TGA and DTA are thermal analysis techniques that can be used to characterize materials. TGA measures mass change as a function of temperature, providing information about decomposition reactions and moisture/solvent content. DTA measures the temperature difference between a sample and reference, revealing endothermic and exothermic physical/chemical changes. Chromatography separates mixtures based on differences in component migration rates through a stationary and mobile phase. Common techniques include column chromatography, TLC, and gas chromatography.
Differential thermal analysis (DTA) is a thermal analysis technique that measures the temperature difference between a sample and an inert reference material as they are heated or cooled. DTA can detect physical or chemical changes in a sample as they occur, such as fusion, crystallization, oxidation, or decomposition. Changes are detected based on the temperature difference that develops between the sample and reference material. DTA provides a characteristic "fingerprint" curve for a sample that can be used to identify materials. Common applications of DTA include quantitative identification and purity assessment of materials.
Differential thermal analysis (DTA) is a thermal analysis technique that monitors the temperature difference between a sample and an inert reference material as both are subjected to a controlled temperature program. It detects endothermic or exothermic physical or chemical changes in the sample that cause temperature differences compared to the reference. A DTA instrument consists of sample and reference holders connected to thermocouples, a furnace, temperature programmer, and recording system to plot the differential temperature curve against time or temperature. DTA provides both qualitative and quantitative information about materials and is widely used in industries like pharmaceuticals, polymers, minerals, and cement.
Thermal analytical techniques measure physical properties of substances as a function of temperature. This document discusses differential thermal analysis (DTA), which compares the temperature of a sample to an inert reference as both are heated. DTA can detect exothermic or endothermic physical or chemical changes in a sample, such as melting, crystallization, or decomposition, as these processes cause the sample's temperature to increase or decrease relative to the reference. The temperature difference between sample and reference is plotted versus temperature or time to produce a DTA curve that can identify materials and characterize thermal processes.
This document discusses the use of thermal analysis techniques like differential thermal analysis (DTA), differential scanning calorimetry (DSC), and thermogravimetric analysis (TGA) in preformulation studies. These techniques are used to characterize properties of drug substances and excipients like polymorphism, degree of crystallinity, moisture content, and thermal stability. They provide important information on aspects like purity, solid-solid interactions, and decomposition behavior which helps optimize dosage form development. The principles and applications of DTA, DSC, and TGA are explained to analyze various thermal events in materials.
This document discusses several thermal analysis techniques including differential thermal analysis (DTA). It explains that DTA involves heating a sample and inert reference material simultaneously and measuring any temperature difference, which can indicate physical or chemical changes in the sample. The document provides details on DTA instrumentation, the factors that can affect DTA results, and applications such as material identification and purity assessment by comparing DTA curves.
This document discusses differential thermal analysis (DTA). It begins by defining thermal analysis and classifying different techniques. DTA principles and instrumentation are then explained. The document discusses the advantages and disadvantages of DTA, as well as several applications including identification of substances and detection of impurities. Thermal analysis can provide information about physical and chemical changes that occur as a substance is heated. DTA specifically measures the temperature difference between a substance and an inert reference as both are heated. This temperature difference corresponds to exothermic or endothermic reactions occurring in the substance.
Thermal analysis techniques measure physical properties as a function of temperature. Differential thermal analysis (DTA) and differential scanning calorimetry (DSC) compare the temperature of a sample to an inert reference as each is subjected to a heating or cooling program. In DTA, any temperature difference between sample and reference indicates a chemical or physical change in the sample. DSC directly measures heat flow into or out of the sample, allowing determination of transition temperatures and heats of reactions. Both techniques find applications in chemistry, materials science, polymers, pharmaceuticals and more.
1. Differential thermal analysis (DTA) is a technique that measures the temperature difference between a sample and an inert reference material as they are heated.
2. When a sample undergoes a chemical or physical change like melting or decomposition, it will absorb or release heat, causing its temperature to differ from the reference material. This temperature difference is plotted against temperature or time to produce a DTA curve.
3. Endothermic processes like melting cause negative peaks on the DTA curve as the sample temperature lags the reference. Exothermic processes like oxidation cause positive peaks as the sample temperature exceeds the reference. The shape, size, and temperature of peaks provide information about the sample.
Differential thermal analysis (DTA) is a thermal analysis technique that measures the temperature difference between a sample and an inert reference material as they are heated or cooled. DTA can detect physical or chemical changes in a sample as they occur, such as fusion, crystallization, oxidation, or decomposition. Changes are detected based on the temperature difference that develops between the sample and reference material. DTA provides a characteristic "fingerprint" curve for a sample that can be used to identify materials. Common applications of DTA include quantitative identification and purity assessment of materials.
Differential thermal analysis (DTA) is a thermal analysis technique that monitors the temperature difference between a sample and an inert reference material as both are subjected to a controlled temperature program. It detects endothermic or exothermic physical or chemical changes in the sample that cause temperature differences compared to the reference. A DTA instrument consists of sample and reference holders connected to thermocouples, a furnace, temperature programmer, and recording system to plot the differential temperature curve against time or temperature. DTA provides both qualitative and quantitative information about materials and is widely used in industries like pharmaceuticals, polymers, minerals, and cement.
Thermal analytical techniques measure physical properties of substances as a function of temperature. This document discusses differential thermal analysis (DTA), which compares the temperature of a sample to an inert reference as both are heated. DTA can detect exothermic or endothermic physical or chemical changes in a sample, such as melting, crystallization, or decomposition, as these processes cause the sample's temperature to increase or decrease relative to the reference. The temperature difference between sample and reference is plotted versus temperature or time to produce a DTA curve that can identify materials and characterize thermal processes.
This document discusses the use of thermal analysis techniques like differential thermal analysis (DTA), differential scanning calorimetry (DSC), and thermogravimetric analysis (TGA) in preformulation studies. These techniques are used to characterize properties of drug substances and excipients like polymorphism, degree of crystallinity, moisture content, and thermal stability. They provide important information on aspects like purity, solid-solid interactions, and decomposition behavior which helps optimize dosage form development. The principles and applications of DTA, DSC, and TGA are explained to analyze various thermal events in materials.
This document discusses several thermal analysis techniques including differential thermal analysis (DTA). It explains that DTA involves heating a sample and inert reference material simultaneously and measuring any temperature difference, which can indicate physical or chemical changes in the sample. The document provides details on DTA instrumentation, the factors that can affect DTA results, and applications such as material identification and purity assessment by comparing DTA curves.
This document discusses differential thermal analysis (DTA). It begins by defining thermal analysis and classifying different techniques. DTA principles and instrumentation are then explained. The document discusses the advantages and disadvantages of DTA, as well as several applications including identification of substances and detection of impurities. Thermal analysis can provide information about physical and chemical changes that occur as a substance is heated. DTA specifically measures the temperature difference between a substance and an inert reference as both are heated. This temperature difference corresponds to exothermic or endothermic reactions occurring in the substance.
Thermal analysis techniques measure physical properties as a function of temperature. Differential thermal analysis (DTA) and differential scanning calorimetry (DSC) compare the temperature of a sample to an inert reference as each is subjected to a heating or cooling program. In DTA, any temperature difference between sample and reference indicates a chemical or physical change in the sample. DSC directly measures heat flow into or out of the sample, allowing determination of transition temperatures and heats of reactions. Both techniques find applications in chemistry, materials science, polymers, pharmaceuticals and more.
1. Differential thermal analysis (DTA) is a technique that measures the temperature difference between a sample and an inert reference material as they are heated.
2. When a sample undergoes a chemical or physical change like melting or decomposition, it will absorb or release heat, causing its temperature to differ from the reference material. This temperature difference is plotted against temperature or time to produce a DTA curve.
3. Endothermic processes like melting cause negative peaks on the DTA curve as the sample temperature lags the reference. Exothermic processes like oxidation cause positive peaks as the sample temperature exceeds the reference. The shape, size, and temperature of peaks provide information about the sample.
Differential Thermal Analysis Introduction, Reference and Standard material, Instrumentation in that Furnace, Sample holder, Furnace temperature controller, DC amplifier and Recorder. Principle, Factors Affecting, Working, Physical and chemical reactions (Endotherm and Exotherm), Advantages and Disadvantages, Applications
Differential thermal analysis is a type of Thermal Analysis. This presentation includes definition of Thermal analysis, types of thermal analysis with focus on DTA, its principle, Instrumentation and applications.
