Introduction To Analytical Chemistry PDF

Summary

This document introduces the fundamental concepts of analytical chemistry. It discusses the different types of analysis procedures and techniques, including qualitative and quantitative analyses. The document also touches on practical applications of analytical chemistry, such as environmental and clinical testing.

Full Transcript

Introduction to
Analytical Chemistry

1
 Analytical Chemistry
Analytical Chemistry – the science and
technology used to determine the chemical
composition of samples
It tries to answer these questions:

What is in the sample? – qualitative
analysis

How much of it is there in the sample? –
quantitative analysis
2
What is Analytical Chemistry used for?
Clinical – tests on blood and other bodily fluids
Forensic – CSI
Environmental – samples of rocks, soil, sediment,
water, air, biota (plant and animal matter), etc.
Food – what is in the food and how much is
there?
Quality control – checking on the manufacturing
process (refineries, pharmaceuticals, etc.)
Scientific research – geology, anthropology,
exploration of planets, etc.
Chemistry On Mars
3
 What is a sample?
Consider that you have to find the concentration of
lead in Lake Ontario water.
Population – all of the water in Lake Ontario
You cannot do measurements on all of the water in
Lake Ontario, so you take samples of water from
the lake.
We infer information about a population from
observations made on a subset or sample taken
from the population.
You might collect three bottles of water from the
lake. These individual bottles are called sampling
units or sampling increments.
4
 Samples
The collection of samples that you have are
called the gross sample.
In taking samples, the goal is always to get
a sample that truly reflects the composition
of the population (at the time that the
sample was collected); that is, we want a
representative sample.

5
 Samples
Very often, we have to be specific
about the meaning of the results of our
analysis. It may not be as simple as we
originally thought.
The question we had was:
–What is the concentration of lead in
Lake Ontario water?

6
Lake Ontario

7
 Samples
Maybe the question about lead in Lake
Ontario water should be more specific.
Would you expect the lead concentration to
be the same everywhere in the lake?
Would it be the same at different depths?
Would the results of your lead
determination be different if the samples
were collected at a different time?
Day or night, weekday or weekend, summer
or winter.
Dissolved lead or total lead? 8
 Dissolved or Total Metals
Environmental water samples (e.g., water
from a river or lake) are very often not
perfectly clear. They may have solid
particles in them that are not dissolved (silt,
sand, sediment, algae, etc.)
If there are metals in the water, the metals
can be dissolved, or they can be attached
to the surface of tiny solid particles
suspended in the water (not dissolved).
Metals could also be stuck inside tiny
particles in the water.
9
 Dissolved or Total Metals
Total metal in a water sample includes
both the metal that is dissolved and the
metal that is stuck in or on any undissolved
solid particles in the water.
You must treat the sample differently if you
want to determine dissolved metal than if
you want to determine total metal.
To find the concentration of dissolved
metal, filter the water to remove any
undissolved particles, then measure the
metal concentration in the filtrate.
10
 Dissolved or Total Metals
To find the concentration of total metal,
digest the water sample (to dissolve the
metal which is not dissolved) and then
measure the metal concentration in the
digestate.
Digesting a sample dissolves things in the
sample that were not dissolved before
(usually by boiling the sample in mineral
acid).

11
 Samples
Samples can be homogeneous or
heterogeneous.
Homogeneous samples have the same
composition (at the microscopic level)
throughout, for example a liquid solution (no
undissolved particles).
Heterogeneous samples have constituent
parts that can be distinguished visually or
with a microscope.

12
 Homogeneity
We always want to get a representative
sample, and this is easier to do when the
population is homogeneous (e.g., water
samples).
It is harder to do when the population is
heterogeneous (e.g., soil samples).

13
 Analytical Methods
Once the samples come to the laboratory, they
are analyzed using one or more analytical
methods.
An analytical method is a written document
that clearly specifies the reagents, apparatus,
and procedures needed to do the analysis.
This kind of document is often called a
Standard Operating Procedure (SOP).
It is similar to an experiment in your lab
manual at Sheridan, but it is much more
detailed.
14
 Classes of Analysis
Methods can be classified as
– wet chemistry methods (e.g., gravimetric methods,
volumetric methods)
– instrumental methods (e.g., spectroscopy,
chromatography)
They can also be classified by what is being measured
Organic Analysis – the determination of carbon
compounds in samples
– Most important technique - Chromatography
Inorganic Analysis – the determination of elements, ions,
and non-carbon compounds
– Most important technique –
Spectroscopy
15
 But first, some terminology
Analyte - an analyte is a chemical
(element, ion, or compound) that is being
measured or identified in a chemical test. It
may also be a group of chemicals that
belong to the same chemical family, and
which are being determined together.

