(1) The document discusses cathode rays, positive rays, and matter waves.
(2) Cathode rays are streams of electrons emitted from the cathode of discharge tubes. Positive rays are streams of positive ions that pass through holes in the cathode.
(3) Experiments with cathode rays helped determine the specific charge of electrons. Mass spectrographs use electric and magnetic fields to separate positive ions based on their mass-to-charge ratio.
(4) According to de Broglie, all moving particles exhibit wave-like properties with a wavelength inversely proportional to momentum. This established the wave-particle duality of matter.
When light encounters a surface, or travels from one media to another, several interactions are possible. For general lighting, we are typically interested in reflection, transmission, refraction, total internal reflection (which is really a special case of refraction), and absorption.
This presentation has been moved. To view this presentation, please visit http://pubs.acs.org/iapps/liveslides/pages/index.htm?mscNo=jz3008408
Ultrafast Studies of the Photophysics of Cis and Trans States of the Green Fluorescent Protein Chromophore
This document discusses the analysis of oxides using Laser Assisted Atom Probe Tomography. It provides motivation for studying oxides at the atomic scale and describes sample preparation techniques. Results are presented on analyzing thin films of SiO2, MgO, and HfO2. Key findings include being able to analyze oxides depending on layer thickness and sample preparation. The document concludes that further improvements in sample preparation and analysis are needed to fully characterize oxides using this technique.
Interpreting and Understanding Dynamic Light Scattering Size DataHORIBA Particle
Jeff Bodycomb of HORIBA Scientific provides a short presentation about interpreting dynamic light scattering data for particle size. Learn how dynamic light scattering instruments collect data and how that data is transformed into particle size information including central values and distributions. This presentation will be useful for SZ-100 Nanoparticle Analyzer users and anyone who would like to become more comfortable with DLS data.
The document is a registration form for a one or two year classroom program to prepare for competitive exams like IIT-JEE. It requests information like name, address, percentage in math and science, exam preferences. It also has the student rank their skills in areas like clarity of concepts and ability to work hard. The form must be submitted with payment and photos by a week before the test date to register. Registration fees are non-refundable and tests dates are chosen from options provided. The program is offered through Anurag Tyagi Classes which has branches in Ghaziabad.
Best therapy for small superficial treatment areasRosannah Smith
The document compares electron therapy and low energy photon therapy for small superficial treatments. Film dosimetry experiments show that electron therapy results in underdosing of the central treatment area and overdosing of surrounding healthy tissue for fields smaller than 3 cm due to the wide penumbra. In contrast, photon therapy provides a more uniform dose across the majority of the treatment area with a much narrower penumbra, avoiding misdosing. Therefore, photons are concluded to provide a safer and more effective option than electrons for small superficial treatments.
This document discusses radiotherapy equipment, including low-energy machines and external beam equipment such as superficial x-ray units, orthovoltage machines, telecurie units using radioactive cobalt-60 and cesium-137 sources, and linear accelerators. It describes the properties, production, applications and limitations of different radiotherapy machines. The document focuses in detail on cobalt-60 teletherapy units, explaining their photon energy, production method, source design and shielding, dose profile, and techniques to reduce penumbra.
When light encounters a surface, or travels from one media to another, several interactions are possible. For general lighting, we are typically interested in reflection, transmission, refraction, total internal reflection (which is really a special case of refraction), and absorption.
This presentation has been moved. To view this presentation, please visit http://pubs.acs.org/iapps/liveslides/pages/index.htm?mscNo=jz3008408
Ultrafast Studies of the Photophysics of Cis and Trans States of the Green Fluorescent Protein Chromophore
This document discusses the analysis of oxides using Laser Assisted Atom Probe Tomography. It provides motivation for studying oxides at the atomic scale and describes sample preparation techniques. Results are presented on analyzing thin films of SiO2, MgO, and HfO2. Key findings include being able to analyze oxides depending on layer thickness and sample preparation. The document concludes that further improvements in sample preparation and analysis are needed to fully characterize oxides using this technique.
Interpreting and Understanding Dynamic Light Scattering Size DataHORIBA Particle
Jeff Bodycomb of HORIBA Scientific provides a short presentation about interpreting dynamic light scattering data for particle size. Learn how dynamic light scattering instruments collect data and how that data is transformed into particle size information including central values and distributions. This presentation will be useful for SZ-100 Nanoparticle Analyzer users and anyone who would like to become more comfortable with DLS data.
