This document discusses key concepts in analytical chemistry and sampling. It begins by defining important terminology used in analytical chemistry like analyte, matrix, determination, measurement, accuracy, precision, selectivity, sensitivity and more. It then covers different types of chemical analysis based on the information required like proximate, partial, trace and complete analysis. Additionally, it discusses different types of analysis based on sample size like macro, semi-micro and micro analysis. The document also covers classical and non-classical methods of analysis as well as important concepts in sampling like population, sampling techniques, sampling units, increments, gross sample, sub-sample and analysis sample. It discusses the purposes of sampling like judging acceptability, detecting contamination and identifying materials. Finally
Analytical Chemistry. detail topic for Honor StudentsNisbaRani2
Analytical Chemistry. detail topic for Honor Students. detail type and method of analysis are discussed in this ppt with examples. Easy and precise knowledge of classical and non-classical methods of chemical and Physical analysis respectively. all terms of analysis are discussed here.
The document discusses key concepts in analytical chemistry including:
1) It defines analytical chemistry as the branch dealing with determining the composition of matter.
2) It outlines common analytical techniques like qualitative, quantitative, characterization and fundamental analysis.
3) It describes important terms used in analytical chemistry like analysis, analyte, matrix, determination, measurement, technique, method, procedure and protocol.
4) It provides an overview of analytical methods classification including chemical methods like gravimetry, volumetry and instrumental methods like optical, electroanalytical, separation and miscellaneous methods.
analaytical chemistry for medical laboratory.pdfnimonayoseph27
Analytical chemistry is concerned with separating, identifying, and quantifying the components of samples. This lecture introduces analytical chemistry, covering topics such as the definition and goals of analytical chemistry, common terms, classifications of qualitative and quantitative analysis, and the steps involved in chemical analysis. Both classical chemical methods and modern instrumental methods are discussed. Analytical chemistry plays an important role across various fields including industrial quality control, environmental monitoring, medicine, forensics, and more.
Pharmaceutical analysis involves qualitative, quantitative, and semi-quantitative analysis to determine what substances are present in a sample and how much of each substance is present. There are various types of analytical methods including classical methods like titrimetry and gravimetry as well as instrumental methods using techniques like spectroscopy, chromatography, and electroanalytical methods. The document discusses the scope, classification, advantages, and limitations of different pharmaceutical analytical methods.
Pharmaceutical analysis involves qualitative, quantitative, and semi-quantitative analysis to determine what substances are present in a sample and how much of each substance is present. There are various types of analytical methods including classical methods like titrimetry and gravimetry as well as instrumental methods using techniques like spectroscopy, chromatography, and electroanalytical methods. The selection of analytical method depends on factors like sample complexity, required accuracy and precision, cost, and availability of instrumentation.
Pharmaceutical analysis involves qualitative, quantitative, and semi-quantitative analysis to determine what substances are present in a sample and how much of each substance is present. There are various types of analytical methods including classical methods like titrimetry and gravimetry as well as instrumental methods using techniques like spectroscopy, chromatography, and electroanalytical methods. The selection of analytical method depends on factors like sample complexity, required accuracy and precision, cost, and availability of instrumentation.
This document discusses key concepts in analytical chemistry and sampling. It begins by defining important terminology used in analytical chemistry like analyte, matrix, determination, measurement, accuracy, precision, selectivity, sensitivity and more. It then covers different types of chemical analysis based on the information required like proximate, partial, trace and complete analysis. Additionally, it discusses different types of analysis based on sample size like macro, semi-micro and micro analysis. The document also covers classical and non-classical methods of analysis as well as important concepts in sampling like population, sampling techniques, sampling units, increments, gross sample, sub-sample and analysis sample. It discusses the purposes of sampling like judging acceptability, detecting contamination and identifying materials. Finally
Analytical Chemistry. detail topic for Honor StudentsNisbaRani2
Analytical Chemistry. detail topic for Honor Students. detail type and method of analysis are discussed in this ppt with examples. Easy and precise knowledge of classical and non-classical methods of chemical and Physical analysis respectively. all terms of analysis are discussed here.
