station is located to determine if the
published records were revised after the station was
discontinued. If, however, the data for a discontinued
station were obtained by computer retrieval, the data would
be current. Any published revision of data is always
accompanied by revision of the corresponding data in
computer storage.
Manuscript information for lake or reservoir stations
differs from that for stream stations in the nature of the
REMARKS and in the inclusion of a stage-capacity table when
daily volumes are given.
Peak Discharge Greater than Base Discharge
Tables of peak discharge above base discharge are included
for some stations where secondary instantaneous peak
discharge data are used in flood-frequency studies of
highway and bridge design, flood-control structures, and
other flood related projects. The base discharge value is
selected so an average of three peaks a year will be
reported. This base discharge value has a recurrence
interval of approximately 1.1 years or a 91-percent chance
of exceedence in any 1 year.
Data Table of Daily Mean Values
The daily table of discharge records for streamgaging
stations gives mean discharge for each day of the water
year. In the monthly summary for the table, the line headed
TOTAL gives the sum of the daily figures for each month;
the line headed MEAN gives the arithmetic average flow in
cubic feet per second for the month; and the lines headed
MAX and MIN give the maximum and minimum daily mean
discharges, respectively, for each month. Discharge for the
month is expressed in cubic feet per second per square mile
(line headed CFSM); or in inches (line headed IN); or in
acrefeet (line headed AC-FT). Values for cubic feet per
second per square mile and runoff in inches or in acre-feet
may be omitted if extensive regulation or diversion is in
effect or if the drainage area includes large
noncontributing areas. At some stations, monthly and (or)
yearly observed discharges are adjusted for reservoir
storage or diversion, or diversion data or reservoir
volumes are given. These values are identified by a symbol
and a corresponding footnote.
Statistics of Monthly Mean Data
A tabular summary of the mean (line headed MEAN), maximum
(MAX), and minimum (MIN) of monthly mean flows for each
month for a designated period is provided below the mean
values table. The water years of the first occurrence of
the maximum and minimum monthly flows are provided
immediately below those values. The designated period will
be expressed as FOR WATER YEARS __-__, BY WATER YEAR (WY),
and will list the first and last water years of the range
of years selected from the PERIOD OF RECORD paragraph in
the station manuscript. The designated period will consist
of all of the station record within the specified water
years, including complete months of record for partial
water years, and may coincide with the period of record for
the station. The water years for which the statistics are
computed are consecutive, unless a break in the station
record is indicated in the manuscript.
Summary Statistics
A table titled SUMMARY STATISTICS follows the statistics of
monthly mean data tabulation. This table consists of four
columns with the first column containing the line headings
of the statistics being reported. The table provides a
statistical summary of yearly, daily, and instantaneous
flows, not only for the current water year but also for the
previous calendar year and for a designated period, as
appropriate. The designated period selected, WATER YEARS
__-__, will consist of all of the station records within
the specified water years, including complete months of
record for partial water years, and may coincide with the
period of record for the station. The water years for which
the statistics are computed are consecutive, unless a break
in the station record is indicated in the manuscript. All
of the calculations for the statistical characteristics
designated ANNUAL (see line headings below), except for the
ANNUAL 7-DAY MINIMUM statistic, are calculated for the
designated period using complete water years. The other
statistical characteristics may be calculated using partial
water years. The date or water year, as appropriate, of the
first occurrence of each statistic reporting extreme values
of discharge is provided adjacent to the statistic.
Repeated occurrences may be noted in the REMARKS paragraph
of the manuscript or in footnotes. Because the designated
period may not be the same as the station period of record
published in the manuscript, occasionally the dates of
occurrence listed for the daily and instantaneous extremes
in the designated-period column may not be within the
selected water years listed in the heading. When the dates
of occurrence do not fall within the selected water years
listed in the heading, it will be noted in the REMARKS
paragraph or in footnotes. Selected streamflow
duration-curve statistics and runoff data also are given.
Runoff data may be omitted if extensive regulation or
diversion of flow is in effect in the drainage basin.
The following summary statistics data are provided with
each continuous record of discharge. Comments that follow
clarify information presented under the various line
headings of the SUMMARY STATISTICS table.
ANNUAL TOTAL.-The sum of the daily mean values of discharge
for the year.
ANNUAL MEAN.-The arithmetic mean for the individual daily
mean discharges for the year noted or for the designated
period.
HIGHEST ANNUAL MEAN.-The maximum annual mean discharge
occurring for the designated period.