The document is a registration form for a one or two year classroom program to prepare for competitive exams like IIT-JEE. It requests information like name, address, percentage in math and science, exam preferences. It also has the student rank their skills in areas like clarity of concepts and ability to work hard. The form must be submitted with payment and photos by a week before the test date to register. Registration fees are non-refundable and tests dates are chosen from options provided. The program is offered through Anurag Tyagi Classes which has branches in Ghaziabad.
Best therapy for small superficial treatment areasRosannah Smith
The document compares electron therapy and low energy photon therapy for small superficial treatments. Film dosimetry experiments show that electron therapy results in underdosing of the central treatment area and overdosing of surrounding healthy tissue for fields smaller than 3 cm due to the wide penumbra. In contrast, photon therapy provides a more uniform dose across the majority of the treatment area with a much narrower penumbra, avoiding misdosing. Therefore, photons are concluded to provide a safer and more effective option than electrons for small superficial treatments.
This document discusses radiotherapy equipment, including low-energy machines and external beam equipment such as superficial x-ray units, orthovoltage machines, telecurie units using radioactive cobalt-60 and cesium-137 sources, and linear accelerators. It describes the properties, production, applications and limitations of different radiotherapy machines. The document focuses in detail on cobalt-60 teletherapy units, explaining their photon energy, production method, source design and shielding, dose profile, and techniques to reduce penumbra.
This document summarizes key concepts in electron beam dosimetry and monitor unit calculations. It discusses electron beam interactions, depth dose distributions, characteristics of clinical beams, and factors that affect dose such as field size, distance, and inhomogeneities. It also describes how monitor units are calculated using output factors, distance corrections, and prescription isodose levels to determine the monitor units needed to deliver a prescribed dose to the treatment volume. Sample problems demonstrate how these concepts are applied in practice.
This document discusses key concepts in radiotherapy dosage, including:
1. Surface dose and kilovoltage radiation were limiting factors, while megavoltage radiation allows deeper penetration with less scatter.
2. Primary radiation output depends on tube current, voltage, target material and distance from source, while scattered radiation depends on beam size, shape, and material properties.
3. With megavoltage beams, electrons travel farther, depositing most energy at the end of their track and creating a "build up" where dose increases with depth before falling off due to inverse square law.
The document contains a foundation course on matter in our surroundings from CBSE. It includes 11 multiple choice questions about the properties of solids, liquids, and gases. It then has an objective test section with fill-in-the-blank, true/false, and multiple choice questions related to states of matter, phase changes, density, temperature scales, and other concepts. The questions assess understanding of key ideas like the differences between solids, liquids, and gases, properties like compressibility and thermal conduction, and processes like evaporation, diffusion, and sublimation.
multiple filed arrangement in Radiotherapy, Medical College KolkataKazi Manir
The document discusses various radiation therapy techniques for dose distribution in matter using multiple fields and wedge fields. It covers:
1) Using multiple fields allows more uniform dose distribution in the tumor compared to a single field, while limiting dose to normal tissues.
2) Parallel opposed fields provide simplicity but can excessively dose normal tissues above and below the tumor. Larger field sizes are needed for adequate coverage.
3) Patient thickness, beam energy, and field size must be considered to minimize lateral tissue effects and ensure uniform dose distribution.
4) Multiple techniques like wedges, isocentric beams, and field matching seek to further optimize dose distribution while sparing critical structures. Proper planning and verification is important.
Electron beam therapy uses electrically charged particles called electrons that are generated by a linear accelerator to treat superficial cancers. It deposits dose uniformly from the surface to a specific depth before rapidly falling off, sparing deeper tissues. Electron energies up to 20 MeV can treat disease within 6 cm of the surface. Accessories like applicators, cutouts, bolus and internal shields are used to shape the beam for treatment fields and protect healthy tissues. Precise dose specification and reporting is important for electron therapy due to the rapid dose fall-off and higher skin doses compared to prescription depth.
