Plaintext
Alliance for Aquatic Resource Monitoring
Chemical Monitoring
Manual
January 2010
© 2010 Alliance for Aquatic Resource Monitoring. Chemical Monitoring Manual.
Is licensed under the Creative Commons Attribution-NonCommercial-
NoDerivatives 4.0 International license.
http://creativecommons.org/licenses/by-nc-nd/4.0/
If you would like to use this content in other ways, please email us.
1
� Table of Contents
Background on ALLARM ………………….……………………………………………………………………………………………………...3
Background on Chemical Monitoring Manual ………………………………………………………………………………………...4
Cleaning your kits and sampling containers….…………………………………………………………………………………………5
Hints and tips to make cleaning easier..…………………………………………………………………………………………………..5
Handling hydrochloric acid solution.………………………………………………………………………………………………………..6
General safety precautions……………………………………………………………………………………………………………………..6
Sample collection……………………………..……………………………………………………………………………………………………..7
General tips and suggestions……………………………………… ………………………………………………………………………..10
References ……………………………………………………………………………………………………………………………………………12
2
�Background on ALLARM:
The Alliance for Aquatic Resource Monitoring (ALLARM) is a project of the Environmental Studies
Department at Dickinson College. Since its founding in 1986, ALLARM has become a nationally
recognized technical and programmatic support center for community organizations interested in
watershed assessment, protection, and restoration. ALLARM program goals are to:
1) Enhance local action for the protection and
restoration of Pennsylvania watersheds by
empowering communities with scientific
knowledge and tools to implement
watershed assessments;
2) Provide Dickinson College students with
opportunities to participate in community-
based participatory research thereby
enhancing the quality of undergraduate
science education; and
3) Be the leader in volunteer monitoring in
Pennsylvania and a national model for
college-community partnerships.
Through the work of student and professional staff,
ALLARM offers comprehensive services to enable
groups to use critical scientific tools to enhance
environmental quality and fully participate in community decision-making. The program staff includes a
Director, an Assistant Director, a faculty Science Director, and 12-14 undergraduate student staff.
For more information on please visit: www.dickinson.edu/allarm or email: allarm@dickinson.edu
Project funding provided by the Foundation for Pennsylvania Watersheds.
3
�Chemical Monitoring Manual Background:
What is the purpose of chemical
monitoring?
Chemical monitoring is a way to look at specific water
parameters in greater detail in order to determine the health
of a stream. It is also a snapshot view in time of the
chemistry of the stream since the water chemistry is always
changing. Since most aquatic organisms need to live in water
all of the time, the chemistry of the water affects whether
organisms are able to survive there or not. Measuring water
chemistry can also be helpful in identifying whether there is
a pollution source in the water and what type of pollution it
might be.
What is this manual?
When conducting chemical monitoring there are a lot of
steps to consider and put into practice to ensure that data
you are collecting are as credible as possible. This manual
is designed to be a reference point for best chemical
monitoring practices. Part of this manual is focused on
equipment cleaning and maintenance – practices that
cannot be understated. For example, if you do not wash
your glassware properly you will inaccurately inflate your
nutrient testing results. In developing volunteer
monitoring protocols, ALLARM has done and continually
conducts extensive research to make sure that the
protocols volunteer monitors use are the most up to date
and relevant for their monitoring objectives. The methods
reflected in this manual reflect laboratory and field
standard practices.
On average it takes a volunteer monitor 3-5 hours to
conduct chemical monitoring for eight parameters each
month. This manual is designed to ensure that time spent
monitoring is well spent.
4
�Cleaning your kits and sampling containers
Always wear latex gloves when using this cleaning procedure!
Wash all glassware, plasticware, droppers, syringes, and sample bottles using the following procedure:
1. Thoroughly wash with a brush and phosphate-free detergent
(Alconox or equivalent).
2. Rinse 3 times with cold tap water.
3. Rinse with 10% Hydrochloric acid solution (use a very small
amount 2 – 5 mL depending on the container).