The document discusses key concepts in analytical chemistry including:
1) It defines analytical chemistry as the branch dealing with determining the composition of matter.
2) It outlines common analytical techniques like qualitative, quantitative, characterization and fundamental analysis.
3) It describes important terms used in analytical chemistry like analysis, analyte, matrix, determination, measurement, technique, method, procedure and protocol.
4) It provides an overview of analytical methods classification including chemical methods like gravimetry, volumetry and instrumental methods like optical, electroanalytical, separation and miscellaneous methods.
analaytical chemistry for medical laboratory.pdfnimonayoseph27
Analytical chemistry is concerned with separating, identifying, and quantifying the components of samples. This lecture introduces analytical chemistry, covering topics such as the definition and goals of analytical chemistry, common terms, classifications of qualitative and quantitative analysis, and the steps involved in chemical analysis. Both classical chemical methods and modern instrumental methods are discussed. Analytical chemistry plays an important role across various fields including industrial quality control, environmental monitoring, medicine, forensics, and more.
Pharmaceutical analysis involves qualitative, quantitative, and semi-quantitative analysis to determine what substances are present in a sample and how much of each substance is present. There are various types of analytical methods including classical methods like titrimetry and gravimetry as well as instrumental methods using techniques like spectroscopy, chromatography, and electroanalytical methods. The document discusses the scope, classification, advantages, and limitations of different pharmaceutical analytical methods.
Pharmaceutical analysis involves qualitative, quantitative, and semi-quantitative analysis to determine what substances are present in a sample and how much of each substance is present. There are various types of analytical methods including classical methods like titrimetry and gravimetry as well as instrumental methods using techniques like spectroscopy, chromatography, and electroanalytical methods. The selection of analytical method depends on factors like sample complexity, required accuracy and precision, cost, and availability of instrumentation.
Pharmaceutical analysis involves qualitative, quantitative, and semi-quantitative analysis to determine what substances are present in a sample and how much of each substance is present. There are various types of analytical methods including classical methods like titrimetry and gravimetry as well as instrumental methods using techniques like spectroscopy, chromatography, and electroanalytical methods. The selection of analytical method depends on factors like sample complexity, required accuracy and precision, cost, and availability of instrumentation.
Here are the basic steps to calculate the molarity of a standard solution:
1. Weigh out an accurately known amount of the solid reagent.
2. Dissolve the solid in a known volume of solvent. This gives us the total moles of solute and total volume of solution.
3. Use the formula M = moles of solute / liters of solution to calculate the molarity.
For example, if we weighed 2.345 g of NaOH and dissolved it in 1 L of water, we would:
- Find the moles of NaOH using its molar mass (40.00 g/mol): moles = mass / molar mass =
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Analytical chemistry involves separating, identifying, and quantifying components of matter. Hyphenated techniques combine two analytical methods, such as gas chromatography coupled with mass spectrometry (GC-MS). GC-MS separates chemical mixtures using gas chromatography and then identifies components using mass spectrometry. Other common hyphenated techniques include liquid chromatography-mass spectrometry (LC-MS) and gas chromatography-infrared spectroscopy (GC-IR). These coupled techniques provide enhanced sensitivity and accuracy for analyzing organic compounds, pollutants, drugs, proteins, and more.
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This document discusses analytical chemistry and the analytical process. It defines analytical chemistry as dealing with qualitative and quantitative analysis to identify or determine the amount of elements, species, or compounds present in a sample. It outlines the scope of analytical chemistry in applications like quality control, clinical/biological studies, and research. The document then discusses key concepts like chemical interferents, limits of detection, specificity, and sensitivity. It describes the overall analytical procedure as involving problem definition, technique/method selection, sampling, sample treatment, qualitative and quantitative analysis, reporting, and reviewing the original problem.