Thermal analysis techniques such as differential thermal analysis (DTA) measure the temperature difference between a sample and an inert reference material as they undergo identical thermal cycles. DTA provides information about physical and chemical changes in a material as it is heated, such as melting, crystallization, and decomposition, by detecting endothermic or exothermic reactions. The DTA instrument consists of sample and reference holders connected to thermocouples within a furnace. Changes in the sample are detected as differences in temperature compared to the unreactive reference. DTA is useful for characterizing materials like minerals, polymers, and pharmaceuticals.
I. Thermal analysis is a technique used to study the physical, chemical, and mechanical properties of materials as a function of temperature. It provides information about phase transitions and thermal decomposition.
II. Common thermal analysis methods include TGA, DTA, DSC, TMA, DMA, dilatometry, and laser flash analysis. TGA measures weight changes upon heating, DTA/DSC detect endothermic and exothermic reactions, and TMA/DMA analyze dimensional changes and viscoelastic properties.
III. Thermal analysis finds applications in materials characterization, stability evaluation, compositional analysis, and determination of properties like glass transition temperatures.
Thermal methods of analysis involve measuring physical properties of substances as a function of temperature under controlled heating. Techniques commonly used in pharmacy include thermogravimetry, thermo-microscopy, differential thermal analysis, and differential scanning calorimetry. Thermogravimetry measures the mass of a substance as a function of temperature using a furnace, microbalance, and recorder to heat the substance and record weight changes. It can reveal details about decomposition temperatures and reactions.
Differential thermal analysis (DTA) measures the temperature difference between a sample and a reference material as both are heated. The apparatus consists of a sample holder with thermocouples, a furnace, temperature programmer, and recording system. The sample and reference are placed in identical cavities in a heating block within an oven. Thermocouples contact each to measure any temperature difference. Changes appear as endothermic or exothermic curves on a graph. DTA allows accurate determination of transition temperatures and is highly sensitive even at very high temperatures.
Thermal analytical methods such as differential scanning calorimetry (DSC) are important tools used in drug development to provide quantitative information about physical and chemical changes in materials as a function of temperature. DSC can be used to determine properties like melting points, glass transition temperatures, crystallization behavior, purity, and reaction kinetics. Samples are prepared in small pans and calibrated using standard reference materials before interpretation of transitions identified on DSC thermograms, which can indicate properties like polymorphism, purity according to established equations, or whether a compound is crystalline or amorphous. DSC finds regulatory use for characterization and is described in pharmacopeias with requirements for experimental documentation.
Differential thermal analysis (DTA) is a technique that monitors the temperature difference between a sample and an inert reference material as both are subjected to a controlled temperature program. Changes in the sample, whether endothermic or exothermic, can be detected relative to the reference. DTA provides information about physical and chemical changes that occur as a material is heated, such as melting, oxidation, and decomposition. The instrument consists of sample and reference holders connected to thermocouples, a furnace for heating, a temperature programmer, and a recording system to plot the differential temperature versus temperature or time.
Differential thermal analysis (DTA) is a thermal analysis technique that measures the temperature difference between a sample and an inert reference material as they are heated or cooled under identical conditions. [DTA] curves provide information about physical and chemical changes in a material as a function of temperature or time, such as fusion, decomposition, or phase transitions. The DTA technique involves heating a sample and reference material simultaneously while measuring any temperature differences between the two. Changes in the sample, such as exothermic or endothermic reactions, will result in temperature differences compared to the inert reference curve. DTA can be used to identify materials and assess purity by comparing sample curves to reference curves.
The document summarizes several thermal analysis techniques such as TMA, DSC, TGA, DTA, and TPD. It explains that these techniques involve heating a sample at a constant rate while measuring its properties, such as weight, size, heat flow, or gases evolved. The data
This document summarizes a seminar presentation on preformulation studies using thermal analysis, X-ray diffraction, and FT-IR spectroscopy. The presentation introduces various thermal analysis techniques including thermogravimetry, differential thermal analysis, and differential scanning calorimetry. Applications of thermal analysis in preformulation are discussed such as characterization of hydrates and solvates, study of polymers, detection of impurities, drug-excipient compatibility studies, polymorphism, prediction of drug stability, and degree of crystallinity. The document provides an overview of the techniques and their uses in preformulation studies.
Differential thermal analysis and differential scanning calorimetry are thermal analysis techniques that involve measuring physical properties of a sample as it is heated or cooled. In differential thermal analysis, the temperature difference between a sample and inert reference is measured as the sample undergoes physical or chemical changes. Differential scanning calorimetry directly measures the heat flow into or out of a sample as it is heated or cooled. Both techniques provide information about phase transitions, purity, crystallinity, and reactions in polymers, pharmaceuticals, minerals, and other materials.
Ppp Dsc 1 Thermal Analysis Fundamentals Of Analysisguest824336
Thermal analysis techniques such as differential scanning calorimetry (DSC) are used to investigate polymer properties as a function of temperature. DSC provides information on glass transition temperatures, crystallization temperatures, melting points, and heat capacity by measuring the heat flow into or out of a small polymer sample as it is heated or cooled. Proper sample preparation and experimental parameters are important to obtain accurate and reproducible DSC results.
Thermo mechanical analysis (TMA) measures the relationship between a sample's length or volume and temperature. TMA instruments precisely measure both the temperature of a sample and very small movements of a probe in contact with the sample. TMA is mainly used to study polymers, characterizing polymers and assessing their mechanical properties. Some applications of TMA include measuring the thermal expansion of materials like aluminum, studying the effect of cross-linking and plasticizers on polymers, and determining the relationship between hardness and indentation.
This document provides an overview of thermogravimetric analysis (TGA). TGA measures the mass of a substance as it is heated, allowing the determination of thermal stability and decomposition points. It describes key concepts like dynamic and isothermal TGA, and outlines the typical components of a TGA instrument including a furnace, balance, and temperature controller. Sample preparation and factors affecting analysis are also discussed. Applications include characterization of materials used in industries like pharmaceuticals and petrochemicals.
This document discusses Thermogravimetric Analysis (TGA) and Differential Scanning Calorimetry (DSC). TGA measures the change in weight of a sample during heating or cooling, while DSC measures the heat absorbed or released by a sample during phase transitions or chemical reactions. Both techniques provide information about physical and chemical changes in materials as functions of temperature. The document describes the principles, instrumentation, experimental procedures, sources of error, and applications of TGA and DSC for characterizing materials.
Basic Polymer identification and DSC and TGA analysisVatsal Kapadia
Vatsal K. Kapadia is interning at Larsen & Toubro in their Polymer Testing department. During the internship, he is analyzing various polymer materials to identify their composition and properties. Some of the techniques he is using include differential scanning calorimetry to determine melting points and glass transition temperatures, thermogravimetric analysis to measure composition and filler content, and conducting various tests such as burning samples to identify different polymer classes. The goal of his analysis is to help determine the appropriate materials for components and identify opportunities to improve products.
Thermogravimetry is a technique that measures the mass of a substance as a function of increasing temperature in a controlled temperature environment. Key aspects of thermogravimetry include the instrumentation used to precisely control and measure temperature and mass changes, factors that can influence results like heating rate and sample properties, and applications like compositional analysis, kinetic studies, and calibration. Thermogravimetry provides important information about physical and chemical processes like dehydration, decomposition, and phase transitions that are associated with weight changes.
Provides up to date information on DSC, recent developments and applicability. Recommended for those seeking up-to-date information on thermal analysis instruments.
Thermogravimetric analysis (TGA) is introduced as a technique to measure the changes in mass of a material as it is heated. Key points made in the document include:
- TGA is commonly used to assess the thermal stability and determine the composition of polymers. It measures the mass of a sample as it is heated in a controlled atmosphere.
- Common factors analyzed from TGA curves include the shape, temperatures of mass changes, and magnitudes of mass changes. Temperature of initial degradation and 5% mass loss are used to compare thermal stability.
- Polymers typically undergo degradation through mechanisms like decomposition, desorption, or oxidation, which result in mass changes. TGA can be used
Lecture notes on therm analysis in PowerPointJJsry
Thermal analysis techniques measure physical and chemical properties of substances as a function of temperature. Common techniques include thermogravimetric analysis (TGA), differential thermal analysis (DTA), and differential scanning calorimetry (DSC). TGA measures weight changes, DTA measures temperature differences between a sample and reference, and DSC measures heat flows. These techniques are useful for characterizing materials across many industries including polymers, chemicals, pharmaceuticals, foods, and metals. They provide information about phase transitions, decomposition reactions, purity, and more.
Differential Thermal Analysis Introduction, Reference and Standard material, Instrumentation in that Furnace, Sample holder, Furnace temperature controller, DC amplifier and Recorder. Principle, Factors Affecting, Working, Physical and chemical reactions (Endotherm and Exotherm), Advantages and Disadvantages, Applications
Differential thermal analysis is a type of Thermal Analysis. This presentation includes definition of Thermal analysis, types of thermal analysis with focus on DTA, its principle, Instrumentation and applications.
