Sper Scientific 840026 Radiation Detection Meter User Manual

11

Neutrons, having no net charge, do not interact with matter

as easily as other particles, and can drift through great

thickness of material without incident. A free neutron, drift-

ing through space, will decay in an average of 11.7 min-

utes, yielding a proton and an electron (beta ray). The neu-

tron can also combine with the nucleus of an atom, if its

path carries it close enough. When a neutron is absorbed

into a nucleus, it is saved from its ultimate fate (decay), but

may render the nucleus unstable. This absorption process

is used in medicine and industry, to create radioactive ele-

ments from non-radioactive ones. Detecting neutrons is

specialized and beyond the scope of typical Geiger count-

ers, but most possible neutron sources also emit gamma

and beta radiation, affording detection of the source.

The highly energetic X-ray and gamma rays lose their en-

ergy as they penetrate matter. X-rays have an energy of up

to about 200,000 eV, compared to gamma radiation which

can be as energetic as several million eV. One million eV

gamma radiation can penetrate an inch of steel. Gamma

and X-ray radiation are by far the most penetrating of all

common types, and are only effectively absorbed by large

amounts of heavy, dense material of high atomic number,

such as lead.

SPECIFICATIONS

*(Cesium 137)

1mR/hr=10µS/hr

model

Calibration

Radiation

Range

Typical

Accuracy

Min/Max

Detection

Energy

840007

Gamma*

0~10 mR/hr

+20%

30 KeV ~

1.5 MeV

840026

Gamma* 0~100 mR/hr

+15%

30KeV ~

1.SMeV