Field Screening Methods for Radioactive Contamination


United States	Environmental Monitoring	November 1990

Environmental Protection	Systems Laboratory

Agency	P.O. Box 93478

	^ V^as NV 89193-3478 		

OFFICE OF RESEARCH AND DEVELOPMENT	TECHNOLOGY SUPPORT PROJECT

&EPA Field Screening

Methods for
Radioactive

INTRODUCTION

The complexity of hazardous
waste sites presents a
challenge to field scientists
and decision makers in the
remediation process. There
is growing concern in the
technical and secular com-
munities about the likelihood
of radioactive contaminants
at sites previously thought to
contain only organic or
inorganic material. Hazard-
ous waste site problems can
be described broadly as:

• Low level without radioac-
tive contamination

High level without radioac-
tive contamination

Low level with low level
radioactive contamination

Low level with high level
radioactive contamination

High level with low level
radioactive contamination

Radioactive contamination
only

High level with high level
radioactive contamination

Surveys are recommended
for sites that are suspected of

containing radioactive waste.
This cautionary measure can
identify problems early in the
site characterization proce-
dure and can isolate areas
that require special care in
the remediation program.

Portable instruments are
available that will determine
the presence of radioactive
hot spots in a quick, semi-
quantitative manner. These
instruments are not isotope
specific, but do identify the
source as an alpha, beta, or
gamma ray emitter.

INSTRUMENTATION

EPA
EMSL-
TSP-
1190x

Several portable instruments
are commercially available
that can detect alpha, beta,
and gamma radiation. The
alpha counter is a separate
unit from the beta/gamma
counter. Each is battery
operated, smaller than a
shoebox, and easily man-
aged by one field scientist.
The beta/gamma counter
operates in two modes: with
the shield closed, it detects

gamma rays; with the shield
open, it detects beta plus
gamma rays. The amount of
beta radiation can be deter-
mined by the subtraction of
gamma from beta plus
gamma. The readings are
displayed on an analog meter
in millirems/hour or counts/
minute.

Another device that is
amenable to field survey use

is the portable ion chamber.
It is a hand-held instrument
with charged gas in a cham-
ber and is useful for the
detection of gamma radiation.

A "pancake" detector is often
used for quick screening of
clothing and flat surfaces. It
is sensitive to beta and
gamma radiation and gets its
name from its flat round
shape.

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Portable radiation survey
instruments are calibrated
with laboratory sources
placed at various distances
from the detectors before the
site survey. A sampling grid
is established following data
quality objective goals. Once
the instruments are ready
and ail health and safety
precautions have been
addressed by the field team,

the survey can begin. A
typical approach may consist
of two field personnel, one
with an alpha counter and the
other with a beta/gamma
(also known as Geiger)
counter. Each sampler would
have a log book in which to
record the readings at the
pre-ordained locations on the
grid. Due to the character of
gamma radiation, gamma

signals will be detected and
counted. It is important that
the sampler hold the counter
just above the ground surface
consistently through the
study. For screening pur-
poses, it is essential that any
radiation greater than back-
ground level be investigated
further to assure a thorough
knowledge of the radioactive
character of the site.

Commercially available
detectors are generally
reliable, consistent and easy
to use. The strong advan-
tage of knowing the radioac-
tive character of a hazardous
waste site is obvious. It
allows future characterization
and remediation to be
performed intelligently and
safely.

When combined with a
carefully planned laboratory
confirmation, field screening

can be a quick and effective
method for assessing the
extent and location of radio-
active contamination. Liquid
scintillation methods, alpha/
beta counting, alpha spec-

Advantages

•	Rapid, real-time results

•	Low cost (compared with
full laboratory analysis)

•	Easy to use

troscopy, and high resolution
gamma spectroscopic
methods can identify the
isotopes and better quantify
the radioactivity at the site.

Limitations

¦ Inability to probe beneath
surface

•	Doesn't reveal specific
isotope identity

•	Difficulty detecting tritium

A low-energy photon detector
system (LEPS) is being
investigated for use at mixed-
waste sites. Using germa-
nium diodes with a high

sensitivity to gamma-and x-
ray energies, this detector
can be encased in a water-
tight container and used
above ground or lowered into

a drilled borehole. This
technology promises remote
sensing of radiation by the
employment of rugged,
submersible detectors.

REFERENCES

Field Monitoring Standard Operating Procedures, U.S. EPA Field Monitoring Branch, #003
EMSL-ORS, 1990, 88 pp.

Moe, H. J., and E. J. Vallario, Operational Health Physics (particularly Chs. 10-12), ANL
publication #88-26, 1988, 930 pp.

FOR FURTHER INFORMATION

For further details on field screening meth-
ods for radioactive contamination, contact:

Mr. Terry Grady
Nuclear Radiation Division
U.S. Environmental Protection Agency
Environmental Monitoring
Systems Laboratory
P.O. Box 93478

Las Vegas, Nevada 89193-3478

(702) 798-2136
FTS 545-2136

For general Technology Support information,
contact:

Mr. Ken Brown, Manager

Technology Support Center

U.S. Environmental Protection Agency

Environmental Monitoring Systems Laboratory

P.O. Box 93478

Las Vegas, NV 89193-3478

(702) 798-2270/734-3207
FTS 545-2270
FAX/FTS 545-2637

The Technology Support Center fact sheet series is developed and written by
Clare L. Gerlach, Lockheed Engineering & Sciences Company, Las Vegas.

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