LOWEST ANNUAL MEAN.-The minimum annual mean discharge
occurring for the designated period.
HIGHEST DAILY MEAN.-The maximum daily mean discharge for
the year or for the designated period.
LOWEST DAILY MEAN.-The minimum daily mean discharge for the
year or for the designated period.
ANNUAL 7-DAY MINIMUM.-The lowest mean discharge for 7
consecutive days for a calendar year or a water year. Note
that most low-flow frequency analyses of annual 7-day
minimum flows use a climatic year (April 1-March 31). The
date shown in the summary statistics table is the initial
date of the 7-day period. This value should not be confused
with the 7-day 10-year low-flow statistic.
MAXIMUM PEAK FLOW.-The maximum instantaneous peak discharge
occurring for the water year or designated period.
Occasionally the maximum flow for a year may occur at
midnight at the beginning or end of the year, on a
recession from or rise toward a higher peak in the
adjoining year. In this case, the maximum peak flow is
given in the table and the maximum flow may be reported in
a footnote or in the REMARKS paragraph in the manuscript.
MAXIMUM PEAK STAGE.-The maximum instantaneous peak stage
occurring for the water year or designated period.
Occasionally the maximum stage for a year may occur at
midnight at the beginning or end of the year, on a
recession from or rise toward a higher peak in the
adjoining year. In this case, the maximum peak stage is
given in the table and the maximum stage may be reported in
the REMARKS paragraph in the manuscript or in a footnote.
If the dates of occurrence of the maximum peak stage and
maximum peak flow are different, the REMARKS paragraph in
the manuscript or a footnote may be used to provide further
information.
INSTANTANEOUS LOW FLOW.-The minimum instantaneous discharge
occurring for the water year or for the designated period.
ANNUAL RUNOFF.-Indicates the total quantity of water in
runoff for a drainage area for the year. Data reports may
use any of the following units of measurement in presenting
annual runoff data:
Acre-foot (AC-FT) is the quantity of water required to
cover 1 acre to a depth of 1 foot and is equivalent to
43,560 cubic feet or about 326,000 gallons or 1,233 cubic
meters.
Cubic feet per square mile (CFSM) is the average number of
cubic feet of water flowing per second from each square
mile of area drained, assuming the runoff is distributed
uniformly in time and area.
Inches (INCHES) indicate the depth to which the drainage
area would be covered if all of the runoff for a given time
period were uniformly distributed on it.
10 PERCENT EXCEEDS.-The discharge that has been exceeded 10
percent of the time for the designated period.
50 PERCENT EXCEEDS.-The discharge that has been exceeded 50
percent of the time for the designated period.
90 PERCENT EXCEEDS.-The discharge that has been exceeded 90
percent of the time for the designated period.
Data collected at partial-record stations follow the
information for continuous-record sites. Data for
partial-record discharge stations are presented in two
tables. The first table lists annual maximum stage and
discharge at crest-stage stations, and the second table
lists discharge measurements at lowflow partial-record
stations. The tables of partialrecord stations are followed
by a listing of discharge measurements made at sites other
than continuous-record or partial-record stations. These
measurements are often made in times of drought or flood to
give better areal coverage to those events. Those
measurements and others collected for a special reason are
called measurements at miscellaneous sites.
Identifying Estimated Daily Discharge
Estimated daily-discharge values published in the
water-discharge tables of annual State data reports are
identified. This identification is shown either by flagging
individual daily values with the letter "e" and noting in a
table footnote, "e- Estimated," or by listing the dates of
the estimated record in the REMARKS paragraph of the
station description.
Accuracy of Field Data and Computed Results
The accuracy of streamflow data depends primarily on (1)
the stability of the stage-discharge relation or, if the
control is unstable, the frequency of discharge
measurements, and (2) the accuracy of observations of
stage, measurements of discharge, and interpretations of
records.
The degree of accuracy of the records is stated in the
REMARKS in the station description. "Excellent" indicates
that about 95 percent of the daily discharges are within 5
percent of the true value; "good" within 10 percent; and
"fair," within 15 percent. "Poor" indicates that daily
discharges have less than "fair" accuracy. Different
accuracies may be attributed to different parts of a given
record.
Values of daily mean discharge in this report are shown to
the nearest hundredth of a cubic foot per second for
discharges of less than 1 ft3/s; to the nearest
tenths between 1.0 and 10 ft3/s; to whole
numbers between 10 and 1,000 ft3/s; and to three
significant figures above 1,000 ft3/s. The
number of significant figures used is based solely on the
magnitude of the discharge value. The same rounding rules
apply to discharge values listed for partial-record
stations.