Parameter – another name for analyte.

16
 But first, some terminology
Aliquot – an accurately measured portion
of a sample or other liquid.

Matrix – the water, soil, sludge, sediment,
or whatever that makes up most of the
sample. Also called the sample type. The
analyte is said to be in the matrix.

17
 Samples and Standards
In analytical chemistry, you are always doing
measurements on samples or standard solutions.
A sample is an amount of material in which you are
trying to find the concentration of an analyte. The
concentration is unknown until the analysis is
completed.
A standard solution (often just called a standard)
is a solution in which the concentration of analyte is
known. The concentration is known because the
standard solution was prepared by accurately
weighing out a pure compound and dissolving it in a
precisely known volume in a volumetric flask, or
some other method was used to find the
concentration accurately. 18
 Important Concepts in
Analytical Chemistry
Accuracy
Precision
Calibration
Detection Limits
Linear Dynamic Range
Quality Control
Quality Assurance

19
 Accuracy
The agreement between a measurement (or the
average of a group of measurements) and the
“true” value.
Quantitatively expressed as bias
Bias = measured - true x 100%
true
Example: If the true value for a number is 10.0 mg/L
and a measurement of it comes out as 9.2 mg/L,
what is the bias?
Answer: 9.2 - 10.0 x 100% = -8.0 % bias
10.0
Bias can be positive (measured result is too high) or
negative (measured result is too low).
Measured value is less than the true value
⇒ negative bias or biased low 20
 Accuracy
Almost always we don’t know the “true”
value for the concentration of an analyte in
a sample.
If we don’t know the true value of the
concentration of an analyte in a sample, we
can’t say anything about the accuracy of
that particular measurement.
But we can estimate the accuracy of the
method in general.
Accuracy is estimated from the recovery of
known standards. 21
 Recovery of Standards
You prepare a standard solution in which
you know the concentration of analyte very
precisely. This concentration is the
“expected value.”
You measure that standard solution using
your analytical method.
You calculate the ratio of the concentration
you found with your method to the expected
value of concentration, and express it as a
percentage. That is called the % recovery.
22
 Recovery of Standards

23
 Recovery of Standards

24
 Recovery of Standards
By measuring known standards regularly
(several times every day) and keeping a record
of the % recovery, an analyst knows what the
accuracy is for a method in general.

25
 Precision
The degree of mutual agreement among
replicate measurements.
How scattered are the results?
For several replicate measurements (>3),
precision is usually expressed as the standard
deviation (SD).
Sometimes expressed as percent relative
standard deviation (%RSD).
% RSD = SD x 100%
mean
If results are more precise (that’s what we want),
they have a lower standard deviation.
26
 Accuracy and Precision

Not precise Not precise
Not accurate Accurate

Precise Precise
Not accurate Accurate

27
 Detection Limits
For every kind of analytical method,
there is a detection limit.
What do you think “detection limits”
means?
The smallest concentration that you
can detect.
The smallest concentration that you
can measure.
Are these two things the same ?
No, they are not. 28
 Detection Limits
To detect something is to have evidence
that some of it present, as opposed to
none of it being present. It is a yes/no
decision.
To measure something is to find a
meaningful number for its concentration. It
is quantitative.
There must be more of a substance
present if you want to measure it than
to simply detect it.
29
 Limits
Therefore, in Analytical Chemistry,
we speak of Detection Limits and
Quantitation Limits.
Quantitation Limits are always higher
than Detection Limits.
Keep in mind that these are
measurements at the limits of the
capabilities of the analytical methods.

30
 Method Detection Limit
The formal definition:
– Method Detection Limit (MDL): the
minimum concentration of a substance that
can be measured and reported with 99%
confidence that the analyte concentration is
greater than zero. Also called Limit of
Detection (LOD).
What it really means:
– The smallest concentration at which you can
say there is something (not nothing) there.
You can’t reliably say how much.