Thermal analysis techniques such as differential thermal analysis (DTA) measure the temperature difference between a sample and an inert reference material as they undergo identical thermal cycles. DTA provides information about physical and chemical changes in a material as it is heated, such as melting, crystallization, and decomposition, by detecting endothermic or exothermic reactions. The DTA instrument consists of sample and reference holders connected to thermocouples within a furnace. Changes in the sample are detected as differences in temperature compared to the unreactive reference. DTA is useful for characterizing materials like minerals, polymers, and pharmaceuticals.
I. Thermal analysis is a technique used to study the physical, chemical, and mechanical properties of materials as a function of temperature. It provides information about phase transitions and thermal decomposition.
II. Common thermal analysis methods include TGA, DTA, DSC, TMA, DMA, dilatometry, and laser flash analysis. TGA measures weight changes upon heating, DTA/DSC detect endothermic and exothermic reactions, and TMA/DMA analyze dimensional changes and viscoelastic properties.
III. Thermal analysis finds applications in materials characterization, stability evaluation, compositional analysis, and determination of properties like glass transition temperatures.
Thermal methods of analysis involve measuring physical properties of substances as a function of temperature under controlled heating. Techniques commonly used in pharmacy include thermogravimetry, thermo-microscopy, differential thermal analysis, and differential scanning calorimetry. Thermogravimetry measures the mass of a substance as a function of temperature using a furnace, microbalance, and recorder to heat the substance and record weight changes. It can reveal details about decomposition temperatures and reactions.
Differential thermal analysis (DTA) measures the temperature difference between a sample and a reference material as both are heated. The apparatus consists of a sample holder with thermocouples, a furnace, temperature programmer, and recording system. The sample and reference are placed in identical cavities in a heating block within an oven. Thermocouples contact each to measure any temperature difference. Changes appear as endothermic or exothermic curves on a graph. DTA allows accurate determination of transition temperatures and is highly sensitive even at very high temperatures.
Thermal analytical methods such as differential scanning calorimetry (DSC) are important tools used in drug development to provide quantitative information about physical and chemical changes in materials as a function of temperature. DSC can be used to determine properties like melting points, glass transition temperatures, crystallization behavior, purity, and reaction kinetics. Samples are prepared in small pans and calibrated using standard reference materials before interpretation of transitions identified on DSC thermograms, which can indicate properties like polymorphism, purity according to established equations, or whether a compound is crystalline or amorphous. DSC finds regulatory use for characterization and is described in pharmacopeias with requirements for experimental documentation.
Differential thermal analysis (DTA) is a technique that monitors the temperature difference between a sample and an inert reference material as both are subjected to a controlled temperature program. Changes in the sample, whether endothermic or exothermic, can be detected relative to the reference. DTA provides information about physical and chemical changes that occur as a material is heated, such as melting, oxidation, and decomposition. The instrument consists of sample and reference holders connected to thermocouples, a furnace for heating, a temperature programmer, and a recording system to plot the differential temperature versus temperature or time.
Differential thermal analysis (DTA) is a thermal analysis technique that measures the temperature difference between a sample and an inert reference material as they are heated or cooled under identical conditions. [DTA] curves provide information about physical and chemical changes in a material as a function of temperature or time, such as fusion, decomposition, or phase transitions. The DTA technique involves heating a sample and reference material simultaneously while measuring any temperature differences between the two. Changes in the sample, such as exothermic or endothermic reactions, will result in temperature differences compared to the inert reference curve. DTA can be used to identify materials and assess purity by comparing sample curves to reference curves.
The document summarizes several thermal analysis techniques such as TMA, DSC, TGA, DTA, and TPD. It explains that these techniques involve heating a sample at a constant rate while measuring its properties, such as weight, size, heat flow, or gases evolved. The data
This document summarizes a seminar presentation on preformulation studies using thermal analysis, X-ray diffraction, and FT-IR spectroscopy. The presentation introduces various thermal analysis techniques including thermogravimetry, differential thermal analysis, and differential scanning calorimetry. Applications of thermal analysis in preformulation are discussed such as characterization of hydrates and solvates, study of polymers, detection of impurities, drug-excipient compatibility studies, polymorphism, prediction of drug stability, and degree of crystallinity. The document provides an overview of the techniques and their uses in preformulation studies.
Differential thermal analysis and differential scanning calorimetry are thermal analysis techniques that involve measuring physical properties of a sample as it is heated or cooled. In differential thermal analysis, the temperature difference between a sample and inert reference is measured as the sample undergoes physical or chemical changes. Differential scanning calorimetry directly measures the heat flow into or out of a sample as it is heated or cooled. Both techniques provide information about phase transitions, purity, crystallinity, and reactions in polymers, pharmaceuticals, minerals, and other materials.
Ppp Dsc 1 Thermal Analysis Fundamentals Of Analysisguest824336
Thermal analysis techniques such as differential scanning calorimetry (DSC) are used to investigate polymer properties as a function of temperature. DSC provides information on glass transition temperatures, crystallization temperatures, melting points, and heat capacity by measuring the heat flow into or out of a small polymer sample as it is heated or cooled. Proper sample preparation and experimental parameters are important to obtain accurate and reproducible DSC results.
Thermo mechanical analysis (TMA) measures the relationship between a sample's length or volume and temperature. TMA instruments precisely measure both the temperature of a sample and very small movements of a probe in contact with the sample. TMA is mainly used to study polymers, characterizing polymers and assessing their mechanical properties. Some applications of TMA include measuring the thermal expansion of materials like aluminum, studying the effect of cross-linking and plasticizers on polymers, and determining the relationship between hardness and indentation.
This document provides an overview of thermogravimetric analysis (TGA). TGA measures the mass of a substance as it is heated, allowing the determination of thermal stability and decomposition points. It describes key concepts like dynamic and isothermal TGA, and outlines the typical components of a TGA instrument including a furnace, balance, and temperature controller. Sample preparation and factors affecting analysis are also discussed. Applications include characterization of materials used in industries like pharmaceuticals and petrochemicals.
This document discusses Thermogravimetric Analysis (TGA) and Differential Scanning Calorimetry (DSC). TGA measures the change in weight of a sample during heating or cooling, while DSC measures the heat absorbed or released by a sample during phase transitions or chemical reactions. Both techniques provide information about physical and chemical changes in materials as functions of temperature. The document describes the principles, instrumentation, experimental procedures, sources of error, and applications of TGA and DSC for characterizing materials.
Basic Polymer identification and DSC and TGA analysisVatsal Kapadia
Vatsal K. Kapadia is interning at Larsen & Toubro in their Polymer Testing department. During the internship, he is analyzing various polymer materials to identify their composition and properties. Some of the techniques he is using include differential scanning calorimetry to determine melting points and glass transition temperatures, thermogravimetric analysis to measure composition and filler content, and conducting various tests such as burning samples to identify different polymer classes. The goal of his analysis is to help determine the appropriate materials for components and identify opportunities to improve products.
Thermogravimetry is a technique that measures the mass of a substance as a function of increasing temperature in a controlled temperature environment. Key aspects of thermogravimetry include the instrumentation used to precisely control and measure temperature and mass changes, factors that can influence results like heating rate and sample properties, and applications like compositional analysis, kinetic studies, and calibration. Thermogravimetry provides important information about physical and chemical processes like dehydration, decomposition, and phase transitions that are associated with weight changes.
Provides up to date information on DSC, recent developments and applicability. Recommended for those seeking up-to-date information on thermal analysis instruments.
Thermogravimetric analysis (TGA) is introduced as a technique to measure the changes in mass of a material as it is heated. Key points made in the document include:
- TGA is commonly used to assess the thermal stability and determine the composition of polymers. It measures the mass of a sample as it is heated in a controlled atmosphere.
- Common factors analyzed from TGA curves include the shape, temperatures of mass changes, and magnitudes of mass changes. Temperature of initial degradation and 5% mass loss are used to compare thermal stability.
