Oil Testing Kit

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Introduction

The Oil Testing Kit is an open source Do-It-Yourself kit which attempts to make it possible to identify oil pollution by type. This means matching a suspected sample with a known sample of crude oil, motor oil, heating oil, or other petroleum-based contaminant using a homemade fluorescence spectrometer, which measures the color of light emitted by carefully prepared samples when they are illuminated with strong ultraviolet light, as shown above.

Collect, Scan, Compare

The process of testing for oils can be described in three overall steps;

collecting samples of suspected oil or tar from the ground, and dissolving small amounts in mineral oil so they are transparent
illuminating the solutions with ultraviolet light -- presently using a 405 nanometer blue laser -- and recording the light spectrum with a DIY spectrometer
comparing the spectrum to those of similarly prepared samples of known pollutant oils, as well as a negative control

Here we will discuss and illustrate these steps in depth.

Collect

Locating samples

Originally, we focused on tar balls which were washing up on US Gulf Coast shorelines following the BP oil spill. These ranged from hard black lumps to orange residue. But oil contamination takes many forms, from residue around a street drain, to a sheen or buildup on the surface of the water. Here are some examples:

Left to right: dried oil on rocks in 2010, Louisiana coast by Cesar Harada CC-BY-NC-SA, oil residue in the ocean in 2010, Louisiana coast by Cesar Harada CC-BY-NC-SA, Oil tanker leak on tracks beside Mississippi River, by @marlokeno

Preparing samples

These should be collected in glass jars and stored in a cool, dark place, as there may always be an opportunity to test them later with more expensive, official means. But for the purposes of the Public Lab Oil Testing Kit, we recommend using cotton swabs or small brushes dipped in mineral oil to remove some of the material and dissolve it in a small, square-sided glass jar of mineral or baby oil. You may need to rub the sample for a while to get it to dissolve. If it does not dissolve, there may be more aggressive ways to dissolve it.

Seal the bottle tightly with the cap. You can then shake the bottle or turn it over to get the residue to dissolve -- it may take some time before the mineral oil takes on a distinct but faint yellowish hue.

Concentration

One big issue is getting the correct concentration of sample dissolved. If it's too little, we may not be able to get it to glow under UV light. Too much and it could be too dark for the light to be visible in the bottle. We recommend a darkness similar to very dilute tea:

Labeling

Label the bottle with the date, time, and location. If you also give it a unique number, any other information can be kept in a notebook next to that number, such as further notes on the location and its condition. Take a photo of the sample with your label, in the place you found the sample, for context.

Scan

Compare

Variations

There are many variations of the process which could be useful. These include:

collecting samples from a sheen on the surface of the water -- which may be difficult as sheens are extremely thin and spread out
measuring fluorescence in-situ, without collecting or concentrating samples in a jar -- which could be difficult as it's very dilute and mixed with other things like water, dirt, or plant matter

Many of these may be future goals of the project, but we are focusing on our primary use case of collecting contaminated soil or residue from the ground, dissolving it in mineral oil, and illuminating it with UV in a spectrometer.

Dissolving samples

We use mineral oil as it's non-toxic and cheap, and can be purchased in most pharmacies as either mineral oil or "baby oil". However, some samples may be hard enough that they don't dissolve readily, and more aggressive solvents may be able to dissolve these, such as methanol or denatured alcohol. These are not as safe to handle, however, so we advise caution if you attempt this. Please post a research note if you attempt this, as it is an unexplored area.

Alpha program

We've sent out about 20 prototype "alpha" kits to people around the US to give the oil test kit a try, and refine it to get ready for a bigger release. If you have one please share what you've done with it and post any ideas, feedback, complaints, suggestions, questions and modifications you have by using this button:

Post about your alpha oil testing kit

Photo walkthrough

Collect everything shown above: mineral oil, swabs, jars, dropper, and a desktop spectrometer.

Use the dropper to fill a jar with mineral oil.