Discharge at many stations, as indicated by the monthly
mean, may not reflect natural runoff due to the effects of
diversion, consumption, regulation by storage, increase or
decrease in evaporation due to artificial causes, or to
other factors. For such stations, values of cubic feet per
second per square mile and of runoff in inches are not
published unless satisfactory adjustments can be made for
diversions, for changes in contents of reservoirs, or for
other changes incident to use and control. Evaporation from
a reservoir is not included in the adjustments for changes
in reservoir contents, unless it is so stated. Even at
those stations where adjustments are made, large errors in
computed runoff may occur if adjustments or losses are
large in comparison with the observed discharge.
Other Data Records Available
Information of a more detailed nature than that published
for most of the stream-gaging stations such as discharge
measurements, gage-height records, and rating tables is
available from the USGS Water Science Center. Also, most
streamgaging station records are available in
computer usable form and many statistical analyses have been
made.
Information on the availability of unpublished data or
statistical analyses may be obtained from the USGS Water
Science Center in the state where the station is located.
Data Collection and Computation
Rainfall data generally are collected using electronic data
loggers that measure the rainfall in 0.01-inch increments
every 15 minutes using either a tipping-bucket rain gage or
a collection well gage. Twenty-four hour rainfall totals
are tabulated and presented. A 24-hour period extends from
just past midnight of the previous day to midnight of the
current day. Snowfall-affected data can result during cold
weather when snow fills the rain-gage funnel and then melts
as temperatures rise. Snowfall-affected data are subject to
errors. Missing values are indicated by this symbol "---"
in the table.
Data Presentation
Precipitation records collected at surface-water gaging
stations are identified with the same station number and
name as the stream-gaging station. Where a surface-water
daily-record station is not available, the precipitation
record is published with its own name and
latitude-longitude identification number.
Information pertinent to the history of a precipitation
station is provided in descriptive headings preceding the
tabular data. These descriptive headings give details
regarding location, period of record, and general remarks.
The following information is provided with each
precipitation station. Comments that follow clarify
information presented under the various headings of the
station description.
LOCATION.-See Data Presentation in the EXPLANATION OF
STAGE- AND WATERDISCHARGE RECORDS section of this report
(same comments apply).
PERIOD OF RECORD.-See Data Presentation in the EXPLANATION
OF STAGE- AND WATERDISCHARGE RECORDS section of this report
(same comments apply).
INSTRUMENTATION.-Information on the type of rainfall
collection system is given.
REMARKS.-Remarks provide added information pertinent to the
collection, analysis, or computation of records.
Collection and Examination of Data Surface-water samples
for analysis usually are collected at or near stream-gaging
stations. The quality-of-water records are given
immediately following the discharge records at these
stations. The descriptive heading for water-quality records
gives the period of record for all water-quality data; the
period of daily record for parameters that are measured on
a daily basis (specific conductance, water temperature,
sediment discharge, and so forth); extremes for the current
year; and general remarks.
For ground-water records, no descriptive statements are
given; however, the well number, depth of well, sampling
date, or other pertinent data are given in the table
containing the chemical analyses of the ground water.
Water Analysis
Most of the methods used for collecting and analyzing water
samples are described in the TWRIs, which may be accessed
from http://
water.usgs.gov/pubs/twri/.
One sample can define adequately the water quality at a
given time if the mixture of solutes throughout the stream
cross section is homogeneous. However, the concentration of
solutes at different locations in the cross section may
vary considerably with different rates of water discharge,
depending on the source of material and the turbulence and
mixing of the stream. Some streams must be sampled at
several verticals to obtain a representative sample needed
for an accurate mean concentration and for use in
calculating load.
Chemical-quality data published in this report are
considered to be the most representative values available
for the stations listed. The values reported represent
water-quality conditions at the time of sampling as much as
possible, consistent with available sampling techniques and
methods of analysis. In the rare case where an apparent
inconsistency exists between a reported pH value and the
relative abundance of carbon dioxide species (carbonate and
bicarbonate), the inconsistency is the result of a slight
uptake of carbon dioxide from the air by the sample between
measurement of pH in the field and determination of
carbonate and bicarbonate in the laboratory.
For chemical-quality stations equipped with digital
monitors, the records consist of daily maximum and minimum
values (and sometimes mean or median values) for each
constituent measured and are based on 15-minute or 1-hour
intervals of recorded data beginning at 0000 hours and
ending at 2400 hours for the day of record.
