KANSAS PRIVATE WATER WELLS SURVEY
Khalid M. Kalout
Kansas Department of Health and Environment, Bureau of Air and Radiation
Topeka, KS

ABSTRACT

The potential for high radon in private well-water is a particular concern in Kansas where about 360,000
rural residents (about 16 % of Kansas population) use groundwater from private supplies wells as their primary water
source. Because of the costly expense associated with monitoring, a national systematic survey of radon in private
well-water has not been performed. In Kansas, a state wide radon survey of private wells was conducted between
June and September 1995.
This survey was the first of its kind in Kansas that addressed:
-To what extent are rural Kansas residents, who utilize private well water, being exposed to indoor radon
off-gassed from waterborne radon?
-What percentage of private well sites sampled have radon concentrations that exceed the maximum
concentration (MCL) limits for public drinking water supplies?

-Are there any regional radon distribution trends in Kansas well-water?
-Do private well-water supplies in Kansas have higher concentrations of radon than Kansas public groundwater supplies?
-Do well-water radon concentrations vary compared to sub geology in Kansas?
While radon level will be determined in a subpopulation of private wells, the primary thrust of this survey will be to
examine the radon level in a sample of 500 private wells in Kansas.

INTRODUCTION
Many of the rocks and soils in Kansas have the potential to generate levels of radon exceeding that of the
US Environmental Protection Agency (USEPA) action level (I).
Indoor Radon Data in Kansas
Indoor radon screening measurements from 2,031 homes sampled in the StateEPA Residential Radon
Survey conducted in Kansas during the winter of 1987-1988 are shown in figure 1. The maximum value recorded in
the survey was 48 pCi1L in Marshall county, 25.8 % of the measurements exceeded 4 pCi11, state average was 3.51
pCa, standard deviation was 3.74 pCa, standard error of the mean was *0.083, coefficient of variation was 106 %.
Except for counties in the Kansas City, Topeka, and Wichita areas, most counties in the survey are represented by
20 or fewer indoor radon measurements; 19 counties have more than 20 measurements.
Based on StateIEPA survey most counties in southeastern and south-central Kansas have low (0-2 pCi/1) to
moderate (2-4 pCa) indoor radon averages. Counties in northeastern Kansas have moderate to high (> 4 pCiA)
indoor radon averages. Most of the counties in north-central and central Kansas have high indoor radon averages,
and western Kansas has an approximately equal mixture of counties with moderate and high indoor radon averages

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1996 International Radon Symposium 1 7.1

(Fig. 1). The highest maximum radon readings occurred in northeastern and central ~ansas^.
The Kansas statewide indoor radon database has been expanded to 15,495 data points (Fig.2). This database
includes the initial 1987-1988 survey data and subsequently obtained screening measurements from RPP listed
companies. The maximum value recorded in this database is 204 pCiA in Clay county. The state average radon level
is 4.35 pCi/l, the number of measurements above EPA action level were 5,646 (36.5% up from 25.8%), standard
deviation is 6.06, standard error of the mean is i0.048, coefficient of variation 139 %.
STATEWIDE PRIVATE WATER WELL SURVEY

The Statewide Private Water Well Survey (SPWWS) sampling frame was used from June to September,
1995 to assess radon concentrations in private well-water by collecting samples from 500 private wells. A sampling
kit containing four 20 ml vials along with a detailed instruction sheet were sent to local sanitarians and members of
the flood state response team working on phase I1 of the Center for Disease Control (CDC) study (targeted private
wells that been affected by the flood of 1993). The team members collected their samples and took the time to
collect the radon samples. Water samples were sent in to the Kansas Department of Health and Environment
(KDHE) lab within 24 hours for analysis.
Sample Collections
The sample collection team were trained to obtain the samples using EPA Sampling Procedures. Generally,
the training focused on collecting the sample in a manner that minimized radon lost to the atmosphere. Instructions
which accompanied the collection kit included questions regarding collection site, collection time and any other
information that was worth noting. The instructions directed the sample collectors to use a 20 ml vial to obtain a
sample of water from an indoor faucet. The cold water faucet was allowed to run for about 10 minutes before the
sample was collected. During the sampling the water was run allowed to run slowly to eliminate air bubbles from
being introduced into the sample, and then the vial was capped as quickly as possible and returned promptly to the
lab.
Analysis of Samples
- Apparatus
. Sample collection kits.
.Liquid scintillation counting system with automatic sample changer (Beckman-230, Wallaz 1409)

- Reagents
.Scintillation counting solution: mineral oil based scintillator (New England Nuclear Corp.

Cat.# PSS-

007H) or Opti-Fluor 0 (Puckered Instrument Co.)

