Native fluorescence imaging direct push probe

We claim: 1. A fluorescence imaging method comprising the following steps: penetrating a subsurface soil environment to a given depth with a cone penetration testing (CPT) direct push probe; illuminating through a window in the probe the subsurface soil adjacent to the probe at the given depth with white light; recording, in-situ and in real time, a first image of the white-light-illuminated subsurface soil at the given depth; illuminating through the window the subsurface soil adjacent to the probe at the given depth with only ultra violet (UV) light such that fluorescence is excited in microbes and minerals that may be present in the subsurface soil at the given depth; recording, in-situ and in real time, a second image of the UV-light-illuminated subsurface soil at the given depth after the UV excitation light has been filtered from the second image such that only the fluorescence response is recorded; superimposing the second image over the first image to create a composite image of the subsurface soil; and quantifying a capability of the soil at the given depth to naturally attenuate contaminants; assessing and managing a spatial variability of geochemical and microbiological conditions; and delineating contaminants in low-permeability zones. 2. The method of claim 1 , wherein the first and second images are recorded with a charge-coupled device (CCD) camera. 3. The method of claim 2 , wherein the probe is pushed to a plurality of depths at a given location and wherein a separate composite image is created at each depth. 4. The method of claim 3 , wherein the probe is pushed at least 2 meters below a soil surface. 5. A fluorescence imaging method comprising the following steps: penetrating a subsurface soil environment to a plurality of depths at a given location with a cone penetration testing (CPT) direct push probe; illuminating through a window in the probe the subsurface soil adjacent to the probe at the given depth with white light; recording, in-situ and in real time, a first image of the white-light-illuminated subsurface soil at the given depth; illuminating through the window the subsurface soil adjacent to the probe at the given depth with only ultra violet (UV) light such that fluorescence is excited in microbes and minerals that may be present in the subsurface soil at the given depth; recording, in-situ and in real time, a second image of the UV-light-illuminated subsurface soil at the given depth after the UV excitation light has been filtered from the second image such that only the fluorescence response is recorded, wherein the first and second images are recorded with a charge-coupled device (CCD) camera; superimposing the second image over the first image to create a composite image of the subsurface soil, wherein a separate composite image is created at each depth; and determining biogeochemical processes that are occurring in the subsurface soil at each of the plurality of depths based on the composite image taken at each depth. 6. The method of claim 2 , wherein the UV excitation light is filtered from the second image by a longpass optical filter before the second, induced fluorescence image is recorded by the CCD camera. 7. The method of claim 3 , wherein the composite images are created at a spatial scale commensurate with a distribution of contaminants that are desired to be studied. 8. The method of claim 1 , further comprising the step of determining where natural attenuation of contaminants is occurring in the soil. 9. The method of claim 7 , wherein the probe is continuously pushed through the subsurface soil, and wherein the illuminating steps are performed with rapid flashes of white light and UV light.