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This document provides an overview of analytical chemistry and the steps involved in a quantitative analysis. It discusses how analytical chemistry plays a vital role in many areas of science. The key steps in a quantitative analysis are: 1) selecting an appropriate analytical method, 2) acquiring a representative sample, 3) processing the sample, 4) eliminating any interferences, 5) calibrating and making measurements, 6) calculating results, and 7) evaluating the reliability of the results. Instrumental methods have become increasingly important alongside classical wet chemical techniques. The goal of analytical chemistry is to determine the chemical composition of samples both qualitatively and quantitatively.
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Is a procedure or set of procedures intended to ensure that a manufactured or performed service adheres to a defined set of quality criteria or meets the requirements of client or customer. QC is similar to, but not identical with, quality assurance (QA)
This document summarizes analytical chemistry techniques used in forensic science laboratories. It describes how forensic labs are divided into areas like biology, chemistry, DNA, and toxicology. The chemistry lab analyzes samples like blood, urine, and drugs using techniques like Fourier transform infrared spectroscopy, gas chromatography/mass spectrometry, liquid chromatography/mass spectrometry, and atomic absorption spectroscopy to identify organic and inorganic compounds. These analytical techniques help determine the chemical composition of evidence and whether detected substances caused or contributed to death.
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The document defines key terms used in analytical chemistry, including analyte, sample, matrix, concentration, calibration curve, accuracy, precision, interference, standards, and more. It also provides examples of primary standards such as sodium carbonate and potassium hydrogen phthalate. Additionally, it discusses the scope of analytical chemistry and its role in fields like agriculture, environment, forensics, manufacturing, and more. The document aims to familiarize readers with fundamental concepts in analytical chemistry.
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This document provides an overview of analytical chemistry and instrumentation. It defines pharmaceutical chemistry and analytical chemistry. It discusses qualitative and quantitative analysis and describes common analytical instruments like pH meters, ORP meters, gas chromatographs, mass spectrometers, and spectrometers. It also outlines the analytical methodology and lists some applications of instrumental methods in fields like bioanalysis, environmental analysis, materials science, and forensic science.
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Here are the basic steps to calculate the molarity of a standard solution:
1. Weigh out an accurately known amount of the solid reagent.
2. Dissolve the solid in a known volume of solvent. This gives us the total moles of solute and total volume of solution.
3. Use the formula M = moles of solute / liters of solution to calculate the molarity.
For example, if we weighed 2.345 g of NaOH and dissolved it in 1 L of water, we would:
- Find the moles of NaOH using its molar mass (40.00 g/mol): moles = mass / molar mass =
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The document discusses the field of chemical analysis, including its goals and applications. It describes the roles of chemical analysts in quantifying, detecting, and identifying unknown substances in samples. Analysts apply standardized techniques to answer compositional questions, while more experienced analysts develop new methods and study the fundamental science underlying measurements. Chemical analysis draws upon diverse disciplines and impacts many fields, such as chemistry, biotechnology, materials science, manufacturing, and forensics.
This document provides an overview of extractables and leachables (E&Ls) studies. It discusses that E&Ls studies are needed in industries like biomedical devices, food packaging, and pharmaceutical packaging to identify substances that can migrate from materials into products. Jordi Labs is introduced as a leader in E&Ls analysis with state-of-the-art facilities and over 80% of staff being chemists. The document outlines the basic process of an E&L study including sample selection, extractions, identification of E&Ls using techniques like mass spectrometry, quantitative analysis, and determining acceptable levels. Regulations for E&Ls from organizations like USP, FDA and ISO are also summarized.
Analytical chemistry involves separating, identifying, and quantifying components of matter. Hyphenated techniques combine two analytical methods, such as gas chromatography coupled with mass spectrometry (GC-MS). GC-MS separates chemical mixtures using gas chromatography and then identifies components using mass spectrometry. Other common hyphenated techniques include liquid chromatography-mass spectrometry (LC-MS) and gas chromatography-infrared spectroscopy (GC-IR). These coupled techniques provide enhanced sensitivity and accuracy for analyzing organic compounds, pollutants, drugs, proteins, and more.