31
 Estimated Quantitation Limit
The formal definition:
– Estimated Quantitation Limit (EQL): the
lowest concentration that can be reliably
measured within specified limits of precision
and accuracy during routine laboratory
operating conditions. Also called Limit of
Quantitation (LOQ).
What it really means:
– The smallest concentration at which you can
report a number.
The EQL is generally 5 to 10 times the MDL.

32
 Reporting Limit
The Reporting Limit (RL) is the
lowest concentration that a
laboratory reports for an analyte. A
concentration below that is
considered to be “not detected.”
Laboratories usually use their EQL
as the reporting limit.
The reporting limit used by a
laboratory must always be above the
MDL. 33
 Why do MDLs and RLs matter?
Why does anyone care how low the
concentrations are that a lab can measure?
Most of the samples that an environmental lab
analyzes need to be measured because
Environmental regulations set a limit on how
high concentrations of chemicals can be in
many types of sample, e.g., rivers, lakes,
landfills, etc.
For example, Ontario Regulation 169 specifies
the maximum allowable concentrations of
chemical elements and compounds in our
drinking water. These maximum concentrations
are called Standards. 34
 This is a part of Ontario Regulation 169, showing the
highest allowed concentrations of elements and
compounds in our drinking water. It shows, for example,
that the highest allowable concentration of benzene is
0.001 mg/L, for cadmium, it is 0.005 mg/L.
35
 Reporting Limits
If a laboratory wants to measure benzene in
drinking water in Ontario, it has to be able
to reliably measure benzene well below the
0.001 mg/L standard, not just down to the
standard.
Of course, the same can be said for the
determination of all the other parameters in
drinking water and also for all the
parameters under other regulations.

36
 Limits
How is this all actually done in
practice?
For every analytical method, the
laboratory determines what the MDL is
on a regular basis (typically once a
year).
The laboratory multiplies the found
MDL by a safe margin (about 5x to
10x) to get its EQL/RL.
The laboratory publishes its RLs. 37
 Method Detection Limit (MDL)
Depends on the entire method, not just the
measurement step.
It is determined from several replicate
analyses of a sample in a given matrix
containing the analyte.
The MDL is calculated from the precision of
the measurements.
The MDL is not related to the accuracy of
the method.

38
 How is the MDL determined?
1) Estimate the MDL.
2) Prepare a solution which has a
concentration of about 5 to 10 times
the estimated MDL.
3) Take 8 portions (aliquots) of that
solution through the entire
measurement process.

39
 How is the MDL determined?
4) Calculate the standard deviation of
the 8 results
5) Use Student’s t:

MDL = t x SD
For n = 8, t = 2.998
For n = 7, t = 3.143

40
 Example of MDL Determination
The determination of Total Copper in
water by Graphite Furnace Atomic
Absorption Spectroscopy.
1) Analyst estimates that the MDL is
0.0007 mg/L.
2) Analyst prepares a solution which
has 0.005 mg/L of copper.
3) Analyst digests 8 aliquots of the
solution. Analyst measures copper in 8
digests on GFAA instrument.
41
Example of MDL Determination
0.0049
0.0049 Mean = 0.0051 mg/L
0.0052
SD = 0.000196 mg/L
0.0054
0.0053
MDL = 2.998 x 0.000196
0.0049 = 0.00059 mg/L
0.0051 = 0.59 µg/L
0.0052
42
What if the 8 numbers were...
0.990
Mean = 0.977 mg/L
1.001
0.977 SD = 0.076 mg/L
0.977
0.809 MDL = 2.998 x 0.076
1.005 = 0.23 mg/L

0.976
But one result looks quite
1.078 different from the others.
43
We might be able to reject the suspect
result. Use Dixon’s test for outliers.