4. Rinse 3 times with distilled/deionized water.
The phosphate-free soap is used as a general cleaning (like when you
wash dishes at home, except the soap is phosphate-free to prevent
phosphorus contamination) to remove larger particles from your kit
equipment. The dilute hydrochloric acid (HCl) solution will remove
any atomic particles that have adhered to your equipment.
Tip: Three is the magic number for rinsing.
A little solution goes a long way. HCl is expensive use a little of
the solution and roll it around to make sure it comes into
contact with the whole interior of your sampling equipment.
Hints and tips to make cleaning easier:
Syringes:
•Wash the syringe by separating the plunger from the body of the
syringe.
• Flush the syringe by pulling and pushing the plunger repeatedly
into and out of the body of the syringe while pulling in and
expelling out the detergent.
Droppers:
• Pull off the rubber bulbs and thoroughly wash the bulb and tube
of the dropper.
• Pour a small amount (0.5 mL) of the 10% HCl acid solution into
the dropper tube. Carefully reattach the rubber bulb and
thoroughly rinse all inside surfaces of the tube and bulb by
rotating and inverting the dropper.
• Dispose of the used HCl solution in your sink drain with running
tap water.
TIP! Unless noted in the procedure, kit parts do not have to be completely dry before reuse.
5
�Handling hydrochloric acid solution:
Handling the 10% Hydrochloric Acid Solution (HCl):
1. PRODUCT IDENTIFICATION AND INGREDIENTS
• 10% by volume Hydrochloric Acid in distilled water.
2. PRECAUTIONARY MEASURES
• Avoid contact with eyes, skin and clothing.
• Do not breathe mist or vapor.
• Wash thoroughly after handling.
• Wear disposable latex gloves when handling.
3. FIRST AID
• Eye And Skin Contact
o Immediately flush eyes and skin with water for 10
to 15 minutes.
o Remove contaminated clothing.
o Call a physician.
• Ingestion
o Call a physician immediately.
• Inhalation
o Remove to fresh air.
4. SPILL AND DISPOSAL PROCEDURES
• Pick up liquid with a sponge or cloth.
• Rinse liquid down the drain with cold running tap
water.
• Wear disposable latex gloves.
Tip: HCl will stain stainless steel sinks pink. Consider using a different sink.
General safety precautions:
• Read all instructions to familiarize yourself with the test procedure before you begin. Note any
precautions.
• Read the labels on the reagents and the Material Safety Data Sheets prior to use.
6
� • Keep all chemicals and equipment out of the
reach of young children.
• Do not dispose of chemicals on the ground
or in the stream. Unless otherwise noted in
the directions dispose of used reagents in
your sink drain while running cold water for
one to two minutes.
• Avoid contact between reagent chemicals
and skin, eyes, nose, and mouth. Wear
rubber gloves when conducting chemical
analysis.
• Use the test tube caps or rubber stoppers
(not your fingers) to cover the test tubes
when shaking or mixing.
• When dispensing reagent from a plastic
squeeze bottle, hold the bottle straight up
and down (not at an angle) and squeeze
gently. If the gentle squeeze does not work,
the bottle may be clogged.
• Never use chemicals beyond their expiration date. When you receive your materials note the
expiration dates.
• In the event of accidental poisoning, contact your local poison control center listed in the blue
pages of your phone book. Be prepared to provide the name of the reagent in question and
the code number.
Sample Collection:
This sampling program is designed to collect a water sample that is
small enough in volume to be conveniently collected, transported and
handled, while accurately representing the quality of the entire
stream segment at the point in time when the sample was taken. This
requires that the sample be taken and handled in such a way that no
significant changes in composition occur before the at-home or field
tests are made. The water quality monitoring program is designed to
ensure that sampling and subsequent analytical methods provide a
true basis for answering the questions that originally prompted the
sampling.
Where should I collect the sample?