Records of surface-water quality ordinarily are obtained at
or near stream-gaging stations because discharge data are
useful in the interpretation of surface-water quality.
Records of surface-water quality in this report involve a
variety of types of data and measurement frequencies.
Classification of Records
Water-quality data for surface-water sites are grouped into
one of three classifications. A continuous-record station
is a site where data are collected on a regularly scheduled
basis. Frequency may be one or more times daily, weekly,
monthly, or quarterly. A partial-record station is a site
where limited water-quality data are collected
systematically over a period of years. Frequency of
sampling is usually less than quarterly. A miscellaneous
sampling site is a location other than a continuous- or
partial-record station, where samples are collected to give
better areal coverage to define water-quality conditions in
the river basin.
A careful distinction needs to be made between continuous
records as used in this report and continuous recordings
that refer to a continuous graph or a series of discrete
values recorded at short intervals. Some records of water
quality, such as temperature and specific conductance, may
be obtained through continuous recordings; however, because
of costs, most data are obtained only monthly or less
frequently. Locations of stations for which records on the
quality of surface water appear in this report may be
published as a USGS Annual Scientific Investigations Report
by State, and may be accessed from http://pubs.usgs.gov, or the
Related Information and Publications page of this Web
Site.
Accuracy of the Records
One of four accuracy classifications is applied for
measured physical properties at continuous-record stations
on a scale ranging from poor to excellent. The accuracy
rating is based on data values recorded before any shifts
or corrections are made. Additional consideration also is
given to the amount of publishable record and to the amount
of data that have been corrected or shifted.
Arrangement of Records
Water-quality records collected at a surface-water daily
record station are published immediately following that
record, regardless of the frequency of sample collection.
Station number and name are the same for both records.
Where a surface-water daily record station is not available
or where the water quality differs significantly from that
at the nearby surface-water station, the continuing
water-quality record is published with its own station
number and name in the regular downstream-order sequence.
Water-quality data for partial-record stations and for
miscellaneous sampling sites appear in separate tables
following the table of discharge measurements at
miscellaneous sites.
Onsite Measurements and Sample Collection
In obtaining water-quality data, a major concern is
assuring that the data obtained represent the naturally
occurring quality of the water. To ensure this, certain
measurements, such as water temperature, pH, and dissolved
oxygen, must be made onsite when the samples are collected.
To assure that measurements made in the laboratory also
represent the naturally occurring water, carefully
prescribed procedures must be followed in collecting the
samples, in treating the samples to prevent changes in
quality pending analysis, and in shipping the samples to
the laboratory. Procedures for onsite measurements and for
collecting, treating, and shipping samples are given in
TWRIs Book 1, Chapter D2; Book 3, Chapters A1, A3, and A4;
and Book 9, Chapters A1-A9. Most of the methods used for
collecting and analyzing water samples are described in the
TWRIs, which may be accessed from http://water.usgs.gov/pubs/twri/.
Also, detailed information on collecting, treating, and
shipping samples can be obtained from the USGS Water
Science Center.
Rating the accuracy of continuous water-quality records
[≤, less than or equal to; ±, plus or minus value shown; °C, degree Celsius; >, greater than; %, percent; mg/L, milligram per liter; pH unit, standard pH unit]
|
Measured field
parameter
|
Ratings of accuracy
(Based on combined fouling and calibration drift corrections applied to the record)
|
|
Excellent
|
Good
|
Fair
|
Poor
|
|
Water temperature
|
≤ ± 0.2 °C
|
> ± 0.2 - 0.5 °C
|
> ± 0.5 - 0.8 °C
|
> ± 0.8 °C
|
|
Specific conductance
|
≤ ± 3%
|
> ± 3 - 10%
|
> ± 10 - 15%
|
> ± 15%
|
|
Dissolved oxygen
|
≤ ± 0.3 mg/L or ≤ ± 5%, whichever is greater
|
> ± 0.3 - 0.5 mg/L or > ± 5 - 10%, whichever is greater
|
> ± 0.5 - 0.8 mg/L or > ± 10 - 15%, whichever is greater
|
> ± 0.8 mg/L or > ± 15%, whichever is greater
|
|
pH
|
≤ ± 0.2 units
|
> ± 0.2 - 0.5 units
|
> ± 0.5 - 0.8 units
|
> ± 0.8 units
|
|
Turbidity
|
≤ ± 0.5 turbidity units or ≤ ± 5%, whichever is greater
|
> ± 0.5 - 1.0 turbidity units or > ± 5 - 10%, whichever is greater
|
> ± 1.0 - 1.5 turbidity units or > ± 10 - 15%, whichever is greater
|
> ± 1.5 turbidity units or > ± 15%, whichever is greater
|
Water Temperature
Water temperatures are measured at most of the
water-quality stations. In addition, water temperatures are
taken at the time of discharge measurements for
water-discharge stations. For stations where water
temperatures are taken manually once or twice daily, the
water temperatures are taken at about the same time each
day. Large streams have a small diurnal temperature change;
shallow streams may have a daily range of several degrees
and may follow closely the changes in air temperature. Some
streams may be affected by waste-heat discharges.