0.809 - 0.976 = R
1.078
0.809 - 1.005
1.005
1.001
If R > 0.55, result is an
0.990 outlier and should be
0.977 rejected.
0.977 In this case, R = 0.85
0.976 0.809 should be
rejected.
0.809

44
Calculate the MDL using only 7 results
1.078 Mean = 1.001 mg/L
1.005
SD = 0.036 mg/L
1.001
0.990 MDL = 3.143 x 0.036
0.977 = 0.11 mg/L
0.977
0.976 Use t = 3.143 for n = 7
0.809 Instead of t = 2.998

45
 Dixon’s Test
How do you know if you should do Dixon’s
Test?
You should do Dixon’s Test if there is any
chance at all that one number is different
from the other 7.
Do Dixon’s Test if one number looks
significantly higher or significantly lower
than the other 7 numbers.

46
 Dixon’s Test
Can you use Dixon’s Test twice on one data
set, i.e., when two numbers look very
different from the other 6?
No, Dixon’s Test can be used only once on
a set of 8 replicates, when one number
looks like it might be different from the other
7 numbers.
You cannot reject 2 out of 8 numbers to
calculate your MDL based on 6 replicates.
You can calculate MDL based on 8
replicates, or 7, but not 6. 47
 Why does it matter what
concentration is used?
At higher concentrations, the SD
will be higher.
If MDL determination is done at a
concentration that is too high
(> 10 x MDL), the MDL that is
found will be too high - not the
true MDL.
48
How often must MDL be determined?
It depends on the analytical
laboratory’s policy – MDLs must be
redetermined every year or every 2
years.
MDL must be redetermined if there
is a major change to the method or
to the instrument.
A determination of MDL is a rough
estimate - it is very imprecise.
49
 Method Detection Limit or
Instrument Detection Limit?
Sometimes IDL is determined. It is not
as useful as MDL.
IDL determination is the same as MDL
determination except that the variability
of the preparation steps is not
included.
If there is no sample preparation in the
method, then IDL is the same as MDL.
50
 Linear Dynamic Range
Some instruments
reach “saturation”
as the concentration
is increased.
The Linear Dynamic
Range refers to the
range of
concentrations that
are still on the linear
part of the
calibration curve. 51
 Quality Control (QC)
QC is done at the bench level by the
analyst as a routine, structured part of
analysis. It is done by analyzing QC
samples along with real samples within a
batch or run.
Method Blank (sometimes simply called
Blank)
Duplicates or Repeats
Spiked Blank or QC Standard
Matrix Spike or Spiked Sample
SRMs and CRMs 52
 Method Blank
The formal definition:
– An aliquot of reagent water or other blank matrix
that is treated exactly as a sample including
exposure to all glassware, equipment, solvents,
reagents, and internal standards, that are used with
other samples. The Method Blank is used to
determine if method analytes or other interferences
are present in the laboratory environment, the
reagents, or the apparatus.
What it really means:
– Water with nothing in it (except the preservatives
that are added to normal samples). You should
detect nothing when you do a measurement.
53
 Field Blank or Travelling Blank
The formal definition:
– An aliquot of reagent water or other blank
matrix that is placed in a sample container in
the laboratory and treated as a sample in all
respects, including shipment to the sampling
site, exposure to sampling site conditions,
storage, preservation, and all analytical
procedures. The purpose of the FB is to
determine if method analytes or other
interferences are present in the field
environment.
What it really means:
– Fill a bottle with pure water in the lab; send it to
the sampling site and bring it back. 54
 What is an acceptable level for
a Method Blank?
If the Method Blank is measured as
less than the Reporting Limit, i.e., “not
detected,” this would be acceptable.
This would pass QC.
If any amount greater than the
Reporting Limit is measured in the
Method Blank, that is considered to
be a QC failure.
55
 What happens when there is a
QC failure?
The analyst must stop doing
analyses.
The analyst must find and correct
the problem that caused the QC
failure.
Once the problem has been
corrected and QC again passes,
regular analyses can resume.
56
 Laboratory Duplicates
The formal definition:
– Two aliquots of the same sample taken in
the laboratory and analyzed separately
using identical procedures. These
duplicates will demonstrate the precision
associated with laboratory procedures,
but not with sample collection,
preservation, or storage.
What it really means:
– Measure one sample twice in a row.
57
 Field Duplicates
The formal definition:
– Two separate samples collected at the same
time and placed under identical
circumstances and treated exactly the same
throughout field and laboratory procedures.
They give a measure of the precision
associated with sample collection,
preservation and storage, as well as with
laboratory procedures.
What it really means:
– Fill two sample bottles at once at the
sampling site.
58
How closely do duplicates agree?
The Relative Percent Difference
(RPD) is calculated. m1 and m2 are
the sample and duplicate
measurements.