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This document discusses analytical chemistry and the analytical process. It defines analytical chemistry as dealing with qualitative and quantitative analysis to identify or determine the amount of elements, species, or compounds present in a sample. It outlines the scope of analytical chemistry in applications like quality control, clinical/biological studies, and research. The document then discusses key concepts like chemical interferents, limits of detection, specificity, and sensitivity. It describes the overall analytical procedure as involving problem definition, technique/method selection, sampling, sample treatment, qualitative and quantitative analysis, reporting, and reviewing the original problem.
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Different techniques of analysis
Significant Figures
Errors - Types & Minimization
Calibration of glasswares - pipette, burette & Volumetric flask
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This document provides an overview of analytical chemistry and the steps involved in a quantitative analysis. It discusses how analytical chemistry plays a vital role in many areas of science. The key steps in a quantitative analysis are: 1) selecting an appropriate analytical method, 2) acquiring a representative sample, 3) processing the sample, 4) eliminating any interferences, 5) calibrating and making measurements, 6) calculating results, and 7) evaluating the reliability of the results. Instrumental methods have become increasingly important alongside classical wet chemical techniques. The goal of analytical chemistry is to determine the chemical composition of samples both qualitatively and quantitatively.
This document discusses the importance of instrumental analysis methods in conjunction with traditional analytical techniques. It provides an overview of fundamental principles of instrumental measurements and how they can be applied to specific chemical analyses. Key aspects covered include the differences between analytical techniques and methods, important terms, developing a method of analysis by defining the problem, sampling, sample preparation, performing measurements, and comparing results to standards. The overall message is that instrumental methods provide modern solutions to analytical problems when used appropriately alongside traditional methods.
Is a procedure or set of procedures intended to ensure that a manufactured or performed service adheres to a defined set of quality criteria or meets the requirements of client or customer. QC is similar to, but not identical with, quality assurance (QA)
This document summarizes analytical chemistry techniques used in forensic science laboratories. It describes how forensic labs are divided into areas like biology, chemistry, DNA, and toxicology. The chemistry lab analyzes samples like blood, urine, and drugs using techniques like Fourier transform infrared spectroscopy, gas chromatography/mass spectrometry, liquid chromatography/mass spectrometry, and atomic absorption spectroscopy to identify organic and inorganic compounds. These analytical techniques help determine the chemical composition of evidence and whether detected substances caused or contributed to death.
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The document defines key terms used in analytical chemistry, including analyte, sample, matrix, concentration, calibration curve, accuracy, precision, interference, standards, and more. It also provides examples of primary standards such as sodium carbonate and potassium hydrogen phthalate. Additionally, it discusses the scope of analytical chemistry and its role in fields like agriculture, environment, forensics, manufacturing, and more. The document aims to familiarize readers with fundamental concepts in analytical chemistry.
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This document provides an overview of analytical chemistry and instrumentation. It defines pharmaceutical chemistry and analytical chemistry. It discusses qualitative and quantitative analysis and describes common analytical instruments like pH meters, ORP meters, gas chromatographs, mass spectrometers, and spectrometers. It also outlines the analytical methodology and lists some applications of instrumental methods in fields like bioanalysis, environmental analysis, materials science, and forensic science.
This document discusses analytical methods validation as per ICH and USP guidelines. It provides an overview of the types of analytical procedures that require validation including identification tests, potency assays, limit tests, impurity tests, and specific tests. The key validation parameters discussed include specificity, accuracy, precision, linearity, range, limit of detection, limit of quantitation, ruggedness, and robustness. It also summarizes the objectives, types of procedures, and validation parameters for analytical method validation as defined by ICH and USP guidelines.
HTS is a high-tech way to hasten the drug discovery process, allowing quick and efficient screening of large compound libraries at a rate of a few thousand compounds per day or per week.