At stations where recording instruments are used, either
mean temperatures or maximum and minimum temperatures for
each day are published. Water temperatures measured at the
time of water discharge-measurements are on file in the USGS
Water Science Center in the State where the station is
located.
Sediment
Suspended-sediment concentrations are determined from
samples collected by using depth-integrating samplers.
Samples usually are obtained at several verticals in the
cross section, or a single sample may be obtained at a
fixed point and a coefficient applied to determine the mean
concentration in the cross section.
During periods of rapidly changing flow or rapidly changing
concentration, samples may be collected more frequently
(twice daily or, in some instances, hourly). The published
sediment discharges for days of rapidly changing flow or
concentration are computed by the subdivided-day method
(time-discharge weighted average). Therefore, for those
days when the published sediment discharge value differs
from the value computed as the product of discharge times
mean concentration times 0.0027, the reader can assume that
the sediment discharge for that day was computed by the
subdivided-day method. For periods when no samples were
collected, daily discharges of suspended sediment were
estimated on the basis of water discharge, sediment
concentrations observed immediately before and after the
periods, and suspended-sediment loads for other periods of
similar discharge.
At other stations, suspended-sediment samples are collected
periodically at many verticals in the stream cross section.
Although data collected periodically may represent
conditions only at the time of observation, such data are
useful in establishing seasonal relations between quality
and streamflow and in predicting long-term
sediment-discharge characteristics of the stream.
In addition to the records of suspended-sediment discharge,
records of the periodic measurements of the particle-size
distribution of the suspended sediment and bed material are
included for some stations.
Laboratory Measurements
Samples for biochemical oxygen demand (BOD) and indicator
bacteria are analyzed locally. All other samples are
analyzed in the USGS laboratory in Lakewood, Colorado,
unless otherwise noted. Methods used in analyzing sediment
samples and computing sediment records are given in TWRI,
Book 5, Chapter C1. Methods used by the USGS laboratories
are given in the TWRIs, Book 1, Chapter D2; Book 3, Chapter
C2; and Book 5, Chapters A1, A3, and A4. The TWRI
publications may be accessed from http://water.usgs.gov/pubs/twri/.
These methods are consistent with ASTM standards and
generally follow ISO standards.
Data Presentation
For continuing-record stations, information pertinent to
the history of station operation is provided in descriptive
headings preceding the tabular data. These descriptive
headings give details regarding location, drainage area,
period of record, type of data available, instrumentation,
general remarks, cooperation, and extremes for parameters
currently measured daily. Tables of chemical, physical,
biological, radiochemical data, and so forth, obtained at a
frequency less than daily are presented first. Tables of
"daily values" of specific conductance, pH, water
temperature, dissolved oxygen, and suspended sediment then
follow in sequence.
In the descriptive headings, if the location is identical
to that of the discharge gaging station, neither the
LOCATION nor the DRAINAGE AREA statements are repeated. The
following information is provided with each
continuous-record station. Comments that follow clarify
information presented under the various headings of the
station description.
LOCATION.-See Data Presentation information in the
EXPLANATION OF STAGE- AND WATER-DISCHARGE RECORDS section
of this report (same comments apply).
DRAINAGE AREA.-See Data Presentation information in the
EXPLANATION OF STAGEAND WATER-DISCHARGE RECORDS section of
this report (same comments apply).
PERIOD OF RECORD.-This indicates the time periods for which
published water-quality records for the station are
available. The periods are shown separately for records of
parameters measured daily or continuously and those
measured less than daily. For those measured daily or
continuously, periods of record are given for the
parameters individually.
INSTRUMENTATION.-Information on instrumentation is given
only if a water-quality monitor temperature record,
sediment pumping sampler, or other sampling device is in
operation at a station.