RPD = abs(m1 - m2) x 100%
(m1 + m2)/2

59
 RPD
The Total Phosphorus in a sample is
measured as 4.7 mg/L. The duplicate is
measured as 5.3 mg/L.

RPD = abs(4.7 - 5.3) x 100
(4.7 + 5.3)/2
= 0.6 x 100 = 12% RPD
5.0

60
 What are acceptable
duplicates?
Depending on the analysis, in order
to pass QC, the RPD must be 15%
or less (inorganics) up to 50% or
less (organic soils).
The acceptable RPD will be
specified in the laboratory
procedure.

61
 Spiked Blank
The formal definition:
– An aliquot of reagent water or other blank
matrix to which known quantities of the
method analytes are added in the
laboratory. It is analyzed exactly like a
sample, and is used to determine whether
the method is in control.
What it really means:
– Make up a solution with an exactly known
concentration to check the accuracy of
your method. 62
 Spiked Blank or QC Standard
Organic analysts often call it Spiked Blank,
or simply Spike.
Inorganic analysts often call it QC Standard.
Two different names for the same thing.
It is absolutely critical that the Spiked
Blank be prepared completely
independently from the calibration
standards.
What do we mean by “prepared
independently?”
63
 Spiked Blank or QC Standard
That means it is prepared from a different
bottle of reagent, from a different
manufacturer, if possible.
This is called using a “second source.”
Why is it crucial that the Spiked Blank (QC
Standard) be made from a different bottle of
reagent than the calibration standards?
Hint: What if the bottle contents had
partially decomposed, or has contaminants
in it?
64
What is an acceptable spiked blank?

Acceptance limits are based on
historical data.
At least 25 points are collected over
time.
The mean and standard deviation are
calculated.
A result that is within 3 SD of the mean
would be considered acceptable.
65
 Matrix Effects
Standard solutions prepared in a laboratory
are almost always very simple. They usually
consist of one, or a few, pure compounds
dissolved in RO water.
In contrast to this, real samples very often are
complex mixtures containing perhaps dozens
of components.
It is possible that some of the many
components in the sample may interfere with
your measurement of the one component in
the sample that you are trying to determine.
66
 Matrix Effects
Something in the matrix of the sample may
cause your measurement to be too low, i.e., it
may suppress your measurement.
Alternatively, something in the sample may
cause your measurement to be too high, i.e., it
may erroneously enhance your measurement.
Both of these kinds of interference due to
components in the sample matrix are called
matrix effects.
A laboratory can find out of there is any matrix
effect on a sample by analyzing a QC called a
Matrix Spike or Spiked Sample. 67
 Matrix Spike or Spiked Sample
The formal definition:
– A sample prepared by adding a known
volume of a target analyte to a specified
amount of matrix sample for which an
independent estimate of the target analyte
concentration is available. Matrix spikes
(spiked samples) are used to determine the
effect of the matrix on a method's recovery
efficiency.
What it really means:
– Make up a solution in which you add an
exactly known concentration to a sample
instead of to pure water. 68
 Matrix Spike or Spiked Sample
Example:
– You measure Fe in a sample as 11.4 mg/L.
– You take another aliquot of the same sample and
add 5.0 mg/L Fe to it. You “spiked” the sample.
– You measure the spiked sample.
– You expect to get 11.4 + 5.0 = 16.4 mg/L.
– If you do measure 16.4 mg/L in the spiked sample,
there is no matrix effect. You can conclude that the
measurement on the original sample is unaffected
by its matrix.

69
 Matrix Spike or Spiked Sample
– If you measure lower than 16.4 mg/L in the spiked
sample, that means that something in the matrix of
the sample makes it appear lower than it really is;
there is a matrix effect, in which the sample matrix
suppresses the measurement of Fe.
– This means the measurement of the original sample
is probably also lower than the true value.
– It is also possible that you measure higher than
16.4 mg/L in the spiked sample. That would mean
that something in the sample matrix causes the
measurement of Fe to be too high.