IIT JEE PHYSICS Class Notes by Ambarish Srivastava (Part 3)Ambarish Srivastava
These are the IIT JEE Physics Notes that I dictated to my students of Class XI in the Year 2013... Thanks to my Student Sanchit Minocha for Writing the notes nicely, whose photocopy I am sharing.... This is part 3 Covers Waves and Sound (Continued from part 2)
IIT JEE PHYSICS Class Notes by Ambarish Srivastava (Part 2)Ambarish Srivastava
These are the IIT JEE Physics Notes that I dictated to my students of Class XI in the Year 2013... Thanks to my Student Sanchit Minocha for Writing the notes nicely, whose photocopy I am sharing.... This is part 2 up to From Collisions to Waves Including Thermodynamics ... Waves Continues in part 3
The document discusses key concepts in radiobiology relevant for radiotherapy. It defines important treatment volumes including the gross tumour volume (GTV), clinical target volume (CTV), planning target volume (PTV), treated volume (TV), irradiated volume (IV), and organs at risk (OARs). It also describes biological factors that influence radiation effects on tissues, known as the "5 Rs": repair, repopulation, reoxygenation, redistribution, and radiosensitivity. Fractionated radiotherapy takes advantage of these factors to maximize tumor cell kill while minimizing damage to normal tissues.
Toppersnotes-- Sample for physics, chemistry and mathematicsToppersNotes
Toppersnotes is an education initiative by students of IIT bombay who want to help the present day IIT-JEE aspirants in an innovative way.We provide toppers handwritten notes & their strategy to jee aspirants. www.toppersnotes.in
This document provides information on dosimetric calculations for radiation therapy. It discusses key concepts like percent depth dose (PDD) and tissue maximum ratio (TMR) which are used to calculate dose for non-isocentric and isocentric setups, respectively. Factors like collimator scatter, phantom scatter, and beam modifiers are also covered. The document outlines the basic principles and provides examples of SSD and SAD calculations.
Electron beam therapy uses megavoltage electron beams to treat superficial tumors within 6 cm of the skin surface, sparing deeper tissues. The dose distribution of electron beams provides a uniform dose in the target region followed by a rapid dose fall-off. Treatment planning for electron beams requires consideration of electron energy, air gaps, tissue inhomogeneities, and adjacent fields to determine the optimal dose distribution. Electron beams can effectively treat many superficial cancers of the skin, limbs, and surgical beds.
The document discusses the components and operation of a linear accelerator used for radiation therapy. It describes the key parts of a linear accelerator including the electron gun, accelerator structure, treatment head and how they work together to generate photon or electron beams for radiation treatment. The linear accelerator uses microwave technology to accelerate electrons which are then converted into x-ray or electron beams that can be aimed at a tumor from multiple angles using the rotating gantry.
1. There are fundamental and process limitations to energy efficiency due to losses from imperfect conversions and practical constraints. Fundamental limitations arise from physical laws, while process limitations are due to real-world application issues.
2. Calculating energy efficiency involves determining the useful energy output compared to the total energy input. For any process or system, the energy efficiency can never be 100% due to inevitable losses.
3. Different forms of energy can be converted to other forms, but with losses due to the second law of thermodynamics. Not all energy can be converted to other desired forms.
IIT JEE PHYSICS CLASS NOTES UPLOADED BY Er. AMBARISH SRIVASTAVA (AIR 538)Ambarish Srivastava
IIT JEE PHYSICS NOTES PART 6
Semiconductor Devices, Principles of Communication,
Diffraction, Polarization.
Uploaded by Ambarish Srivastava
Thanks to my student Harsh Pruthi (2014 batch) for Making Nice Notes
IIT JEE PHYSICS Class Notes by Ambarish Srivastava (Part 1)Ambarish Srivastava
These are the IIT JEE Physics Notes that I dictated to my students of Class XI in the Year 2013... Thanks to my Student Sanchit Minocha for Writing the notes nicely, I am sharing the photocopy of his notes.... This is part 1 up to Conservation of Momentum
This document summarizes and compares different methods for optimizing irradiation directions in intensity-modulated radiation therapy (IMRT) planning. It formulates the problem as a mixed integer program and evaluates several solution methods including set covering, linear programming relaxation, local search, and a full mixed integer programming approach. Computational results show that all methods can generate good treatment plans within 10 minutes and that optimizing angles is important when few beams are used.
1. Isodose curves represent the dose distribution from radiation beams and are lines connecting points of equal percentage depth dose. They are used to depict the volumetric and planar variations in absorbed dose.
2. The parameters that affect the shape of isodose curves include beam quality, source size, SSD, SDD, field size, and beam modifiers like wedges and flattening filters. Lower beam energy results in greater lateral scatter and more bulging curves.