The dropper can become the oil jar's new top! Convenient. Don't get that dropper dirty!

Swab and slightly dissolve some residue, which could be on the ground, on a beach, by a sewer drain, and put it in the jar. Where possible, try not to put too much sand or other stuff in the jar. Wear gloves. It helps if the swab is first wet with mineral oil.

You can move the swab around to dissolve the residue. You're going for a nearly clear color, with just a slight brown tinge.

Seal the bottle, and gently turn it over a bunch of times to help the residue dissolve into the mineral oil.

You may then have to wait for the sediment to settle out. You want the liquid to be quite transparent, with the chunky stuff settled to the bottom.

Shine the blue/violet/UV laser through to see if the material now fluoresces. This sample worked really well!

Label the jar and take good notes about where you got the material and when.

Place it in a box (you can use the desktop spectrometer box itself -- see Mathew L's research note) and illuminate it with the laser again, and save the result in SpectralWorkbench.org.

Coming soon: save the spectrum and try to get it bright enough for the highest point of the curve to fall between 25-75% intensity.

Illustrations

For the illustrated guide:

Related link to spectral challenge draft graphics: https://github.com/jywarren/spectralchallenge/issues/4

Parts list

Possible upgrade: nail polish bottles, with built-in bottlecap-swabs. An all-in-one, one-use pre-filled with mineral oil! Maybe you break off the swab and throw it away, or maybe it doesn't matter.
http://www.ebottles.com/showbottles-bottle-1556-kw-ELIQUID_VIALS.htm
http://www.ebottles.com/showbottles-bottle-1329-gclid-Cj0KEQjwopOeBRC1ndXgnuvx8JYBEiQAq4RPt_MBIoRstpRXJzK66iXV1lbaZ6J7TWOot8oR6wDas7QaAops8P8HAQ-kw-NAIL_POLISH_BOTTLES_WITH_BRUSHES___GLASS.htm
http://www.freundcontainer.com/french-square-glass-bottles/p/v4225B01/
5oz mineral oil (baby oil -- the added fragrance doesn't fluoresce): $3 - http://www.amazon.com/Johnson-Baby-Oil-Kids-Ounce/dp/B000GCJM06/
an eyedropper: $0.05 0 http://www.sciplus.com/p/CAP-WDROPPER_39038
a 405nm blue/violet laser pen: $3 http://www.alibaba.com/product-gs/700677050/well_tested_405_nm_blue_laser.html, or http://www.ebay.com/itm/like/350812684726?lpid=82 to buy just one cuvettes
4 flat-sided jars: $0.35 each - http://www.sciplus.com/p/WHITCAP-BOTTLE_48212
cotton swabs: $0.10
olive oil test sample: $0.17
paper instructions (yet to be made)

Draft instructions

The basic instructions will be something like:

Put on latex or nitrile gloves
Wet a cotton swab with mineral oil
Rub it on the sample -- a suspected tarball or lump of oily residue -- until it gets brownish (it could take a little while for it to dissolve)
Dip the dirty swab (that's like a pirate insult... :-P) in one of the square bottles which has been filled 2/3 with mineral oil, and repeatedly and gently dunk it until the brown stuff dissolves and "taints" the mineral oil.
Keep dunking until it looks like a very very weak tea -- so you can see the coloration. We need to come up with a standard way to determine how dark... maybe a printed comparison strip?
Cap the square jar and throw away the cotton swab (bag it if it's really gross).
Throw away the gloves and wash your hands

Then, inside your spectrometer box (to reduce stray light and to protect your eyes from the laser light):

Without looking at the laser light directly (it's bad for your eyes!!!), shine the laser through a hole in your box, so the laser shines through your jar perpendicular to the spectrometer opening. We'll illustrate this better but look at the Parts & Crafts note above.
Move the laser up and down until you see both the bright laser peak on your SpectralWorkbench.org graph, as well as the broader range of colors that are the fluorescence.