REMARKS.-Remarks provide added information pertinent to the
collection, analysis, or computation of the records.
COOPERATION.-Records provided by a cooperating organization
or obtained for the USGS by a cooperating organization are
identified here. EXTREMES.-Maximums and minimums are given
only for parameters measured daily or more frequently. For
parameters measured weekly or less frequently, true
maximums or minimums may not have been obtained. Extremes,
when given, are provided for both the period of record and
for the current water year.
REVISIONS.-Records are revised if errors in published
water-quality records are discovered. Appropriate updates
are made in the USGS distributed data system, NWIS, and
subsequently to its Web-based national data system, NWISWeb
(http://waterdata.usgs.gov/nwis).
Users of USGS water-quality data are encouraged to obtain
all required data from NWIS or NWISWeb to ensure that they
have the most recent updates. Updates to the NWISWeb are
made on an annual basis.
The surface-water-quality records for partialrecord
stations and miscellaneous sampling sites are published in
separate tables following the table of discharge
measurements at miscellaneous sites. No descriptive
statements are given for these records. Each station is
published with its own station number and name in the
regular downstream-order sequence.
Remark Codes
The following remark codes may appear with the
water-quality data in this section:
| Printed Output |
Remark |
| E |
Value is estimated. |
| > |
Actual value is known to be greater than the value
shown. |
| < |
Actual value is known to be less than the value shown. |
| M |
Presence of material verified, but not quantified. |
| N |
Presumptive evidence of presence of material. |
| U |
Material specifically analyzed for, but not detected. |
| A |
Value is an average. |
| V |
Analyte was detected in both the environmental sample and
the associated blanks. |
| S |
Most probable value. |
Water-Quality Control Data
The USGS National Water Quality Laboratory collects
quality-control data on a continuing basis to evaluate
selected analytical methods to determine long-term method
detection levels (LTMDLs) and laboratory reporting levels
(LRLs). These values are re-evaluated each year on the
basis of the most recent quality-control data and,
consequently, may change from year to year.
This reporting procedure limits the occurrence of false
positive error. Falsely reporting a concentration greater
than the LT-MDL for a sample in which the analyte is not
present is 1 percent or less. Application of the LRL limits
the occurrence of false negative error. The chance of
falsely reporting a nondetection for a sample in which the
analyte is present at a concentration equal to or greater
than the LRL is 1 percent or less.
Accordingly, concentrations are reported as less than LRL
for samples in which the analyte either was not detected or
did not pass identification. Analytes detected at
concentrations between the LT-MDL and the LRL and that pass
identification criteria are estimated. Estimated
concentrations will be noted with a remark code of "E."
These data should be used with the understanding that their
uncertainty is greater than that of data reported without
the E remark code.
Data generated from quality-control (QC) samples are a
requisite for evaluating the quality of the sampling and
processing techniques as well as data from the actual
samples themselves. Without QC data, environmental sample
data cannot be adequately interpreted because the errors
associated with the sample data are unknown. The various
types of QC samples collected by a USGS Water Science
Center are described in the following section. Procedures
have been established for the storage of
water-quality-control data within the USGS. These
procedures allow for storage of all derived QC data and are
identified so that they can be related to corresponding
environmental samples. These data are not presented in this
report but are available from the USGS Water Science Center
in the State where the Station is located.
Blank Samples
Blank samples are collected and analyzed to ensure that
environmental samples have not been contaminated in the
overall data-collection process. The blank solution used to
develop specific types of blank samples is a solution that
is free of the analytes of interest. Any measured value
signal in a blank sample for an analyte (a specific
component measured in a chemical analysis) that was absent
in the blank solution is believed to be due to
contamination. Many types of blank samples are possible;
each is designed to segregate a different part of the
overall data-collection process. The types of blank samples
potentially collected by USGS Water Science Centers are:
Field blank-A blank solution that is subjected to all
aspects of sample collection, field processing
preservation, transportation, and laboratory handling as an
environmental sample.
Trip blank-A blank solution that is put in the same type of
bottle used for an environmental sample and kept with the
set of sample bottles before and after sample collection.
Equipment blank-A blank solution that is processed through
all equipment used for collecting and processing an
environmental sample (similar to a field blank but normally
done in the more controlled conditions of the office).
Sampler blank-A blank solution that is poured or pumped
through the same field sampler used for collecting an
environmental sample.
Filter blank-A blank solution that is filtered in the same
manner and through the same filter apparatus used for an
environmental sample.