3. Multiple radiation fields can be combined using appropriate beam weights, sizes, angles and modifiers to deliver a more uniform dose to the tumor while sparing surrounding tissues. Parameters like setup accuracy and plan practicality are also considered.
This document provides information about the components of a CT scan system. It describes the console room, examination room, and control room. The console room contains graphic monitors, keyboards, mice, and computers. The examination room houses the patient table and gantry, which contains the x-ray tube, generators, detector array, and data acquisition system. The control room includes AC plants and UPS to provide backup power. The document then discusses the components in more detail, including monitors, computers, the patient table, gantry, x-ray tube, collimators, detectors, generators, slip rings, and data acquisition system.
The document discusses infrared (IR) absorption spectroscopy. It begins by defining IR spectroscopy and explaining that it analyzes infrared light interacting with molecules based on absorption spectroscopy. It then discusses the different IR regions and how molecular vibrations occur when IR radiation hits a molecule and the bonds vibrate. The document covers fundamental vibrations like stretching and bending, as well as factors that affect vibrational frequencies. It also discusses instrumentation used in IR spectroscopy like sources, sample cells, detectors, and various types of spectrometers. Finally, it discusses applications of IR spectroscopy like qualitative analysis and kinetics studies.
This document summarizes key concepts in electron beam dosimetry and monitor unit calculations. It discusses electron beam interactions, depth dose distributions, characteristics of clinical beams, and factors that affect dose such as field size, distance, and inhomogeneities. It also describes how monitor units are calculated using output factors, distance corrections, and prescription isodose levels to determine the monitor units needed to deliver a prescribed dose to the treatment volume. Sample problems demonstrate how these concepts are applied in practice.
This document discusses key concepts in radiotherapy dosage, including:
1. Surface dose and kilovoltage radiation were limiting factors, while megavoltage radiation allows deeper penetration with less scatter.
2. Primary radiation output depends on tube current, voltage, target material and distance from source, while scattered radiation depends on beam size, shape, and material properties.
3. With megavoltage beams, electrons travel farther, depositing most energy at the end of their track and creating a "build up" where dose increases with depth before falling off due to inverse square law.
The document contains a foundation course on matter in our surroundings from CBSE. It includes 11 multiple choice questions about the properties of solids, liquids, and gases. It then has an objective test section with fill-in-the-blank, true/false, and multiple choice questions related to states of matter, phase changes, density, temperature scales, and other concepts. The questions assess understanding of key ideas like the differences between solids, liquids, and gases, properties like compressibility and thermal conduction, and processes like evaporation, diffusion, and sublimation.
multiple filed arrangement in Radiotherapy, Medical College KolkataKazi Manir
The document discusses various radiation therapy techniques for dose distribution in matter using multiple fields and wedge fields. It covers:
1) Using multiple fields allows more uniform dose distribution in the tumor compared to a single field, while limiting dose to normal tissues.
2) Parallel opposed fields provide simplicity but can excessively dose normal tissues above and below the tumor. Larger field sizes are needed for adequate coverage.
3) Patient thickness, beam energy, and field size must be considered to minimize lateral tissue effects and ensure uniform dose distribution.
4) Multiple techniques like wedges, isocentric beams, and field matching seek to further optimize dose distribution while sparing critical structures. Proper planning and verification is important.
Electron beam therapy uses electrically charged particles called electrons that are generated by a linear accelerator to treat superficial cancers. It deposits dose uniformly from the surface to a specific depth before rapidly falling off, sparing deeper tissues. Electron energies up to 20 MeV can treat disease within 6 cm of the surface. Accessories like applicators, cutouts, bolus and internal shields are used to shape the beam for treatment fields and protect healthy tissues. Precise dose specification and reporting is important for electron therapy due to the rapid dose fall-off and higher skin doses compared to prescription depth.