- Polymers typically undergo degradation through mechanisms like decomposition, desorption, or oxidation, which result in mass changes. TGA can be used
Lecture notes on therm analysis in PowerPointJJsry
Thermal analysis techniques measure physical and chemical properties of substances as a function of temperature. Common techniques include thermogravimetric analysis (TGA), differential thermal analysis (DTA), and differential scanning calorimetry (DSC). TGA measures weight changes, DTA measures temperature differences between a sample and reference, and DSC measures heat flows. These techniques are useful for characterizing materials across many industries including polymers, chemicals, pharmaceuticals, foods, and metals. They provide information about phase transitions, decomposition reactions, purity, and more.
lecture notes of thermal analysis in power pointsJJsry
Thermal analysis techniques measure physical and chemical properties of materials as they are heated or cooled at controlled rates. Common techniques include thermogravimetric analysis (TGA), differential thermal analysis (DTA), and differential scanning calorimetry (DSC). TGA measures weight changes, DTA measures temperature differences between a sample and reference, and DSC measures heat flows. These techniques are useful for characterizing materials across many industries including polymers, chemicals, pharmaceuticals, foods, and metals. They provide information about phase transitions, decomposition reactions, purity, and thermal stability.
Gas chromatography (GC) is a common type of chromatography that separates compounds by vaporizing them and passing them through a column with a carrier gas. It can be used to test purity, separate mixtures, and identify unknown compounds. Key components include an inlet to introduce the sample, a column to separate components, and a detector. The carrier gas moves the vaporized sample through the column where components interact differently with the stationary phase and elute at different retention times.
Gas chromatography (GC) is a common type of chromatography used in analytical chemistry for separating and analysing compounds that can be vaporised without decomposition.
Thermal analysis techniques such as thermogravimetric analysis (TGA), differential scanning calorimetry (DSC), and thermal mechanical analysis (TMA) are used to determine the physical and chemical properties of materials as a function of temperature and time. TGA measures weight changes that occur as a material is heated, allowing determination of composition and thermal stability. DSC measures heat flow into or out of a material during phase transitions or chemical reactions. These techniques provide information on material properties and transformations useful for various applications including composite analysis, degradation studies, and quality control.
It include all the thermal methods widely used in large and small scale industries with detailed applications and examples for explanations.
Medha Thakur (M.Sc Chemistry)
The document outlines an experiment using differential scanning calorimetry (DSC) to analyze polymethylmethacrylate (PMMA). The objectives are to understand DSC principles, analyze material degradation, identify weight changes via thermogravimetric analysis (TGA), and determine the glass transition and melting points. PMMA is calibrated in the DSC machine and heated from 30-250°C at 15°C/min. The results show PMMA's glass transition is 105°C, crystallization is 135°C, and melting is 160°C. DSC and TGA are useful for characterizing many material properties as a function of temperature.
This document provides an overview of gas chromatography. It begins by defining chromatography and tracing the history of gas chromatography from its origins in 1903 to its development in the 1940s-1950s. It then describes the basic components and working principles of gas chromatography, including the mobile phase, stationary phase, factors that influence separation, and common instrumentation. It also discusses different types of chromatography techniques and gas chromatography columns. In summary, the document provides a comprehensive introduction to gas chromatography, its history, principles, instrumentation and applications.
Thermal analysis methods like thermogravimetry (TG) and differential scanning calorimetry (DSC) can be used to quantitatively determine the composition of water-in-oil emulsions. TG allows determining the water content through isothermal measurements, while successive heating and cooling in DSC enables determining the amount of ammonium nitrate. If sodium nitrate is also present, it and ammonium nitrate must first be separated from organic matter using diethyl ether before TG. The ratio of ammonium nitrate to sodium nitrate can then be determined from their binary phase diagram.
This document provides an introduction and overview of gas chromatography (GC). It discusses the basic principles of GC, which involves separating components of a mixture based on how they partition between a stationary and mobile phase. The key components of a GC system are described, including the injector where samples are introduced, the column where separation occurs, the oven that controls temperature, and various detectors. Different types of columns, stationary phases, temperature programs, and detectors are discussed to provide flexibility in GC analysis for a wide range of applications.
1) Thermogravimetric analysis (TGA) measures the weight changes of a material as it is heated in different atmospheres. It can be used to analyze inorganic materials, metals, polymers, ceramics, and composites.
2) The document describes using TGA to analyze the thermal decomposition of calcium oxalate monohydrate. Calcium oxalate monohydrate decomposes in three steps as it is heated.
3) The measured mass losses at each step of decomposition closely matched the theoretical predictions, validating the predicted thermal decomposition reactions of calcium oxalate monohydrate.
Gas chromatography is a technique used to separate and analyze mixtures that can be vaporized without decomposition. It works by partitioning components to be separated between a stationary phase and a mobile gas phase. The key components of a gas chromatography instrument are the carrier gas, injection port, column, temperature control system, and detector. Factors like temperature, flow rate, column length, and amount of sample injected can influence separation of the components. Gas chromatography has applications in qualitative and quantitative analysis and is used in quality control of pharmaceuticals.
Gas chromatography and high performance liquid chromatography are analytical techniques used to separate mixtures. Mikhail Tswett invented chromatography in 1901 to separate plant pigments using a glass column packed with calcium carbonate. Liquid chromatography was later refined using smaller packing materials and pumps to deliver solvents at high pressures, allowing for faster separations and the development of high performance liquid chromatography. Chromatography works by separating components in a mixture based on how they interact differently with a stationary and mobile phase as they flow through a column.
Gas chromatography is a technique used to separate and analyze volatile compounds. It works by injecting a sample into a column through which an inert gas flows, carrying the separated components out at different rates depending on their interactions with the stationary phase coating the column. The separated components are detected to produce a chromatogram showing peaks that can be analyzed to determine the identity and quantity of each component in the original sample.
1. Gas chromatography is a technique used to separate mixtures by partitioning components between a stationary and mobile liquid or gas phase.
2. It works by forcing a gaseous or volatile sample mixture through a column containing a solid or liquid stationary phase, which interacts differently with each component. This causes the components to elute from the column at different times.
3. Gas chromatography is useful for separating volatile organic compounds and finds applications in fields like drug analysis and purity testing due to its high resolution, sensitivity, speed, and ability to perform both qualitative and quantitative analysis.
Gas chromatography separates and analyzes compounds by carrying them through a column with an inert gas as the mobile phase. Components separate based on differences in how they partition between the stationary and mobile phases. It is used to detect small volatile compounds and analyze substances like air pollutants, drugs, and industrial chemicals. Key parts include the carrier gas, injection port, separation column coated with a stationary phase, and detector.
Basavarajeeyam is an important text for ayurvedic physician belonging to andhra pradehs. It is a popular compendium in various parts of our country as well as in andhra pradesh. The content of the text was presented in sanskrit and telugu language (Bilingual). One of the most famous book in ayurvedic pharmaceutics and therapeutics. This book contains 25 chapters called as prakaranas. Many rasaoushadis were explained, pioneer of dhatu druti, nadi pareeksha, mutra pareeksha etc. Belongs to the period of 15-16 century. New diseases like upadamsha, phiranga rogas are explained.
Promoting Wellbeing - Applied Social Psychology - Psychology SuperNotesPsychoTech Services
A proprietary approach developed by bringing together the best of learning theories from Psychology, design principles from the world of visualization, and pedagogical methods from over a decade of training experience, that enables you to: Learn better, faster!
Basavarajeeyam is a Sreshta Sangraha grantha (Compiled book ), written by Neelkanta kotturu Basavaraja Virachita. It contains 25 Prakaranas, First 24 Chapters related to Rogas& 25th to Rasadravyas.
Osteoporosis - Definition , Evaluation and Management .pdfJim Jacob Roy
Osteoporosis is an increasing cause of morbidity among the elderly.
In this document , a brief outline of osteoporosis is given , including the risk factors of osteoporosis fractures , the indications for testing bone mineral density and the management of osteoporosis
ABDOMINAL TRAUMA in pediatrics part one.drhasanrajab
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1559024845_1559024845.pdf
1. 1 Chapter 3
The principle of TGA and its applications:
TGA is thermogravimetric analysis.
It is one of the thermal method of analysis. (Thermal methods of analysis are based on the dynamic
relationship between temperature with a change in physical property like mass change or enthalpy change
etc)
In TGA mass of the substance is continuously monitored as the temperature is linearly increased.
TGA apparatus is used to measure TGA. It can scan over a wide range of temperature (25 – 1200 ⁰C)
The main components of TGA apparatus
1. A high precision thermobalence (± 10 μg)
2. Furnace with temperature programming facility.
3. Facility for providing inert atmosphere (like N2 gas) Or Oxidizing environment
4. A computer which can collect, store and process data – like plotting the graph.
The mass vs Temperature plot is called Thermogram. (an idealised thermogram is shown below)
Region I: The horizontal indicates the region where there is no mass
change. Ie from T1 to T2 the material is thermally stable.