- Calibrations
. Counter Efficiency
1. Add a known quantity of Ra-226 standard solution to a known volume of water.
2. Combine 10 ml aliquot of the Ra-226 standard solution with 10 ml of the scintillation counting solution
in a 1.0 ml low potassium glass scintillation vial.
3. Allow approximately 21 days for buildup of radon daughters.
4. Count the standard and background samples for 50 minutes or longer.

1996 International Radon Symposium I - 7.2

(Fig. 1) 1987-1988 StateEPA Survey

Average Radon Level

by county (pCiIL)

(Fig. 2) Current State Database

-

1996 International Radon Symposium I 7.3

5. Subtract the background cpm from the gross cpm for the standard and divide by the known radon activity (Rn222 activity equals Ra-226 activity) to obtain the cpm/pCi conversion factor.

Procedures
1. A waiting period of at least 3 hours should be observed between the collection and counting of the
sample in order to allow the ingrowth of Rn-222 daughters.
2. Before counting, the outer walls of the scintillation vial should be cleaned with ethyl alcohol.
3. At least one standard and one background sample should be counted in a set of samples to be analyzed.
4. Record the cpm of standard, background and samples and calculate Rn-222 concentrations in the
samples^).
Calculations
The pCi11 of Rn-222 in the sample were calculated by using the following equation :
Rn-222 (pCVI) = ((Cs - Cb) x 100) / CF x D
Where
Cs:
Cb:
CF:
D:

Sample cpm
Background cpm
Conversion factor (cpm/pCi)
Decay correction = exp (-0.693 x (Titla))
T:Time elapsed (day) between sample collection to midpoint of counting time.
tiI2:Half-lifeof Rn-222 (3.82 days)

Note: The analyst could use the Radiochemistry Laboratory computer program called "RNCAL" to calculate the Rn222 concentration. The RNCAL will accept a set of duplicate analytical results then perform a statistical test (the 4D test) to determine any outlives. The outlives will be rejected and the mean value of the duplicate results will be
determined.
Quality Control
Triplicate analysis was performed for each sampling location. Each batch of samples were analyzed along
with a QA sample and a standard. The QA sample had a known quantity of Rn-222 (Ra-226). The batch of samples
was recounted whenever the result of the QA sample was out of the control limit.
The holding time of Rn-222 sample was four days. Samples which exceeded the holding time were
analyzed as well. However, a remark indicating the sample exceeded the required holding time was reported.
Detection Limit
A detection limit of 25 pCiA was achieved with the described method when 10 ml of water sample was
counted for 60 minutes with the liquid scintillation analyzer.
SUMMARY OF THE STATEWIDE PRIVATE WATER WELL STUDY
Data that met any of the following exclusion criteria were eliminated from summary data set: water sample
received after four days, water samples with leaky or broken vial, water samples with no information on location, and
water samples with less than ten ml of water. Satisfactory samples for inclusion in the summary (SPWWS)data set
were obtained from 383 sites. The radon concentration in the samples ranged from 25 pCiA to 7,085 pCi11 in Logan
County, with an average of 593 pCi/1, standard deviation 612.36 pCil1, standard error Â±31.2 pCif1. About 63.4%
percent exceeded 300 pCi11 and only two measurements exceeded 3,000 pCiA (Fig 3,4).

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1996 International Radon Symposium I 7.4

State of Kansas Radon measurements
Private well water

AVG = 593 pCUL

STOS a 612 pCUL
SEM = 32 pCiiL
N = 375
MIN 12.5 pCUL
MAX = 7085 pCUL

-

Geometric mean = 357 pCUL

2 measurements woro > 3000 pCUL

State of Kansas Radon measurements
Private well water

la0

200
No.of observations

-

Average = 593 +I- 32 p C L

(Fig. 4)

1996 International Radon Symposium 1 - 7.5

300

Presenting The Data
Using Mapinfo. a desktop mapping system, the data were assigned coordinates for each record so that the
system knows where to spot the record on the map. This process is known as geocoding. Once the geocoding was
completed, the data were ready to be displayed on the map. The data were presented on a county level reflecting that
county's average, also the data can be presented on zipcode or street address level; but for confidentiality reasons
the average on a county level have been selected (Fig.5).

Average radon concentration
! in Private Water Wells by county
I

1500 and above
iooot01500
600 to 1000
300 to 600
0 to 300

pCi/L
pci/L
PC&
PCi/L
PC&

,
i

;

!