IIT JEE PHYSICS Class Notes by Ambarish Srivastava (Part 3)Ambarish Srivastava
These are the IIT JEE Physics Notes that I dictated to my students of Class XI in the Year 2013... Thanks to my Student Sanchit Minocha for Writing the notes nicely, whose photocopy I am sharing.... This is part 3 Covers Waves and Sound (Continued from part 2)
IIT JEE PHYSICS Class Notes by Ambarish Srivastava (Part 2)Ambarish Srivastava
These are the IIT JEE Physics Notes that I dictated to my students of Class XI in the Year 2013... Thanks to my Student Sanchit Minocha for Writing the notes nicely, whose photocopy I am sharing.... This is part 2 up to From Collisions to Waves Including Thermodynamics ... Waves Continues in part 3
The document discusses key concepts in radiobiology relevant for radiotherapy. It defines important treatment volumes including the gross tumour volume (GTV), clinical target volume (CTV), planning target volume (PTV), treated volume (TV), irradiated volume (IV), and organs at risk (OARs). It also describes biological factors that influence radiation effects on tissues, known as the "5 Rs": repair, repopulation, reoxygenation, redistribution, and radiosensitivity. Fractionated radiotherapy takes advantage of these factors to maximize tumor cell kill while minimizing damage to normal tissues.
Toppersnotes-- Sample for physics, chemistry and mathematicsToppersNotes
Toppersnotes is an education initiative by students of IIT bombay who want to help the present day IIT-JEE aspirants in an innovative way.We provide toppers handwritten notes & their strategy to jee aspirants. www.toppersnotes.in
This document provides information on dosimetric calculations for radiation therapy. It discusses key concepts like percent depth dose (PDD) and tissue maximum ratio (TMR) which are used to calculate dose for non-isocentric and isocentric setups, respectively. Factors like collimator scatter, phantom scatter, and beam modifiers are also covered. The document outlines the basic principles and provides examples of SSD and SAD calculations.
Electron beam therapy uses megavoltage electron beams to treat superficial tumors within 6 cm of the skin surface, sparing deeper tissues. The dose distribution of electron beams provides a uniform dose in the target region followed by a rapid dose fall-off. Treatment planning for electron beams requires consideration of electron energy, air gaps, tissue inhomogeneities, and adjacent fields to determine the optimal dose distribution. Electron beams can effectively treat many superficial cancers of the skin, limbs, and surgical beds.
The document discusses the components and operation of a linear accelerator used for radiation therapy. It describes the key parts of a linear accelerator including the electron gun, accelerator structure, treatment head and how they work together to generate photon or electron beams for radiation treatment. The linear accelerator uses microwave technology to accelerate electrons which are then converted into x-ray or electron beams that can be aimed at a tumor from multiple angles using the rotating gantry.
1. There are fundamental and process limitations to energy efficiency due to losses from imperfect conversions and practical constraints. Fundamental limitations arise from physical laws, while process limitations are due to real-world application issues.
2. Calculating energy efficiency involves determining the useful energy output compared to the total energy input. For any process or system, the energy efficiency can never be 100% due to inevitable losses.
3. Different forms of energy can be converted to other forms, but with losses due to the second law of thermodynamics. Not all energy can be converted to other desired forms.
IIT JEE PHYSICS CLASS NOTES UPLOADED BY Er. AMBARISH SRIVASTAVA (AIR 538)Ambarish Srivastava
IIT JEE PHYSICS NOTES PART 6
Semiconductor Devices, Principles of Communication,
Diffraction, Polarization.
Uploaded by Ambarish Srivastava
Thanks to my student Harsh Pruthi (2014 batch) for Making Nice Notes
IIT JEE PHYSICS Class Notes by Ambarish Srivastava (Part 1)Ambarish Srivastava
These are the IIT JEE Physics Notes that I dictated to my students of Class XI in the Year 2013... Thanks to my Student Sanchit Minocha for Writing the notes nicely, I am sharing the photocopy of his notes.... This is part 1 up to Conservation of Momentum
This document summarizes and compares different methods for optimizing irradiation directions in intensity-modulated radiation therapy (IMRT) planning. It formulates the problem as a mixed integer program and evaluates several solution methods including set covering, linear programming relaxation, local search, and a full mixed integer programming approach. Computational results show that all methods can generate good treatment plans within 10 minutes and that optimizing angles is important when few beams are used.
1. Isodose curves represent the dose distribution from radiation beams and are lines connecting points of equal percentage depth dose. They are used to depict the volumetric and planar variations in absorbed dose.
2. The parameters that affect the shape of isodose curves include beam quality, source size, SSD, SDD, field size, and beam modifiers like wedges and flattening filters. Lower beam energy results in greater lateral scatter and more bulging curves.
3. Multiple radiation fields can be combined using appropriate beam weights, sizes, angles and modifiers to deliver a more uniform dose to the tumor while sparing surrounding tissues. Parameters like setup accuracy and plan practicality are also considered.