70
What is an acceptable matrix spike?
Acceptance limits are based on historical
data.
At least 25 points are collected over time.
The mean and standard deviation are
calculated.
A result that is within 3 SD of the mean would
be considered acceptable.
In this case, it must be expressed as %
Recovery.

71
 Certified Reference Materials and
Standard Reference Materials
Certified reference materials
(CRMs) are samples, available in
different matrices, that have been
extensively analyzed by several
laboratories and methods and have
certified concentration values for
specific compounds analyzed.

72
Certified Reference Materials and
Standard Reference Materials
Standard reference materials (SRMs)
are certified reference materials that
have been certified by an organization
recognized in setting standards, e.g.,
NRC, NIST.
National Institute of Standards and
Technology (NIST) SRMs
LKSD-1 to LKSD-4 Lake Sediment
Samples | Natural Resources Canada
73
Certified Reference Materials and
Standard Reference Materials
CRMs or SRMs are used by
laboratories as a check on the
accuracy of their methods.

CRMs or SRMs are not available
for all analyses.

74
 How do all these QC samples
fit in with the real samples?
Every method has a Run Layout that
specifies the order in which real
samples and QCs are run within a
batch.
The Run Layout has strict
requirements for frequency of QCs
within the run.
The analyst is required to follow the
Run Layout given in the SOP for the
method. 75
Run Layout for Nitrilotriacetic Acid Determination
Cal Blank (0 mg/L)
Cal Std 0.4 mg/L
Cal Std 1.0 mg/L
These are calibration standards
Cal Std 2.0 mg/L
Cal Std 3.0 mg/L
Cal Std 5.0 mg/L
QC Standard, 2.0 mg/L (second source)
Method Blank
Sample 1 These 3 are QCs
Sample 1 Lab Duplicate
Sample 2
Sample 3
Sample 4
Sample 5 76
Run Layout for Nitrilotriacetic Acid Determination
Sample 6
Sample 7
Sample 8
Sample 9
Sample 10
Sample 11
Sample 12
Sample 13
Sample 14
Sample 15
QC Standard, 2.0 mg/L (second source)
Method Blank
Sample 16 These 3 are QCs
Sample 16 Lab Duplicate 77
 Autosamplers
In the modern laboratory, in most
methods, samples are rarely run
manually, one at a time.
Samples are loaded by the analyst
onto an autosampler, and then run
automatically, one after another, by
the instrument.
Analyst monitors the progress of the
run, collects and assesses data at the
end of the run.
These can be run overnight as well. 78
79
80
 Quality Assurance (QA)
QA is the overall system and all of its
components to assure quality.
QA is done at the management level.
QA Manager - person who is
responsible for QA system.
QA Manager must not be involved in
production.
QC is a part of QA.

81
 QA has a written plan –
Quality System Manual (QSM)
The QSM defines the quality system.
The QSM outlines policies.

82
 Laboratory
Certification/Accreditation
Formal recognition, given by an outside
agency, of the competence of a laboratory
In Canada:
– Canadian Association for Laboratory
Accreditation (CALA)
– Standards Council of Canada (SCC)
In U.S.:
– National Environmental Laboratory
Accreditation Program (NELAP)

83
 Laboratory Accreditation
ISO Standard 17025 – “General
Requirements for the Competence of
Testing and Calibration Laboratories”
An international standard
You can buy it directly from
International Organization for
Standardization (ISO) or from SCC
($140)

84
 What does a laboratory have to
do to get accredited?
Accreditation is by parameter and
matrix.
Performance Evaluation (PE) samples
twice every year.
Site Assessments once every two
years
Fees (of course)

85
Standard Operating Procedures
(SOPs)
Written procedures describing how
analyses must be done (Analytical
Methods)
SOPs specify everything analyst must
do – no ambiguity
Analysts must follow SOPs exactly.
Authorized (signed)
Validation data
– MDLs, Accuracy, Precision, Linearity
Controlled document
86
 Control Charts
What is a control chart?
Why do we use them?
How are they made?
How are they used?