I

i

1

i

I

(Fig. 5)

1996 International Radon Symposium I - 7.6

EPA'S MAP OF RADON ZONES

The USGS Geologic Radon Province Map is the technical foundation for EPA's Map of Radon Zones. The
Map of Radon Zones is based on the same range of predicted screening levels of indoor radon as USGS Geologic
Radon Province Map. EPA defines the three zones as follows: Zone One areas have an average predicted indoor
radon screening potential greater than 4 pCi/L. Zone Two areas are predicted to have an average indoor radon
screening potential between 2 pCi/L and 4 pCi/L. Zone Three areas are predicted to have an average indoor radon
screening potential less than 2 pCiA ( ^ ( ~ i g6).
Kansas Mac of Radon Zones
The Kansas Map of Radon Zones and its supporting documentation have received extensive review by
Kansas geologists and radon program experts. The Map of Radon Zones for Kansas generally reflects current state
information on radon levels in all counties (3).
Geoloeic Radon Potential
For the purposes of this assessment, Kansas is divided into six geologic radon potential areas (Fig. 7). Each
area is assigned Radon Index (RI) and Confidence Index (CI) scores (Table 1). The Radon Index is a
sermiquantitative measure of radon potential based on geologic, soil, and indoor radon factors. The Confidence
Index is a measure of the relative confidence of the Rl assessment based on the quality and quantity of data used to
make the predictions. At the scale of this report the outlines of the areas shown on figure 9 are generalized, and the
descriptions given in this text should be compared with more detailed geologic and other maps (').
Area PPR is underlain by Pennsylvanian and Permian rocks. Homes in this area may have indoor radon
levels ranging from low (<2 pCiA) to high (>4 pCi/l), depending on the local underlying geology and presence and
thickness of loess cover. Additional indoor radon data compiled by the Kansas Department of Health and
Environment (written communication, 1992) suggest that more homes in this area have moderate to high indoor
radon levels than are indicated by the StateIEPA Residential Radon Survey data. As a consequence the indoor radon
factor was assigned 2 points, but because the data was partially from a non-randomly-sampled volunteer source, the
factor was given 2, rather than 3, confidence index points. Homes built on uranium-bearing Pennsylvanian black
shales within this area may have locally high indoor radon levels. Some areas underlain by carbonate rocks
(limestones and dolomites) may have locally elevated indoor radon levels, especially if solution features or clay-rich
residual soils have developed (the residual soils are commonly red or orange-red in color due to concentration of
iron oxides in the residuum). Some domestic wells drawing water from lower Paleozoic aquifers in this area may
contribute to elevated radon levels by release of dissolved radon from the water into the indoor air. Area PPR is
assigned a moderate or variable overall radon potential (RI=9) with moderate confidence (CH)('I.
Area GLA is underlain by glacial drift and loess of varying thickness. Although the bedrock source for the
glacial drift can be traced as far as the Canadian Shield, a large proportion of the drift is relatively locally derived
from underlying and nearby Paleozoic sedimentary rocks that are relatively poor radon sources. Higher permeability
of the drift relative to bedrock, the presence of crystalline glacial erratics, and the variability of loess cover and
source (primarily glacially derived) cause this area to have moderate to high radon potential, and it is assigned an
overall high geologic radon potential (RI=12), with a high confidence index (0=10) @).
Area MCR is an area of faults and fractures related to the Mid-Continent Rift zone. Homes sited on unfaulted
Permian bedrock in this area are likely to have low radon levels, but those sited on surface or near-surface faults or
fractures may have locally high indoor radon levels. The boundaries of the area are drawn along major subsurface
faults that delineate the rift system (Berendsen and others, 1989). Overall, area MCR is assigned a high radon
potential (R. =12) with high confidence (0=10) (3).

1996 International Radon Symposium I - 7.7

(Fig. 6) EPA'S MAP OF RADON ZONES FOR KANSAS

(Fig. 7) Geologic Radon Potential Areas of Kansas

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1996 International Radon Symposium 1 7.8