Region II: The graph declines indicating a weight loss (weight loss can
be due to dehydration, decomposition, sublimation, desorption,
Evaporation etc. [Weight gain during Metal Oxidation, adsorption
etc]
2. 2 Chapter 3
Applications:
1. Thermal stability of substance 2. Decomposition mechanism of inorganic salts.
Consider the TGA-thermogram of calcium oxalate monohydrate CaC2O4.H2O.
From the graph it is seen that calcium oxalate monohydrate CaC2O4.H2O is stable upto 100⁰C.
Removal of water begins at 100⁰C and gets completed at 226⁰C.
The horizontal portion 226-346⁰C shows the thermal stability of CaC2O4.
Decomposition of CaC2O4 to CaCO3 with the elimination of CO occurs in the temperature range 346-
420⁰C.
The 420-660⁰C horizontal portion gives the thermal stability of CaCO3.
Above 660⁰C CaCO3decomposes to CaO and CO2.
From the mass difference the mechanism of decomposition can be deduced.
3. Qualitative analysis
a. Identification of inorganic salts.
b. Detection of purity of sample.
Decomposition TGA-thermogram pattern is unique characteristic one. Sometimes it helps to identify many
materials by comparison. Purity of sample can also be analysed from TGA-thermogram.
4. Evaporation rates of different liquid mixtures.
5. Quantitative analysis
a) TGA can be used to find the amount of fillers such us in CaCO3 compounded in a plastic.
b) It can be used to estimate the amount of substance present in a mixture if the mechanism and
temperature of decomposition is known. Example the composition of Ca and Ba in CaCO3 + BaCO3 mixture
can be analysed.
3. 3 Chapter 3
Assume that CD is MgCO3 and AB is CaCO3. (AB+CD is Mixture of CaCO3.+ MgCO3)
From figure b (curve bc represent decomposition of CaCO3), x mg of CO2 is evolved form CaCO3
Ie, CaCO3 → CaO + CO2
40 + 12 + (16 x 3) = 100 g of CaCO3 contains 40 + 16 = 56 g CaO and 12 + (16 x 2) = 44 g of CO2
Ie, 44 g of CO2 Ξ 100 g of CaCO3
1 g of CO2 Ξ 100/44 g of CaCO3
Then, x g of CO2 Ξ x (100/44) g of CaCO3
Similarly one can obtain the weight of MgCO3
c) Proximate analysis of Coal (to find out moisture content, volatile matter :- Coal is heated up to 950 o
C in
inert atmosphere) (to find out combustible carbon and ash content ;- Coal is heated in presence of oxygen)
4. 4 Chapter 3
6. Analysis of Polymers (Thermal Stability of Polymers and Identification of polymers from the
thermogram)
Differential Thermogram: (dm/dt vs T)
5. 1 Chapter 3
Application of TGA: Proximate analysis of Coal
Process that can be studied by TGA
Evaporation, Sublimation, oxidation, decomposition, desorption, adsorption etc.
Limitations of TGA
TGA can study process which accompanies a mass change. Ie it cannot study
process like melting, transitions from one crystalline form to another, glass transition
temperature etc.
Differential Thermal Analysis (DTA) and Its Applications
DTA is Differential thermal analysis.
It is one of the thermal method of analysis. (Thermal methods of analysis are based on the dynamic
relationship between temperature with a change in physical property like mass change or enthalpy change
etc)
DTA basics
The material under study and an inert reference material (alumina, silicon carbide etc) are subjected to
identical heating procedure – Temperature is increased linearly.
The temperature difference between the sample and reference material is recorded.
6. 2 Chapter 3
The differential temperature (ΔT) is plotted against the temperature T or time t to get DTA curve.
An idealized DTA curve is shown below,
There is zero temperature difference between
sample and reference when the sample does not
undergo a physical or chemical change.
Physical and chemical processes are either
exothermic or endothermic. Therefore during such a
process a temperature difference will develop. After
the completion of process the temperature again
becomes identical to that of reference.
During endothermic process sample is at lower temperature than reference. Therefore a minimum is
observed in DTA curve.
During exothermic process, sample is at a higher temperature than reference. Therefore a maximum is
observed in DTA curve.
Physical changes like melting, vaporization, desorption, sublimation etc and chemical process like
dehydration, reduction and decomposition are endothermic.
Physical changes like adsorption, crystallization and chemical process like oxidation, polymerization and
chemisorption are exothermic.
Example: DTA of calcium oxalate monohydrate CaC2O4.H2O
DTA apparatus
1) A sample holder and reference hoolder with thermocouple + amplifier assembly
2) A furnace with temperature programming facility.
3) Equipment for controlling the environment
- Providing inert atmosphere if needed.
- Providing air circulation if oxidation is needed.
7. 3 Chapter 3
4) A computer to collect, store, process data – like plotting the graph.
Applications:
1) DTA provide accurate way to determine the melting and boiling point of organic compounds.
2) To find the enthalpy change (ΔH) of a process.
The area enclosed under DTA peak is proportional to mass (m) of the sample and enthalpy change
(ΔH).
3) To distinguish exothermic and endothermic process.
4) Unlike TGA, DTA can give information regarding a phase change where there is no change in mass
(Fusion, boiling, transition from one crystalline form to another etc).
5) Characterization of polymers. It is based on measurement of properties like glass transition
temperature, melting point, decomposition temperature, thermal stability etc.
8. 1 Chapter 3
Chromatography
It is a method used for separating the components of a mixture. The purpose is separation, purification or
identification. The technique was invented by Mikhail Tswett, a Russian botanist.
All chromatographic techniques consist of a mobile phase and stationary phase. Components of mixture are
carried through the stationary phase (it is fixed in a place) by the flow of mobile phase. Migratory rates will be
different for different components due to interaction of solute with stationary phase.
Terms --- a. Mobile phase b. Stationary phase and c. elution
All chromatographic separation techniques contain a mobile phase and a stationary phase.
Stationary phase is fixed in a place. Can be a solid (Finely divided solid adsorbent material packed in a column)
or a liquid (Liquid held on the inner wall surface of capillary tube or liquid held on the pore structure of solid
substances).
Components of the mixture are carried through the stationary phase by the flow of mobile phase. Mobile
phase can be a liquid or gas.
Elution is the process of passing mobile phase through the column to transport solute for separation.
Types Of Chromatography – Based on interaction of solute (Adsorption Chromatography, Partition
chromatography and Ion Exchange Chromatography)
Chromatographic separation is based on differences in migration rate of components in a sample. This
difference in rates is due to difference in interaction of the components with the stationary phase. Based on
the type of interaction chromatography is classified into,
Adsorption chromatography: The migration rate of each component differs due to the difference in
extent of adsorption of components on the surface of stationary phase. Stationary phase is a solid and the
mobile phase can be liquid or gas. Example: column chromatography, thin layer chromatography and gas solid
chromatography.
Partition Chromatography: The migration rate of each component differs due to the difference in
partition or distribution of solute in stationary phase with respect to mobile phase. Stationary phase is a liquid
and the mobile phase can be liquid or gas. Example: gas liquid chromatography and liquid phase HPLC.
Ion Exchange chromatography: Here the stationary phase has ion exchange property and a particular
charge. Separation is due to the difference of affinity of each ion toward the ion exchange resin
Another Classification (Based on mobile phase -- Gas Chromatography (Mobile is a gas and stationary phase is
a solid/liquid) and Liquid Chromatography (Mobile phase is liquid and stationary phase can be solid/liquid)
Advantages /Main Application of chromatography
It is possible to separate very small amount of substance therefore used for purification purpose. Method is
very simple.
9. 2 Chapter 3
Column Chromatography
It is one of the simplest chromatographic methods of separation.
Stationary phase is finely divided solid adsorbent kept in a glass column. Commonly used adsorbent materials
are silica gel and alumina gel. The mobile phase is a liquid which is continuously added to the top of column
and flows down the column due to the action of gravity.
Sample (Components A+B) to be separated is dissolved in a suitable solvent and introduced to the top of the
stationary phase.
Column Chromatography is Adsorption Chromatography therefore each component migrates at different rate
due to the difference in extent of adsorption.
Extent of adsorption of each component in the sample will be different. When we start elution the mobile
phase solvent, the weakly adsorbed one will move faster whereas the strongly adsorbed one moves very
slowly.
Weakly adsorbed component will come out first and the strongly adsorbed one will come out last. The
fractions obtained are collected and evaporated to remove the solvent.
Polarity of solvent (mobile phase) influence the separation. Like dissolves like, therefore highly polar solvents
moves a highly polar component rapidly.
Consider a sample which is a mixture of non-polar A and polar B. If we are eluting with a non-polar solvent, A
will come out first from the column. B will come out only after a long time.
