A laboratory testing program was conducted to identify and interpret the fu
ndamental factors affecting the performance of a new microchip-laser based
fluorescence sensor in soil and ground water. Investigations were performed
using a versatile experimental apparatus designed to simulate the in situ
interface between the laser induced fluorescence (LIF) sensor and contamina
ted media while providing complete control of test conditions. Attempts wer
e made to isolate the effects of soil properties such as grain size, soil t
ype, color, mineralogy, and organic content on in situ LIF observations. Te
st results indicate that soil has no measurable effect on the determination
of pore fluid fluorescence lifetimes or the general form of pore fluid emi
ssion wavelength profiles. However, for a given contaminant concentration i
n the pore space of a soil with a narrow grain size distribution, decreases
in soil grain size are accompanied by a decrease in the magnitude and vari
ability of observed LIF signals. For soils containing a wide range of parti
cle sizes, in-soil LIF observations are primarily influenced by pore space
geometry in relation to the smallest particles present in the soil. These t
rends were found to be a primary function of the volume of pore fluid in a
soil specimen that is in the direct path of laser excitation energy. Soil o
rganic content and optical characteristics such as reflectivity also have p
otential influence on in-soil LIF observations, although on a secondary bas
is. After reviewing these experimental results, which indicate the relative
impact of soil properties on fluorescence observations, a simple geometric
model is presented that captures the primary effects of soil on pore fluid
fluorescence observations.