Splitter blank-A blank solution that is mixed and separated
using a field splitter in the same manner and through the
same apparatus used for an environmental sample.
Preservation blank-A blank solution that is treated with
the sampler preservatives used for an environmental sample.
Reference Samples
Reference material is a solution or material prepared by a
laboratory. The reference material composition is certified
for one or more properties so that it can be used to assess
a measurement method. Samples of reference material are
submitted for analysis to ensure that an analytical method
is accurate for the known properties of the reference
material. Generally, the selected reference material
properties are similar to the environmental sample
properties.
Replicate Samples
Replicate samples are a set of environmental samples
collected in a manner such that the samples are thought to
be essentially identical in composition. Replicate is the
general case for which a duplicate is the special case
consisting of two samples. Replicate samples are collected
and analyzed to establish the amount of variability in the
data contributed by some part of the collection and
analytical process. Many types of replicate samples are
possible, each of which may yield slightly different
results in a dynamic hydrologic setting, such as a flowing
stream. The types of replicate samples collected in this
district are:
Concurrent samples-A type of replicate sample in which the
samples are collected simultaneously with two or more
samplers or by using one sampler and alternating the
collection of samples into two or more compositing
containers.
Sequential samples-A type of replicate sample in which the
samples are collected one after the other, typically over a
short time.
Split sample-A type of replicate sample in which a sample
is split into subsamples, each subsample contemporaneous in
time and space.
Spike Samples
Spike samples are samples to which known quantities of a
solution with one or more well-established analyte
concentrations have been added. These samples are analyzed
to determine the extent of matrix interference or
degradation on the analyte concentration during sample
processing and analysis.
Generally, only ground-water-level data from selected wells
with continuous recorders from a basic network of
observation wells are published in this report. This basic
network contains observation wells located so that the most
significant data are obtained from the fewest wells in the
most important aquifers.
Site Identification Numbers
Each well is identified by means of (1) a 15- digit number
that is based on latitude and longitude and (2) a local
number that is produced for local needs. See NUMBERING
SYSTEM FOR WELLS AND MISCELLANEOUS SITES in this report for
a detailed explanation.
Data Collection and Computation
Measurements are made in many types of wells, under varying
conditions of access and at different temperatures; hence,
neither the method of measurement nor the equipment can be
standardized. At each observation well, however, the
equipment and techniques used are those that will ensure
that measurements at each well are consistent.
Most methods for collecting and analyzing water samples are
described in the TWRIs referred to in the Onsite
Measurements and Sample Collection and the Laboratory
Measurements sections in this report. In addition, TWRI
Book 1, Chapter D2, describes guidelines for the collection
and field analysis of ground-water samples for selected
unstable constituents. Procedures for onsite measurements
and for collecting, treating, and shipping samples are
given in TWRIs Book 1, Chapter D2; Book 3, Chapters A1, A3,
and A4; and Book 9, Chapters A1 through A9. The TWRI
publications may be accessed from http://
water.usgs.gov/pubs/twri/. The values in this report
represent water-quality conditions at the time of sampling,
as much as possible, and that are consistent with available
sampling techniques and methods of analysis. These methods
are consistent with ASTM standards and generally follow ISO
standards. Trained personnel collected all samples. The
wells sampled were pumped long enough to ensure that the
water collected came directly from the aquifer and had not
stood for a long time in the well casing where it would
have been exposed to the atmosphere and to the material,
possibly metal, comprising the casings.
Water-level measurements in this report are given in feet
with reference to land-surface datum (lsd). Land-surface
datum is a datum plane that is approximately at land
surface at each well. If known, the elevation of the
land-surface datum above sea level is given in the well
description. The height of the measuring point (MP) above
or below land-surface datum is given in each well
description. Water levels in wells equipped with recording
gages are reported for every fifth day and the end of each
month (EOM).
Water levels are reported to as many significant figures as
can be justified by the local conditions. For example, in a
measurement of a depth of water of several hundred feet,
the error in determining the absolute value of the total
depth to water may be a few tenths of a foot, whereas the
error in determining the net change of water level between
successive measurements may be only a hundredth or a few
hundredths of a foot. For lesser depths to water the
accuracy is greater. Accordingly, most measurements are
reported to a hundredth of a foot, but some are given only
to a tenth of a foot or a larger unit.
Data Presentation
Water-level data are presented in alphabetical order by
county. The primary identification number for a given well
is the 15-digit site identification number that appears in
the upper left corner of the table. The secondary
identification number is the local or county well number.