Uses of column Chromatography:
Purification of dyes, natural products, pigments etc.
It is commonly used by researchers for the separation of desired compound after synthesis.
10. 3 Chapter 3
THIN LAYER CHROMATOGRAPHY (TLC)
TLC is an adsorption chromatography. The stationary phase is a solid adsorbent, here a sheet of plastic, glass or
metal is coated with a thin layer of solid adsorbent (finely divided silica or alumina)
Sampling: Small amount of mixture to be separated is dissolved in a suitable solvent and spotted near the
bottom of the TLC plate using a capillary tube.
The TLC plate is placed in a solvent. The solvent level should be below the spot. This process is called TLC
development.
The mobile phase, ie the solvent rises up the TLC plate due to capillary action. As the solvent passes the spot it
carries different components at different rate. The component which is weakly adsorbed moves upward very
fast and the other one which is strongly held moves very slowly.
When the solvent front has reached the top of the plate, the TLC plate is removed and dried. Separated
components are visualized. If coloured, one can differentiate it with his eyes, If not (a) put TLC plate in iodine
chamber. Iodine will develop a black colour with most of the organic compounds. (b) Keep the developed TLC
Plate under UV light - aromatic compounds and conjugated dienes produce blue fluorescent spots. (c) Spray
stain reagents (Ninhydrin produces purple colour for amino acids, FeCl3 in dil HCl produces red spot for
phenols, 2,4-dinitrophenyl-hydrazine produces yellow to red spots for aldehydes and ketones, Bromocresol
green produces yellow t green spots for carboxylic acids.)
Advantage and Applications:
... Simple, quick and inexpensive procedure
... Used to check how many components are present in the sample.
... To check purity of sample
... To monitor progress of a chemical reaction
... To select ideal solvent for column chromatography based on Retention Factor.
11. 4 Chapter 3
Retention Factor RF Value: It is the ratio.
Uses of Retention Factor.
a) Used for identification of substance by comparing the retention factor.
b) To select ideal solvent for carrying out column chromatography is based on Retention Factor
differences.
Principle, instrumentation and application of Gas Chromatography GC
GC is gas chromatography (a separation technique). Mixture is separated into its
constituents by a moving gas passing over a stationary phase.
Mobile Phase is gas.
Stationary phase can be solid or liquid. If stationary phase is solid then the basis of separation is difference in
adsorption and the chromatography is called gas solid chromatography GSC. if the stationary phase is liquid
the basis of separation is partition (distribution of solute in mobile and stationary phase) and the
chromatography is called gas liquid chromatography GLC.
12. 5 Chapter 3
Instrumentation for GC. (For GLC and GSC the difference is only in the column)
Carrier gas system:
A source for carrier gas – the mobile phase. Carrier gas is used to transport vaporized sample through the
column. Carrier gas should be inert to stationary phase and components in sample Most commonly used one
is N2 gas. H2 He and Ar can also be used.
Pressure regulator and flow controller are used to adjust flow rate.
Pre-heater heats the carrier gas before elution.
Sample injection system:
Sample is injected using a calibrated micro syringe. Injection is almost instantaneous.
The sample must be converted into vapour state. Resistance heating is used to vaporize sample.
Column and stationary phase:
Column is the heart of chromatographic instrument.
GLC Column : Long capillary column made from capillary tube. Length of column is 3 to 300 meter.
Inner diameter is 0.1 to 1mm. Stationary phase is thin film of liquid coated on the inner surface of capillary
tube.
13. 6 Chapter 3
Or
Short tube like packed column can also be used. The column is packed with finely divided glass
beads. Length of column is 3 to 6 meter. Inner diameter is 1 to 6mm. Stationary phase is liquid held on the
pores of this material.
In general choice of the liquid phase is based on polarity of substances to be separated. The liquid should be
inert, should be non-volatile and thermally stable under operation conditions. Example polar liquid ---
Carbowax-400 . Non-polar liquid ---- n-cetane and silicone oil.
GSC Column : A short tube like packed column is used. Column is packed with finely divided activated
solid adsorbents like silica, alumina, activated charcoal etc. Length of column is 0.7 to 6 meter. Inner diameter
is 1 to 6mm. Stationary phase is solid adsorbents. It should be thermally stable, chemically inert and should
have large surface area.
Efficiency of column is directly proportional to the length of column.
The performance of column increases with decrease of column diameter.
Detectors:
Any physical property which varies from one gas to another and which can be easily monitored forms
the basis of detector.
Thermal conductivity detector (kathrometer) TCD or KCD: Most commonly used detector. Property
monitored is thermal conductivity. Thermal conductivity of pure carrier gas will be different from the one
containing the sample and carrier gas. Sensing element is a thermistor. Temperature across the thermistor
varies depending on the variations in thermal conductivity which in turn changes the resistance. Resistance
changes can be sensed by a wheat-stone bridge circuit. TCD is a non-destructible detector system, therefore
can be used for preparative works.
Flame ionization detector FID: Ions are formed during combustion of organic compounds in Hydrogen
flame. FID is based on detection of these ions. The ions generated are collected by an electrode. A potential
difference develops between this electrode and a base electrode which causes a current to flow. The current is
proportional to concentration of ions which depends on the concentration of organic compound and the
nature of organic species. High sensitivity ( can even detect very low concentrations to high concentrations).
Low cost and low maintenance. It is destructible analytical technique.
.
Recording device:
Recording device give the chromatogram. A plot of detector response vs time is chromatogram. With only
carrier gas flowing through the detector, the recorder is calibrated to zero ie base line. Each separated
components evokes a detector response which registers a peak in chromatogram.
14. 7 Chapter 3
Procedure: The sample is injected to the injection port using a calibrated micro syringe. It is vaporized using
resistance heating. Pre-heated carrier gas carries the vaporized sample through the column where it gets
separated out depending on the interaction of components with stationary phase. Detector will give a
differentiating response for each component separation.
Application:
1. GC is widely used to test purity of organic compounds (impurity is revealed by additional peaks).
2. GC is used to monitor air pollution.
3. By using GC ethyl alcohol content in the blood can be determined with high accuracy.
4. Banned drugs used by athletes can be detected by taking GC of blood and urine sample.
5. GC coupled with mass spectrometry (GC-MS) is used for analysis of hydrocarbon fuels. Perfumes,
flavours etc.
6. Separation of close boiling liquids (Benzene 80.1 o
C and cyclohexane 80.9 o
C)
Factors Affecting retention time (chromatographic separation)
a. The polarity of components versus the polarity of stationary phase on column
If the polarity of the stationary phase and compound are similar, the retention time
increases because the compound interacts stronger with the stationary phase. As a
result, polar compounds have long retention times on polar stationary phases and
shorter retention times on non-polar columns using the same temperature.
b. Column temperature
A excessively high column temperature results in very short retention time but also
in a very poor separation because all components mainly stay in the gas phase.
c. Carrier gas flow rate
A high flow rate reduces retention times, but a poor separation
d. Column length
A longer column generally improves the separation
e. Order of elution is mainly determined by volatility of sample
Least volatile is most retained in the column. Polar compounds (ex: alcohols) are the least volatile and
will be the most retained on the GC system
15. 8 Chapter 3
Principle, instrumentation and application of HPLC
High performance liquid chromatography (a separation technique).
Mobile Phase is liquid
Stationary phase can be solid or liquid (most commonly used is liquid). If stationary phase is solid then the
basis of separation is difference in adsorption, and if it is liquid the basis of separation is partition (distribution
of solute in mobile and stationary phase).
Unlike gas chromatography vaporization of sample is not required for HPLC.
Elution can be done in two ways.
Isocratic elution: mobile phase composition remains constant throughout the chromatographic
separation procedure.
Gradient elution: mobile phase composition is varied during separation process. Required polarity for
separation is achieved by mixing. Gradient elution helps to shorten the retention time. Therefore overall time
required for separation can be considerably reduced.
The common organic solvents used as mobile phase are benzene, cyclohexane, acetone, ethanol etc.
Instrumentation for HPLC.
The main column:
Quite narrow column. Column is packed with particles of small size (3-10 μm). Efficiency of HPLC column
increases when the particle size is reduced.
16. 9 Chapter 3
In order to achieve constant flow rate pressure pumps are used to drive solvent (5000 psi pressure to achieve
flow rate of 1 to 10 ml/min).
Glass tubes cannot withstand such a high pressure therefore smoothly bored stainless tube like columns are
used. Column length 10 – 30 cm , inner diameter 4-10mm.
Two types of modes of operation are there for HPLC:
Normal phase operation: Highly polar stationary phase and non-polar mobile phase. Polar compounds
are retained for longer time. For normal phase silica powder bonded with OH group is used as stationary
phase.