In general, you should collect your sample away from the stream bank
in the current. Do not sample stagnant water. Where practical, you
will wade into the stream to collect the sample. Sample collection in
deep sites can be done from a boat or you may tape your bottle to an
extension pole to reach the deep water. Sampling from a bridge is
7
�also an alternative. Note any variations in sample collection on your data sheet.
How should I collect the sample?
1. Enter the stream downstream of the monitoring point, to avoid introducing disturbed
stream sediment to the sample.
2. Move to the center of the stream, if possible.
3. Take the sample facing upstream from where you are standing:
For streams where water depth and current allow for safe entry and complete emersion of the sample
bottle, use the following procedure:
1. Wear latex gloves when collecting samples and rinse your gloved hands with the stream water.
2. Rinse the bottle and cap with the
stream water, being careful not to
touch the insides of the bottle or
cap with your hands. Totally fill the
bottle and cap with water. Pour out
the rinse water downstream from
where you are standing to avoid
reintroducing the rinse water back
to the collected sample. Repeat 3
times.
3. Prepare to fill the bottle by slightly
tilting the mouth towards you. This
will position the bottle opening
away from the direct flow of the
stream current.
8
� 4. Lower the bottle into the stream current at an angle, attempting to smoothly and evenly sample
the entire depth of the stream. Keep the same tilt to the axis of the bottle throughout the fill
cycle. Keeping the sample bottle slightly tilted in this manner will prevent total filling. This
empty space will allow for thermal expansion during shipping. Try to get the same volume of
sample at each depth.
5. If you are not satisfied with your collection procedure, throw out
the water and try again.
6. Cap the filled bottle tightly and immediately put it on ice.
TIP! Be careful not to disturb the bottom sediment of the stream.
Special Notes for Shallow Streams:
1. For shallow streams where this procedure is not practical,
simply lower the tilted bottle into the stream, to the depth
possible, and allow the bottle to slowly fill with water while
maintaining the tilt. Be careful not to disturb the bottom
sediment.
2. When very shallow stream depth does not allow either
procedure to be used, use a clean 2nd bottle to collect as
much sample as possible, being careful not to disturb the
stream bottom. Slowly and carefully pour the water into the sample bottle. Continue
this procedure until the sample bottle is nearly full.
NOTE: Do not later use this 2nd bottle as a sample collection bottle or use this procedure for
sample collection at another location. This 2nd bottle can only be used to collect additional
samples at the same location.
Special Note for Deep Streams:
For deep or high current waters where it is not safe to enter the stream, take
samples from a boat, bridge or stream bank, and note this sample procedure on
the bottle or forms. You can build a sampling pole for $20 or you can use a bucket
with a rope.
Tip: Be sure that the bucket and sampling bottle are used only for
monitoring and are cleaned properly!
What if there is suspended matter in the sample?
If any significant amount of suspended matter is present in the stream, the
suspended matter should be separated from the sample by the following
procedure:
9
� 1. Fill a container larger than the sample bottle with stream water, using the above procedures
as applicable.
2. Allow the suspended matter to settle.
3. Slowly and carefully pour water into the sample bottle.
General tips and suggestions:
• Water samples should be at room temperature (20 – 23 °C) when testing for
nutrients (nitrate and phosphate). Colder samples will give lower, inaccurate
results.
• Results can vary by shaking technique. To check your technique, purchase a
standard (a solution of known concentration). Run the test using the
standard and vary your shaking technique until you get the correct result.
• Dropper bottles should be held exactly vertically to yield the most even sized
drops.
• Always fill your test tubes exactly to the line, remembering to account for
the meniscus. You can purchase syringes to assist with measuring the
correct amount.
• Clean, clean, clean. Don’t forget the lids, stoppers and syringes.
• Purchase enough glassware so that you can run two replicates without cleaning.
• Remember to shake sample lightly for 3 minutes just
prior to analysis.
• Read the directions! Read them again. Follow them
precisely.
• Set up a clean and open work area and place something
on the table or area to catch spills (newspaper works
well).
• Prior to testing, make sure everything is clean. Check
reagents for discolorations. If you believe there is a
problem with the reagents, buy new ones.