87
 Control Charts
A control chart is a graph that shows
how a measured result changes over
time (days, weeks, and months).
It is usually a measurement on a
known standard solution.
Spiked blank (second source) is
usually plotted.
Control charts are used to monitor
that a process is “in control.”
88
 What is a Control Chart ?
A typical control chart is a graphical display of a quality characteristic
that has been measured or computed from a sample versus the
sample number or time.
The chart contains:
UCL a center line that represents the average
value of the quality characteristic
corresponding to the in-control state.
Mean two other horizontal lines, called the upper
control limit(UCL) and and the lower control
limit(LCL) are also drawn.

LCL
Control Chart These control limits are chosen so that if the
process is in control, nearly all of the sample
points will fall between them. As long as the
points plot within the control limits, the
process is assumed to be in control, and no
action is necessary.
89
 What is a Control Chart ?

However, a point that plots outside
of the control limits is interpreted as
evidence that the process is out of
UCL
control, and investigation and
corrective action is required to find
and eliminate the assignable
Mean causes responsible for this
behavior.

LCL
NOTE: Even if all the points plot
inside the control limits, if they
behave in a systematic or
nonrandom manner, then this is an
indication that the process is out of
control.
90
 Why Do We Use Control Charts?
The Use of Control Charts is an Essential
Component of Statistical Quality Control (SQC)

UCL

+3б
Mean

-3б

LCL

SQC Is An Expected Quality Element outlined by
ISO 17025
91
 What is so special about 3 sd and
The "68 95 99.7 Rule”
A process that is in "control" with a normal
distribution has:
68% of the results will fall within 1sd.
95% of the results will fall within 2sd.
99.7% of the results will fall within 3sd.

There's ~ three chances in 1,000 (0.3%)
that the process will produce a result
outside 3sd.
92
 How does a Control Chart
get started?
Before a control chart can be used,
it must have the upper and lower
control limits (UCL and LCL)
established.
Where do these limits come from?

93
So How Do we Build A Control Chart ?
Step 1: Collect a minimum of 25 data
points over a period of at least three
weeks.
Something

94
Time
 Step 2: Calculate the mean of the measured results
Calculated Concentration

Mean / Average

Date of Analysis 95
Step 3 : Calculate and standard deviation (sd) and plot :
(mean + 3 standard deviations +3 δ ) and

(mean – 3 standard deviations -3 δ )

+3 δ

Mean

-3 δ

96
 How Does a Control Chart Differentiate Between
Random and Assignable Causes ?
If there is a point outside the limits it may be due to an
“intermittent” variation related to an assignable or non-random
cause. The Control Chart is saying “Something may be wrong
with the measurement. Check it out”.

+3 δ Upper
Limit
Something

Out of
Control
Mean /
Point
Average
Lower
-3 δ Limit

97
Sometime
 Control Chart Protocols
Results from a “second source” standard
at a mid-range or lower concentration is
obtained each day the instrument is run.
Control Charts are updated/plotted and
interpreted in “real time”.
Out of control situations are addressed
immediately (same day) prior to data being
reported.
Responses to out of control situations are
documented.
Control charts are audited regularly by QA.
98
 Control Chart Protocols
For multi-element/compound
methods:
control charting of a minimum of
10% of the total number of
compounds is required. (e.g.
Volatiles scan 30 compounds will
monitor 3 or greater
elements/compounds).

99
 Control Charts provide an easily interpreted history of process
performance allowing for operators to identify trends and proactively
make changes before loss of data due to QC failures.

1
2
Mean
3 1
4 4
5 5
6
6
3 7

7
2

Other trends to be aware of that may signal a process issue include:
7 consecutive points rising or falling and 7 consecutive points on the
same side of the mean
100
Common Causes of Violations – Increased Variability

Note: Abrupt change in data

+3 δ

Mean

-3 δ
Typical Causes Include:
variation from SOP
poor technique, lack of training etc.
101
Common Causes of Violations – Shift in Mean

+3 δ

Mean

-3 δ
Causes Include:
incorrect standard or reagent preparation
reference material contamination
incorrect instrument calibration
change in procedure/instrumentation 102
Common Causes of Violations – Downward Trend in Mean

+3 δ

Mean

-3 δ

Causes Include:
evaporative concentration of calibration material
deterioration of reagents
103
Common Causes of Violations: Upward Trend in Mean

+3 δ

Mean

-3 δ

Causes Include:
deterioration of reference material or reagents
evaporative concentration of reference material
104