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1. 5/8/2024 1
SATISH PRADHAN
DNYANASADHANA COLLEGE-THANE-400604
DEPARTMENT OF CHEMISTRY
Introduction to Analytical Chemistry and
Statistical Treatment of Analytical Data
by
Dr.G.R.Bhagure
2. Syllabus
• Role of Analytical Chemistry (9 L)
• 1.1.1. Language of analytical chemistry: important terms and their significance in Analytical
• Chemistry.
• 1.1.2. Purpose of Chemical Analysis; Analysis Based (i) On the nature of information required:
• (Proximate, Partial, Trace, Complete Analysis) and (ii) On the size of the sample used
• (Macro, semi-micro and micro analysis)
• 1.1.3. Classical and Non-Classical Methods of Analysis; their types and importance.
• 1.2. Significance of Sampling in Analytical Chemistry
• 1.2.1. Terms involved in Sampling
• 1.2.2. Types of Sampling
• 1.2.3. Sampling techniques
• 1.3. Results of Analysis. (6L)
• 1.3.1. Errors in Analysis and their types
• 1.3.2. Precision and Accuracy in Analysis
• 1.3.3. Corrections for Determinate Errors
• (Problems including Numericals expected wherever required)
4. • The Language of Analytical Chemistry
1
• Analysis: A process that provides chemical or physical information
about the constituents in the sample or the sample itself.
2
• Analyte's: The constituents of interest in a sample.
3
• Matrix: All other constituents in a sample except for the
analyte's.
4
• Determination: An analysis of a sample to find the
identity, concentration, or properties of the analyte.
5
• Measurement: An experimental determination of an analyte’s
chemical or physical properties.
5. • The Language of Analytical Chemistry
6
• Accuracy: The agreement between measured value and True value
7
• Precision: The Agreement between number of Observations
8
• Selectivity: It is the degree to which the method is free from
interferences' present in matrix.
9
• Sensitivity : Ability of a method to discriminate between
two small concentration differences in the analyte
10
• Selectivity: It is defined as degree to which the method is free
from interferences from other components present in the matrix.
6. 11
• Dynamic range: It is the concentration range from limit
of Quantification (LOQ) to Limit of Linearity (LOL).
12
• Limit of Linearity (LOL) :
• It is defined as maximum concentration range up to which
instrument is produces linear response.
13
• Limit of detection(LOD):
• Minimum amount of concentration of a component that can be
detected with a given degree of confidence.
14
• Limit of Quantification (LOQ):
• Minimum amount of concentration of a component that can be
estimated with a given degree of confidence is termed as LOQ.
7. 12
• Technique: A chemical or physical principle that can be
used to analyze a sample.
13
• Method: A method is the application of a technique for the
determination of a specific analyte in a specific matrix.
14
• Procedure: Written directions outlining how to analyze a
sample.
11. Proximate
Analysis
• Amount of each element is determined with no concern of
sample. Ex. Proximate analysis of Coal which includes
determination of Moisture, Volatile compounds, Ash content,
fixed carbon
Partial
Analysis :
• It involves determination of selected constituent in the sample
Trace
analysis
• Trace analysis : It involves determination of specified
components in the sample in a very minute quantity.
Complete
analysis
• It involves determination of proportion of each components in
the sample .
12. On the size of the
sample used
Macro analysis: Size of the sample
ranges from more than 100 mg or
more than 100uL
Semi micro analysis: Size of the
sample ranges in between 10 mg-
100 mg or volume between 50-100
uL.
Micro analysis: Size of the sample
ranges in between 1 mg- 10 mg or
volume less than 50 uL.
19. Advantages of Non -
classical methods
Fast
No tedious
Accurate and sensitive
with greater precision
Small quantity of
sample required
Ability to detect and
estimate even trace
quantity
26. visible light
26
Light
Trap
Nephelometer
Read Out Device
Sample Cell
Photocell Detector
Collimating Lens
Graduated Disc
Technique is used when
concentration of suspended
particles are less
In this intensity of scattered
light is measured
31. 1.2 SAMPLING
Terms involved, importance of sampling, sampling
techniques, sampling of gases, ambient and stack
sampling, equipments used, sampling of homogenous
and heterogeneous liquids, sampling of static and
flowing liquids, methods and equipments used, sampling
of solids, importance of particle size, and sample size,
samples used In order to understand the criteria for
evaluating the utility of the analytical techniques, need
for the reduction in sample size, methods of reduction in
sample size, collection, preservation and dissolution of
the sample.