Reverse phase operation: Non-polar stationary phase and polar mobile phase. Non-polar compounds
are retained for longer time. Here silica powder bonded with O-CH3 group is used as stationary phase.
Detectors:
Bulk property detector: These monitor a difference in physical property of the pure solvent (mobile phase)
with respect to the one containing sample + solvent. Properties usually monitored are refractive index,
dielectric constant, density etc.
Solute property detector: These detector respond to physical property of the solute such as UV-visible
absorption, fluorescence etc. Mobile phase may or may not have such a response.
Recorder gives the chromatogram (plot of detector response vs time).
Applications:
Can be used for separating volatile and non-volatile organic compounds like natural products (such as
cholesterol, tri-terpinoids etc)
Separation of polypeptides
More amount of compound can be separated when compared with GC.
Can be used to find concentration of trace components
Monitor pesticides level.
To ensure purity of raw materials
Can be used to check food adulteration
HPLC is useful for pharmaceutical, forensic and environmental application.
Why oxygen is unsuitable as carrier gas in GLC?
Oxygen is not chemically inert. It may oxidise some components in the sample. Therefore it is not suitable as a
carrier gas.
17. 10 Chapter 3
------------------------------------------------------------------------------------------------------------------------
Differentiate between GLC and GSC?
GSC GLC
1. Mobile phase Gas Gas
2. Stationary phase solid Liquid
3. Column Packed column Packed or capillary column
4. Basis of separation Difference in Adsorption Difference in Partition
5. Length of column Relatively short long column
6. Thermal stability Good stability Less stable above 300⁰C
of stationary phase
7. Reaction in column Adsorbent may catalyse relatively inert
some reaction.
8. Applicability useful for separation of all volatile materials except
permanent gas and low more permanent gases.
Boiling substances.
What are the information obtained from a chromatogram?
a. The number of peaks will tell us the number of species present.
b. Retention time: time between injection of a sample and the appearance of solute peak at the detector.
Compound can be identified from retention time.
c. Quantitative estimation. Area enclosed by the peak is related to the quantity.
----------------------------------------------------------------------------------------------------------------------------
Differentiate between GC and HPLC?
Mobile phase in GC is gas while mobile phase of HPLC is liquid.
Volatile compounds can only be separated using GC. Even non-volatile compounds like natural products such
as cholesterol, tri-terpenoids can be seperated using HPLC.
Using HPLC more amount of compound can be separated than GC.
----------------------------------------------------------------------------------------------------------------------------
Q. What are the various visualization Technique used in TLC?
Ans: If coloured once can visualize with naked eye
One can visualize spots by irradiating with UV light – blue spot for aromatics and dienes.
Put TLC plate in iodine chamber, iodine develops a black colour with organic
compounds.
Use a stain agent, example Ninhydrin develops a purple colour for amines and
aminoacids.
18. 11 Chapter 3
---------------------------------------------------------------------------------------------------------------------------
Q. Explain the basic principles of TGA with example.
TGA is a technique that monitors mass of substance as the temperature is linearly increased.
Process like dehydration, desorption and decomposition results in a weight change. The TGA
thermogram of CaCO3 is given below,
From the graph it is clear that the CaCO3 is thermally stable up to 660o
C. In the region 660-
840o
C the decomposition of CaCO3 to CaO and CO2 takes place.
---------------------------------------------------------------------------------------------------------------------------
Q. What is RF value in chromatography?
Rf value =
For example, if a compound travels 2.1 cm and the solvent front travels 2.8 cm, the Rf is 0.75.
Q. How do we measure cell constant?
( ) Cell constant is a factor that is
used to convert measured conductance to conductivity. Cell constant of conductivity cell is geometric
factor L / A. It is the ratio of distance between electrodes to area of electrodes. It is very difficult to
precisely obtain the geometric factors. Therefore cell constant is experimentally determined by measuring
conductance of solutions having known conductivity (aqueous KCl solutions).
19. 12 Chapter 3
Q. Give the principles of HPLC. How does it differ from gas chromatography?
Ans: HPLC – High performance liquid chromatography is a separation technique. The mobile
phase is liquid and stationary phase can be a liquid or solid. Liquid stationary phase is most
common one. Here the basis of separation is difference in partition (relative solubility) of solute in
stationary phase and mobile phase.
A small amount of sample to be separated is dropped into the injection port. A high pressure
pump is used to drive the solvent for elution. It carries the components to be separated through
the stationary phase. The relative migration rate of each component is different due to the
deference in relative solubility of each component in stationary phase and mobile phase. The
separated components are detected by bulk property or solute property detector.
Differences
Mobile phase of GC is a gas, whereas mobile phase of HPLC is liquid.
Only Volatile compounds (or gaseous) can be separated using GC. Even non-volatile compounds
can be separated using HPLC.
Gradient elution and Isocratic elution is possible for HPLC.
Using HPLC more amounts of compounds can be separated than GC.
For HPLC a high pressure pump is required to drive solvent for elution whereas for GC tit is not
required.
--------------------------------------------------------------------------------------------------------------------------
Q. Explain the experimental procedure involved in measurement of conductivity of a solution.
Construct a wheat stone bridge circuit. One arm of the bridge is connected to the conductivity cell dipped in
test solution (R1). The other arms two connected to fixed resistanceR3 and R4 and the fourth arm is connected
to a variable resistance (R2). AC current is given. A suitable detector is also connected (Head phone?). The
bridge is balanced when no current pass through the detector. The head phone will not produce any sound
when the bridge is balanced.
If we make R3 and R4 identical, then R1 = R2 ie the resistance of the test solution is the resistance of variable
resistor when the bridge is at balance. From the resistance conductance can be measured.
Then conductivity = conductance x cell constant.
20. 13 Chapter 3
--------------------------------------------------------------------------------------------------------------------------
Q. What are the applications of Conductivity Measurement:
Ionic concentrations, Salinity, Sodium Concentrations in Urine, Total dissolved salts etc....
-----------------------------------------------------------------------------------------------------------------------
Q. What are the information obtained from a chromatogram?
d. The number of peaks will tell us the number of species present.
e. Retention time: time between injection of a sample and the appearance of solute peak at the detector.
Compound can be identified from retention time.
f. Quantitative estimation. Area enclosed by the peak is related to the quantity.
Q. What is meant by retention time?
Retention time: It is the time interval between injection of a sample and the appearance of solute peak at
the detector. It gives as an idea of How much time a compound stayed on the stationary phase. If the
conditions maintained are same, compound can be identified from retention time.
21. 14 Chapter 3
Q. Explain the applications of TLC and Column Chromatography.
Uses of column Chromatography:
Purification of dyes, natural products, pigments etc.
It is commonly used by researchers for the separation of desired compound after synthesis.
Uses of TLC
... Simple, quick and inexpensive procedure
... Used to check how many components are present in the sample.
... To check purity of sample
... To monitor progress of a chemical reaction
... To select ideal solvent for column chromatography based on Retention Factor.
---------------------------------------------------------------------------------------------------------------------------
Q. Explain the significance of Rf value. ?
Every compound (dye, pigment, organic substance etc) have a specific Rf value for
every specific solvent and solvent concentration. Also the relative differences in Rf
value helps in the selection of solvent for preparative chromatographic separation.
Q. Based on mechanism of separation classify chromatographic techniques.
Ans: a. If separation occurs due to relative differences in adsorption -- Adsorption
chromatography.
b. If separation occurs due to relative differences in partition (ie solubility) -- Partition
chromatography.
22. 15 Chapter 3
c. If molecules are separated according to their differences in size ---- size exclusion
chromatography.
d. Based on the differences in affinity towards ion exchanger - ion exchange
chromatography.
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Q.What are the different types of detectors used in gas chromatography?
Ans:
Thermal conductivity detector (kathrometer) TCD or KCD: Most commonly used detector. Property
monitored is thermal conductivity. Thermal conductivity of pure carrier gas will be different from the one
containing the sample and carrier gas. Sensing element is a thermistor. Temperature across the thermistor
varies depending on the variations in thermal conductivity. Resistance changes can be sensed by a wheat-
stone bridge circuit. TCD is a non-destructible detector system, therefore can be used for preparative works.
Flame ionization detector FID: Ions are formed during combustion of organic compounds in Hydrogen
flame. FID is based on detection of these ions. The ions generated are collected by an electrode. A
potential difference develops between this electrode and a base electrode which causes a current to flow.
The current is proportional to concentration of ions which depends on the concentration of organic
compound and the nature of organic species. High sensitivity ( can even detect very low concentrations to
high concentrations). Low cost and low maintenance. It is destructible analytical technique.