Well locations are shown and each well is identified by its
local well or county well number on a map in the local
Water Science Center's Annual Scientific Investigation
Report by State, and may be accessed from. . .
Each well record consists of three parts: the well
description, the data table of water levels observed during
the water year, and, for most wells, a hydrograph following
the data table. Well descriptions are presented in the
headings preceding the tabular data. The following comments
clarify information presented in these various headings.
LOCATION.-This paragraph follows the well-identification
number and reports the hydrologic-unit number and a
geographic point of reference. Latitudes and longitudes
used in this report are reported as North American Datum of
1927 unless otherwise specified.
AQUIFER-.This entry designates by name and geologic age the
aquifer that the well taps.
WELL CHARACTERISTICS-.This entry describes the well in
terms of depth, casing diameter and depth or screened
interval, method of construction, use, and changes since
construction.
INSTRUMENTATION-.This paragraph provides information on
both the frequency of measurement and the collection method
used, allowing the user to better evaluate the reported
water-level extremes by knowing whether they are based on
continuous, monthly, or some other frequency of
measurement.
DATUM-.This entry describes both the measuring point and
the land-surface elevation at the well. The altitude of the
land-surface datum is described in feet above the altitude
datum; it is reported with a precision depending on the
method of determination. The measuring point is described
physically (such as top of casing, top of instrument shelf,
and so forth), and in relation to land surface (such as 1.3
ft above land-surface datum). The elevation of the
land-surface datum is described in feet above National
Geodetic Vertical Datum of 1929 (NGVD 29); it is reported
with a precision depending on the method of determination.
REMARKS-.This entry describes factors that may affect the
water level in a well or the measurement of the water
level, when various methods of measurement were begun, and
the network (climatic, terra ne, local, or areal effects) or
the special project to which the well belongs.
PERIOD OF RECORD.-This entry indicates the time period for
which records are published for the well, the month and
year at the start of publication of water-level records by
the USGS, and the words "to current year" if the records
are to be continued into the following year. Time periods
for which water-level records are available, but are not
published by the USGS, may be noted.
EXTREMES FOR PERIOD OF RECORD.-This entry contains the
highest and lowest instantaneously recorded or measured
water levels of the period of published record, with
respect to land-surface datum or sea level, and the dates
of occurrence.
Water-Level Tables
A table of water levels follows the well description for
each well. Water-level measurements in this report are
given in feet with reference to either sea level or
land-surface datum (lsd). Missing records are indicated by
dashes in place of the water-level value.
For wells not equipped with recorders, water-level
measurements were obtained periodically by steel or
electric tape. Tables of periodic water-level measurements
in these wells show the date of measurement and the
measured water-level value.
Hydrographs
Hydrographs are a graphic display of water-level
fluctuations over a period of time. In this report, current
water year and, when appropriate, period-of-record
hydrographs are shown.
Hydrographs that display periodic water-level measurements
show points that may be connected with a dashed line from
one measurement to the next. Hydrographs that display
recorder data show a solid line representing the mean water
level recorded for each day. Missing data are indicated by
a blank space or break in a hydrograph. Missing data may
occur as a result of recorder malfunctions, battery
failures, or mechanical problems related to the response of
the recorder's float mechanism to water-level fluctuations
in a well.
Data Collection and Computation
The ground-water-quality data in this report were obtained
as a part of special studies in specific areas.
Consequently, a number of chemical analyses are presented
for some wells within a county but not for others. As a
result, the records for this year, by themselves, do not
provide a balanced view of ground-water quality statewide.
Most methods for collecting and analyzing water samples are
described in the TWRIs, which may be accessed from http://water.usgs.gov/pubs/twri/.
Procedures for onsite measurements and for collecting,
treating, and shipping samples are given in TWRI, Book 1,
Chapter D2; Book 5, Chapters A1, A3, and A4; and Book 9,
Chapters A1-A6. Also, detailed information on collecting,
treating, and shipping samples may be obtained from the
local USGS Water Science Center.
Laboratory Measurements
Analysis for sulfide and measurement of alkalinity, pH,
water temperature, specific conductance, and dissolved
oxygen are performed onsite. All other sample analyses are
performed at the USGS laboratory in Lakewood, Colorado,
unless otherwise noted. Methods used by the USGS laboratory
are given in TWRI, Book 1, Chapter D2 and Book 5, Chapters
A1, A3, and A4, which may be accessed from http://water.usgs.gov/pubs/twri/.
| 