32.
33. • TERMSINVOLVED IN SAMPLING
1
• The Population or Universe
2
• Sampling Techniques or Procedures
3
• Sampling Unit:
4
• Increment:
5
• Gross Sample
6
• Sub sample:
7
• Analysis Sample:
34. 1
• The Population or Universe: The bulk material from which sample is to
be drawn is termed as Population or Universe.
2
• Sample: A small portion of the universe drawn for the purpose of
analysis and which posses all essential characteristics of the universe is
called as sample.
3
• Sampling Techniques or Procedures: The series of steps that is to be
carried out to obtain a sample Sampling Technique or sampling
procedure.
4
• Sampling Unit: The minimum size package in the consignment which
sample may represent is known as sampling unit.
5
• Increment: A stated amount of the material that is withdrawn from the
sampling unit is defined as Increment.
35. • Sampling Unit: The minimum size package in
the consignment which sample may represent
is known as sampling unit.
• Increment: A stated amount of the material
that is withdrawn from the sampling unit is
defined as Increment.
W1 W2 W3 W4
I1 I2 I3 I4
GROSS
SAMPLE
36. • Gross Sample: The total sample obtained
by mixing or blending all increments is
known as gross sample.
• Sub sample: A smaller size sample produced by
subdivision of the gross sample and which posses
all essential characteristics of the gross sample is
known as sub-sample.
• Analysis Sample: An accurately weighed
amount of sub sample taken actually for
analysis is known as analysis sample.
38. Judging acceptability:
To know the material from which sample
is withdrawn meets the essential
requirements such as purchase or sales
specification so that material can accepted
or rejected.
For this purpose sample should represent
the whole quantity under consideration
39. Detecting Contamination:
The second Objective or purpose of
sampling is to ensure that material is
free from contamination.
For this purpose sampling is carried out
such that sample will give maximum
assurance of finding the contamination.
40. Identification of Material:
Third purpose of sampling is
to identify the material. A
carefully drawn the sample
can accurately give
information of the material.
42. Random sampling
Random sampling: Random sampling involves the selection of
material without any bias or prejudice. In this method every part of
bulk material has an equal chance of being picked up as a sample.
This technique of sampling requires a minimum knowledge of the
universe under consideration. If the material is homogenous it is
easy to sampling.
If the material is homogenous, random sampling is easy to
perform.
If the material is heterogeneous sampling becomes time
consuming.
In random sampling bulk material is divided into groups. division
of groups is done on the basis of similarity in characteristics. from
each groups sample is withdrawn at random.
43. Non-Random sampling:
Sampling is carried out in more scientific
way than random sampling.
In this sampling better sample is not
obtain than random one.
Ex. in pharmaceutical industry sampling
of tablet is carried out systematically.
After every hundred tablet one tablet is
pick up for analysis..
44. • DIFFICULTIES ENCOUNTEREDIN SAMPLING
1
• Lack of prior information:
2
• Physical Nature: Ex. In pile of coal, the
interior portion is not easily available Or
sampling of rock material is difficult.
3
• Excessive cost: Time, labour, and money.
• Ex.if sampling units are too large, sampling cost will
go up.
45. Sampling of liquids
Care required for sampling of liquids
1
Cleanliness
of apparatus
and
containers
2
Preservation
of sample
composition
3
Positive
identification
of samples
1
2 3
46. Cleanliness of apparatus and containers
1
• Sample containers should be washed repeatedly with tap water and
then distilled water.
2
• Containers should be dried under sunlight or by warm air.