Area KR delineates the bedrock outcrop pattern of Cretaceous sedimentary rocks in Kansas. Parts of this
area. particularly the western part are covered by discontinuous loess deposits. Gray and black shale Units of the
Pierre Shale typically generate moderate to high indoor radon levels. The Dakota and Nebraska Formations and the
Pierre Shale are known to contain locally anomalous amounts of uranium and are known producers of elevated radon
in some areas. Overall. area KR has a high radon potential (RI= 1 2) with high confidence (CI= 1 I) (3).
Area TL is mostly underlain by Tertiary rocks, specifically the Ogallala Formation, that are mostly covered
by younger loess deposits. The highest radon levels in this area are expected to occur in homes sited on siliceous
(silica-cemented) Ogallala Formation, particularly in the southwestern part of the State. Radon levels in structures
built on loess deposits are expected to range from moderate to high depending on the thickness and mineralogy of
the loess. Because the indoor radon data indicate that many areas underlain by loess or Tertiary sedimentary rocks
have county average indoor radon levels exceeding 4.0 pCi/L. and because many of the counties in western Kansas
have relatively few sampled homes in the StateIEPA survey, a conservative approach to ranking the area was
adopted. Indoor radon levels in this area are expected to range from low (< 2 pCi/L) to high (> 4 pCi/L) but are
most likely to be in the moderate to high range, so area TL is assigned an overall high radon potential (Rl= 12) with
high confidence (Cl= 11) (3).
DS denotes areas underlain by dune sands in the Arkansas and Cimarron River valleys. The dune sands are
highly permeable, but because they are composed almost entirely of quartz -rains containing little or no uranium or
radium, they ger~erallygenerate low radiation levels. If the deposits are thin (less than approximately 15 ft thick), the
sands are likely to transmit radon from the underlying bedrock toward the ' surface and into homes built on these
deposits. Relatively higher indoor radon levels are also more likely to occur where the sands are mixed with loess
deposits. Area DS is assigned a moderate or variable geologic radon potential (RI= 1O), with a high confidence index
(CI=1 1) ( Table 1) (3).

TABLE 1. Radon Index (RI) and Confidence Index (CI) scores for geologic radon potential
figure 7 for locations of areas ('*).
AREA
PPR
GLA
MCR
KR
TL
RI CI
FACTOR
RI CI
RI CI
RI CI
RI CI
INDOOR RADON
2
2
2 3
3 3
2 3
2 3
RADIOACTIVITY
2
3
2 2
2 3
2 3
2 3
GEOLOGY
2 2
3 3
3 2
3 3
3 3
SOIL PERM.
1 2
2 2
1 2
2 2
2 2
3 ARCHITECTURE
2
3 3
3
GFE POINTS
0
0 0
0
0
9
9
12 10
12 10
TOTAL
12 11
12 11
RANKING
M M
H H
H H
H H
H H

-

RADON INDEX SCORING:
Probable screening indoor
Radon potential cateeorv
Point ranee radon average for area
LOW
3 - 8 points
< 2 pCi&
9 - 11 points 2 - 4 pCiL
MODERATENARIABLE
HIGH
1 1 points
> 4 pCilL
Possible range of points = 3 to 17

-

-

areas of Kansas. See
DS

RI CI
2
1
2
2
3
0
10

3
3
3
2

M

H

-

-

11

CONFIDENCE INDEX SCORING:
LOW CONFIDENCE
4 - 6 points
MODERATE CONFIDENCE 7 9 points
HIGH CONFIDENCE
10 12 points

-

-

Possible range of points = 4 to 12

CONCLUSION

- Based on the finding of the this survey, and considering the ratio 10,00011 pCil1 (10,000 pCil1 radon in water will
contribute to 1 pCit1 to indoor air) there is a very small sector of Kansans who utilize water from private wells that
are being exposed to a small fraction of one pCil1 of indoor radon off-gassed from waterborne radon.

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1996 International Radon Symposium I 7.9

- Of the total private welk tested

63.4 % exceeded the early EPA proposed MCL of 300 pCi/l, and less than 1%
exceeded the newly US Senate approved MCL of 3,000 pCa.

- Private well-water in Kansas have higher concentrations of radon ( the highest measurement recorded is 7,085
pCi/I) than water from Kansas public ground water supplies (the highest measurement recorded is 5,024 pCil1).

- There are eight sectors or regions clearly identified as follows: east and southeast regions ranging between

minimum deduction to about 600 pCi/I, north east region ranging between 600 pCVl to 1000 pCi/l, upper north of the
state has two region one ranged from 1,000 pCVI to 1,500 pCiA, the second ranged from 600 pCiA to 1,000 pCiA,
central region of the state ranging from 300 pCi/l to 600 pCi11, south center region of the state ranging between
minumum deduction to 300 pCiA, the western region having the highest measurements ranged from 1,500 to 1,812
pci.

- Comparing the results of the study with regards to the geologic radon potential areas of Kansas most regions meet
the criteria closely except for the central region.

- The second phase of this survey

is currently underway. This phase will investigate residences that utilize private
water wells and which the radon measurements in the water were above 3,000 pCi/I.

REFERENCE
(I) R Randall ~chumann,Preliminary Geologic Radon Potential Assessment of Kansas, EPA'S Map of Radon
Zones Kansas, EPA, September 1993.
(2) Radiation Chemistry Lab, Kansas Department of Health and Environment.
(3) EPA'S Map of Radon Zones Kansas, EPA, September 1993.
(4) Table 2, R Randall Schumann, Preliminary Geologic Radon Potential Assessment of Kansas, reprinted from
USGS open file report 93-292-G. Table presented in this paper is modified.

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1996 International Radon Symposium 1 7.10