10
�• When you receive your kits, date the reagents and note the expiration date so you know
when to replace the reagents.
• Use gloves, as many of the chemicals are harmful and this will help lower the chance of
contamination from your hands.
• Prior to running tests, rinse all sample tubes and mixing bottles with the sample water
three times.
• When performing the test follow the times for reactions and shaking exactly. Use a
stopwatch or kitchen timer to help you with this.
• When you put the reagent in the tube, start shaking
immediately.
• Be objective (it is harder than you think).
• For color comparisons, sunlight is best, but always hold
the color comparator up to a light source. When using
the color wheel, place your finger over the area where
the concentrations are listed in order to be objective.
• If you are performing the tests on site, bring a bottle to
dispose the wastewater and bring it home. Unless
otherwise noted in the procedure, pour wastewater
down the sink while running the water, or pour into kitty
litter and dispose of in the trash.
• When done with the test, thoroughly clean and allow
everything to dry prior to resealing the kit.
• Practice with tap water or stream water at home so you can become familiar with the
kits before testing samples.
• To open reagent packets, tap the packet on a hard surface to gather powder on bottom.
Using scissors, cut across packet top horizontally. With both hands, push packet open to
create a pouring spout, then tilt packet to empty.
11
�References:
1. Standard Methods for the Examination of Water and Wastewater, 19th Edition; 1995; American
Public Health Association, American Water Works Association, Water Environment Federation;
Washington, D.C.
2. Chemistry in Review; W. Merrill Davis, Herbert R. Smith; 1962; Lyons and Carnahan, Inc.; Chicago, Ill.
3. Quantitative Analysis, Laboratory Manual, 2nd Edition; R.A. Day, Jr., A.L. Underwood; 1967; Prentice-
Hall, Inc.; Englewood Cliffs, N.J.
4. Lab Manual for Environmental Science 131; Dickinson College Environmental Studies Department;
1996; Dickinson College; Carlisle, Pa.
5. The Chemist’s Companion; Arnold J. Gordon, Richard A. Ford; 1972; John Wiley & Sons; New York,
N.Y.
6. HACH DR/2010 Spectrophotometer Procedures Manual; 1997; HACH Company; Loveland, Co.
7. HACH Water Analysis Handbook, 4th Edition; 2002; HACH Company; Loveland, Co.
8. Lange’s Handbook of Chemistry, 2nd Edition; 1979; McGraw-Hill Book Company; New York, N.Y.
9. Field Manual For Water Quality Monitoring; Mark K. Mitchell, William B. Stapp; 1994; Thomson-
Shore Printers; Dexter, Michigan.
10. Chemistry, A Conceptual Approach; Charles E. Mortimer; 1967; Reinhold Publishing Company; New
York, N.Y.
11. Prudent Practices for Handling Hazardous Chemicals in Laboratories; 1981; National Academy Press;
Washington, D.C.
12. Fundamentals of Analytical Chemistry, 4th Edition; Douglas A. Skoog, Donald M. West; 1982;
Saunders College Publishing; Philadelphia, Pa.
13. The Encyclopedia of Chemistry, 2nd Edition; 1966; Van Nostrand Reinhold Company, New York, N.Y.
14. The Volunteer Monitor’s Guide to Quality Assurance Project Plans; 1996; U.S. Environmental
Protection Agency; EPA 841-B-96-003; Washington, D.C.
15. Volunteer Lake Monitoring; 1991; U.S. Environmental Protection Agency; EPA 440/4-91-002;
Washington, D.C.
16. Volunteer Stream Monitoring: A Methods Manual; 1997; U.S. Environmental Protection Agency; EPA
841-B-97-003; Washington, D.C.
17. www.globe.gov, accessed September 20, 2004
18. Water Quality Test Kit Manual, May 2001, Environmental Alliance for Senior Involvement
19. The Chemistry of Water; 1998; Susan E. Kegley & Joy Andrews; University Science Books, Sausalito,
CA.
12