3
• Clean hands should be used while collecting sample
4
• Gloves should not be worn except when necessary ,if used it should
be clean.
5
• Containers should be labeled properly after sampling; date, location,
time, purpose of sampling ,nature of sample etc.
47. Preservation of sample composition
● If the sample contains solid particles or droplets of
immiscible liquid, care must be taken such that all
particles should transfer to sample containers.
●Sample should not allow to solidify.
●Dissolved and entrained gases should not allowed to
escape.
●Entraining air in the out side should be avoided
sample.
●During handling and transportation sample should
be protected against breakage, evaporation, leakage,
exposure to sunlight and entry of dust and air.
48. Positive identification of samples
1
• Proper location for sampling should be
identified.
2
• Consideration of location for sampling
must be justified.
49. Types of liquids to
be sampled
Homogenous Liquids
Heterogeneous liquids or immiscible
liquids
Liquids containing Emulsions or
unstable suspension
sampling of liquids containing
partially crystallized solids
Sampling of static and flowing
liquids.
Sampling of liquids from various
containers.
50. Apparatus for sampling of Homogenous Liquids
Heterogeneous liquids or immiscible liquids
A
B
Liquid
Sample
Thief
52. Heterogeneous liquids or immiscible liquids
• 1) Two immiscible liquids separating into two layers :
Liquid-2
Liquid-1
Height of the layers
Height of the layers
Sample thief is used to with draw the sample so that gross sample can be prepared.
53. Heterogeneous liquids or immiscible liquids
• 2) Emulsion or unstable suspension:
• Two phases are separated by filtration ,
• Solid and liquid are separated
• The two phases are weighed and then sampled
separately.
• If above is not feasible the entire suspension
is stirred vigorously and resulting liquid is
sampled.
Sample thief is used to with draw the sample so that gross sample can be prepared.
54. Heterogeneous liquids or immiscible liquids
• 3) sampling of liquids containing partially crystallized solids :
• Semi solidified liquid or liquid containing
crystallized solids are heated,
• Heating is continued till solid dissolves or
melts into liquid.
• Then sample is withdrawn by sample thief.
56. Devices for
sampling
of gases
Sampling probe:
Sampling line
attached to container
or vessel.
It is injected into gas
containers/pipe/well
etc.
Sample Container:
Vessel in which gas
sample is collected;
Size of containers
may vary from 250
cm3 to several
cubic meters.
57. General procedures for sampling of gases
Sample containers to hold the gas should be of glass
The containers are connected to stopcock at both ends which will
facilitate easy flushing.
The joints are made from glass to make container leak proof.
Rubber tubing should be avoided to avoid the reaction.
The stopcock are carefully cleaned and then lubricated every time
before every time.
The analysis of gas sample should be carried out simultaneously
or immediately, after the sampling .
Flushing, displacement by liquid and expansion into evacuated
vessel are general methods used for sampling of gases.
In flushing method, the sample container should be flushed with
the gas to be sampled ten to fifteen times.
59. Ambient sampling
The definite area is selected for sampling.
Sampling stations are decided on the
basis of grid pattern.
Sampling of atmospheric gases should be
carried out region wise and area wise and
time wise.
For. Ex. Sampling of atmospheric air in
Thane city
60. Stack sampling: Sampling of gases
released from industry is called as
stack sampling.
PLANT
Industry
Opening
for
sampling
of gas
61. Industrial gases are
generally sampled
continuously.
While sampling it should be ensured
that sample collected should
represent constant fraction of total
flow of all portions of streams are
sampled.
Stack
sampling:
64. Static method or Evacuation Method:
Sample container is evacuated by means of vacuum pump.
For evacuation stopcocks B&C are kept open and
stopcocks A &D are kept closed.
After evacuation the container is also warmed to remove
adsorbed gases on wall of the container. Then stopcock A and B
are closed ,C and D are open. The gas to be sampled is allowed
to entered into sample container through sample probe D
The excess of gas escape and immersed in a pool of mercury.
The evacuation and filling is carried out repeatedly to get desired
sample.