Q. Define elution. Mention types of elution in HPLC?
Elution is the process of passing mobile phase through the stationary phase to transport solute for
separation.
In HPLC elution can be done in two ways,
Isocratic elution: mobile phase composition remains constant throughout the chromatographic separation
procedure.
Gradient elution: mobile phase composition is varied during separation process. Required polarity for
separation is achieved by mixing. Gradient elution helps to shorten the retention time. Therefore overall time
required for separation can be considerably reduced.
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23. 16 Chapter 3
Q. What is the necessity of guard column in HPLC?
The main column used in HPLC instrument is very costly and sensitive. So in order to protect it
from contaminants in the mobile phase a guard column is used.
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Q. What are the main components of a TGA instrument?
Q. What is the importance of HPLC in chemical analysis?
Q. In what way DTA study of polymer helpful to a chemist?
Q. Discuss the information obtainable by applying thermal analysis techniques in the study of solid
polymers.
Q. Describe and interpret the thermogram obtained from a TGA experiment by taking a suitable
example.
Q. What is the significance of peaks in a differential thermogram?
Q. Given a perfume sample, how will you analyse it using GC?
Q. Distinguish between TGA and DTA?
Q. Draw and illustrate the thermogram showing the decomposition of hydrated calcium oxalate.
Q. Suggest the best chromatographic technique for the separation of natural dyes?
Q. Athletes takes performance enhancer drugs. How can you as a chemist analyse if such a
malpractice has taken place?
Q. What is the use of pre-heater in GC?
Q. Compare reverse phase operation and normal phase operation in HPLC.
Q. Outline the GC procedure.
Q. How is Rf value for a spot on TLC plate is calculated? What can Rf value be used for?
Q. What are the advantages of TLC as compared to column chromatography?
Q. Compare column chromatography with TLC.
Q. What are the two most common stationary phase used in column and thin layer chromatography?
24. 17 Chapter 3
Q. Consider the following silica gel TLC plate of compounds A, B, C developed in hexane,
a. Which compound A, B or C is most polar?
Ans: Compound A is most polar. It does not travel as far as the other two compounds.
Q. What are the two basic components of any chromatography system?
Q. What is the difference between analytical and preparative chromatography?
Q. List some ways you could reduce the retention time.
Ans: One way to reduce retention time is by gradient elution in HPLC, changing the
composition of solvent for polarity changing.
The other way increasing the flow rate of mobile phase
Increasing the operating temperature in gas chromatography reduces retention time.
Decreasing the length of column containing stationary phase.
Q. What is meant by a bulk property detector? Give an example of an HPLC detector
that is based on bulk properties and one that is not.
Q. What is gradient elution and how does this differ from an isocratic one? What
advantage does gradient elution have over isocratic separations?
Q. What is the significance of maxima and minima in a differential thermogram?
Q. What are the main components of DTA instrument?
Q. What kind of reference materials are used in DTA? Give two examples.
Q. How can you identify a polymer from TGA analysis?
Q. List three reasons for weight loss in TGA analysis?
Q. Explain why all chemical and physical process can be studies with DTA while
some physical process cannot be studied using TGA.
25. 18 Chapter 3
Q. What is the limitations of TGA experimens and explain how the DTA
overcomes it?
Q. Suggest an instrumental method to measure the evaporfation rates of liquid
mixtures and to determine the purity of a chemical compound. Mention its principle.
Q. Suggest an instrumental method to measure the boiling point and melting point
of a chemical compound. Mention its principle.
Q. Give two examples each of endothermic Physical and chemical process.
Q. Give two examples each of exothermic Physical and chemical process.
26. Conductivity
Conductors: Materials that can pass electric current through it. It can be electronic (current is
carried by the movement of electrons as in metals and semiconductor metals) or electrolytic
(Current is carried by the movement of cations and anions)
Insulators: Materials that cannot pass electric current through it.
Electrical Resistance R (unit is ohm): It is a measure of obstructions to the current flow.
R is proportional to the Length L of Conducting medium and inversely proportional to the cross
sectional Area A of the conducting medium
Ie, Where ρ is the proportionality constant Resistivity or Specific Resistance (unit is
ohm cm)
When L = 1unit (1 cm) and A = 1 unit2
(1cm2
) then ρ = R is specific resistance or resistivity is the
resistance of a conducting medium of unit length and unit cross section.
Electrical Conductance G (unit is ohm-1, mho or Siemens): It is a measure of ease with which current
is flowing. It is the reciprocal of electrical resistance.
G = 1/R
Where k is specific conductance or Conductivity (S cm-1
)
Conductivity is the conductance of 1 cm3
of conducting medium. It is the ability of solution to pass
electric current. L/A is cell constant Kcell of conductivity cell. Cell constant is
a factor that is used to convert measured conductance to conductivity. It is the ratio of distance
between the electrodes to area of electrodes.
Conductivity Cell and cell constant measurement: Consist of two platinum coated electrodes
having 1cm2
area and they are kept 1cm apart.
Cell constant can be theoretically determined from the geometry of cell. Kcell = L/A. But it is very
difficult to precisely obtain the geometric factors. Therefore cell constant is experimentally
determined by measuring conductance of solutions having known conductivity (aqueous KCl
solutions).
27. Experimental set up to determine conductance and conductivity
Construct a wheat stone bridge circuit. One arm of the bridge is connected to the conductivity cell
dipped in test solution (R1). The other arms two connected to fixed resistanceR3 and R4 and the
fourth arm is connected to a variable resistance (R2). AC current is given. A suitable detector is also
connected (Head phone?). The bridge is balanced when no current pass through the detector. The
head phone will not produce any sound when the bridge is balanced.
If we make R3 and R4 identical, then R1 = R2 ie the resistance of the test solution is the resistance of
variable resistor when the bridge is at balance. From the resistance conductance can be measured.
Then conductivity = conductance x cell constant.
Applications of Conductivity Measurement:
Total dissolved solids, Ionic concentrations, Salinity, Sodium Concentrations in Urine etc.....
Advantages
Non-destructive measurements
Fast and reliable
Inexpensive
Drawback
Not ion selective (give a reading of Combined effect of all the dissolved ions)
Pblm1: Calculate the conductivity of given sodium chloride solution at 298 K which shows a
conductance of 500 micro-mho in a cell. A standard solution of 0.01 M KCl shows a conductance of
128 micro-mho in that cell. Given that conductivity of 0.01 M KCl solution is 0.00128/(ohm cm) at
298 K.
Soln:
= = 10 cm-1
.
ohm-1
cm-1
.
28. Pblm2: The specific conductance of N/50 KCl solution at 25o
C is 0.0002765
Ohm-1
cm-1
. If the resistance of the cell containing this solution is 500 ohm,
what is the cell constant?
Soln:
Conductance G = 1/R = 1/500 = 0.002 Simens
Conductivity = Specific conductance = 0.0002765 Ohm-1
cm-1
= 0.0002765 Siemens cm-1
= cm-1
Pblm3: The resistance of 0.01 N NaCl solution at 25 o
C is 200 Ohm. Cell
constant of conductivity cell is unity. Calculate the solution specific
conductance (conductivity).
Soln:
cm-1
Conductance G = 1/R = 1/200 = 0.005 Simens
Siemens cm-1
.
Pblm4: The resistance of a conductivity cell when filled with 0.02 M KCl
solution is 164 ohm at 25 o
C. however when filled with 0.05 M AgNO3
solution its resistance is dropped to 82 ohm. Calculate the conductivity of
AgNO3 solution. Give that specific conductivity of 0.02 M KCl is 2.788
mOhms-1
cm-1
.
Soln:
Conductivity k of KCl = 2.788 x 10-3
Simens Cm-1
Conductance of KCl G = 1/R = 1/164 = 0.006 Simens
Conductance of AgNO3 G = 1/R = 1/82 = 0.012 Simens
= cm-1
ohm-1
cm-1
.
29. PBLM: Imagine that you have 1 ml of solution that contains 1 gram equivalent
(Equivalent weight in grams) of an electrolyte and the conductance is 0.100 S.
If the solution is diluted to 9ml, what will be the conductance, specific
conductance and equivalent conductance of the diluted solution?
Soln: hint
If the solution is diluted to say (9 cm3) (9 mL), the conductance of the solution will be the
same but specific conductance becomes 1/9th as it contains nine cubes.
PBLM: A column of diameter 1 cm and length 50 cm filled with 0.05 M NaOH. The
resistance of the solution is found to be 5.55 x 103
ohm. Calculate its
resistivity, conductance and conductivity. Hint Area = r2