Use: This method is useful when small amount of gas is
available
65. Dynamic method:
Sample container is evacuated by means of vacuum pump.
During vaccumisation stop cock C is closed and A ,E AND
F are kept open.
During sampling, gas from the cylinder are admitted into
sample container.
By repeating procedure several times, the container is
flushed to remove the residual gas and desired sample will
be obtained.
Use: This method is useful when large amount of gas is
available
66. SAMPLING OF SOLIDS
• As solid are heterogeneous it is difficult to carry out sampling of
solids.Ex.in ores certain lumps are rich in the element of interest and
may rich in impurities such as silicates.Lumps of pure solid and
lumps of impurities in different sizes may lead to errors in sampling.
Such errors can reduced by crushing larger lumps into smaller size
or by taking large quantity of the sample.
• In this context the concept of bulk ratio is important.
• BULK RATIO= Weight Of The Sample Total Weight Of Bulk
Material
• SIZE TO WEIGHT RATIO= weight of the largest particle/weight of
the sample
67. Heterogeneous material
SOLIDS
Lumps of
pure solid
Rich in element of
interest
Lumps of
impure solid
Rich in impurities
Sample
size
Such errors can reduced by crushing larger lumps into smaller size or by
taking large quantity of the sample.
68. In this context the concept of bulk ratio is important.
BULK RATIO= Weight Of The Sample / Total Weight Of
Bulk Material
SIZE TO WEIGHT RATIO = weight of the largest
particle/weight of the sample.
This concept is applied to determine the number and
size of increment.
For sample which is true representative of bulk material bulk ratio of
the sample is large and size to weight ratio should be small
70. Coning and quartering
X
X
Cone of the
material
Material
flattened to
circle
Two opposite
parts selected
other two are
rejected
71. Long pile and alternate shovel method
1 2 3 4
1 and 3 are selected and 2 and 4 are rejected or vise versa
72. Rolling and quartering
X
X
Spreading of the
material on thin
polythene sheet
Material
flattened to
circle
Two opposite
parts selected
other two are
rejected
Rolling
75. Tube Sampler: It is thin walled tube ,5 to 10
cm in diameter. It is used for penetration of
predrilled hole.
Split barrel sampler: This is drilling equipment
attached to driller. The driving head made from hard
steel. It is 45 cm long. it is detached from the coupler
and opened to remove sample .
Geo sampler: It is for collection of
sample from planetary rock.
Split tube thief: A slot running through the
entire length of the tube. The end of the tube
is very sharp. The sharp end can pierced into
gunny bag.
77. Sampling of particulate solids
Sampling of particulate solids: dry and free
flowing Material called as particulate
solids.
Concentric tube thief
Solid
material
81. Collection ,preservation and
dissolution of sample
• COLLECTION: Collection of sample
depends on type of sample ,its
physical state, and its chemical state.
• When there is gap between
collection and analysis preservation
of sample is necessary.
82. • Preservation of sample
1
• When the sample is preserved its physical and
chemical composition should remain same.
2
• Sample should not react with the environment
nor with the sample container.
3
• Component of the sample should not react
among themselves.
4
• Composition of sample should not change
due to physical processes ex.volatilisation
83. Dissolution of
the Sample
Most analyses are performed on solutions of
the sample. Therefore, suitable solvent is
required to dissolve the sample rapidly and
under conditions in which there is no loss of
the analyte. The dissolution process depends
on the nature of the sample material.
84. Two most common methods
employed in dissolving inorganic
sample are :
(1) Treatment with Acids : hydrochloric acid, nitric
acid, mixture of hydrochloric and nitric acids,
sulphuric acid or perchloric acid, and
(2) Decomposition by Fluxes: fusion with an acidic
or basic flux followed by treatment with water or an
acid. Organic solvents are preferentially taken to
dissolve the samples of organic nature. However,
special methods are to be developed to dissolve a
silicate material, a high molecular weight polymer or
a specimen of animal tissue.