This document provides information about the components of a CT scan system. It describes the console room, examination room, and control room. The console room contains graphic monitors, keyboards, mice, and computers. The examination room houses the patient table and gantry, which contains the x-ray tube, generators, detector array, and data acquisition system. The control room includes AC plants and UPS to provide backup power. The document then discusses the components in more detail, including monitors, computers, the patient table, gantry, x-ray tube, collimators, detectors, generators, slip rings, and data acquisition system.
The document discusses infrared (IR) absorption spectroscopy. It begins by defining IR spectroscopy and explaining that it analyzes infrared light interacting with molecules based on absorption spectroscopy. It then discusses the different IR regions and how molecular vibrations occur when IR radiation hits a molecule and the bonds vibrate. The document covers fundamental vibrations like stretching and bending, as well as factors that affect vibrational frequencies. It also discusses instrumentation used in IR spectroscopy like sources, sample cells, detectors, and various types of spectrometers. Finally, it discusses applications of IR spectroscopy like qualitative analysis and kinetics studies.
Infrared absorption spectroscopy analyzes infrared light interacting with molecules. When IR radiation hits a molecule, the molecule's bonds absorb the energy and vibrate. There are two main types of vibrations - stretching and bending. Factors like atomic mass and bond strength determine vibrational frequency. Hydrogen bonding occurs between proton donor and acceptor groups and affects frequencies. IR instruments contain sources, sample cells, monochromators, detectors, and recorders. Applications include identifying substances from their unique spectra in the fingerprint region.
guys, i have re-uploaded this presentation after i noticed a slight mistake in slide no.68. well now i've rectified it & the correct one is now available. sorry for the inconvenience viewers!
This document discusses different types of lasers categorized by their gain medium. It provides details on atomic gas lasers like helium-neon lasers and ion gas lasers like argon ion lasers. Helium-neon lasers use a mixture of helium and neon gases as the gain medium, with the helium assisting in the population inversion process to allow lasing from neon. Argon ion lasers use argon gas that is ionized, with the argon ions providing the lasing transition. Excimer lasers use excimer or exciplex molecules as the gain medium, which only exist in excited states and allow efficient population inversion.
Cathode rays were discovered when gases inside discharge tubes were pumped to low pressures and high voltages were applied. At low pressures, the original glow inside the tube disappeared and rays were produced that caused fluorescence on the glass wall opposite the cathode. These cathode rays were shown to be streams of negatively charged particles called electrons through experiments by J.J. Thomson and others showing they were deflected by electric and magnetic fields and had properties of particles like momentum and mass. Thomson concluded cathode rays consisted of electrons, small negatively charged particles, and established them as fundamental components of atoms.
The document discusses infrared (IR) absorption spectroscopy. It begins by defining IR spectroscopy and explaining that it deals with the infrared region of the electromagnetic spectrum. It then discusses the different IR regions and how IR radiation causes molecular vibrations when it hits a molecule. The document goes on to describe different types of molecular vibrations including stretching, bending, scissoring, and twisting vibrations. It also discusses factors that affect vibrational frequencies such as atomic mass and bond strength. Finally, it briefly discusses instrumentation used in IR spectroscopy such as sources, sample cells, detectors, and the applications of IR spectroscopy.
This document describes the key components and functioning of instrumentation used in x-ray diffraction. The main components are a radiation source like an x-ray tube, a collimator to narrow the beam, a monochromator to remove unwanted radiation, detectors like photographic film or counters, and associated electronics. X-ray tubes generate x-rays via the impact of electrons on a metal target. Collimators and monochromators shape and refine the x-ray beam before it interacts with the sample. Detectors then measure the diffraction pattern, with options including film, Geiger-Muller tubes, proportional counters, scintillators, and semiconductors.
Atomic absorption spectroscopy is a technique used to detect specific elements within samples. It works by vaporizing and dissociating the sample into free atoms, then exciting the atoms of the target element using a lamp that emits specific wavelengths of light. The amount of light absorbed corresponds to the concentration of the element within the sample. The document outlines the principle, instrumentation including radiation sources, atomizers, monochromators and detectors, interferences, and applications of atomic absorption spectroscopy for quantitative elemental analysis.
1. X-rays are produced when fast moving electrons are decelerated upon striking a metal target in an x-ray tube.
2. Modern x-ray tubes use a tungsten target and operate under vacuum to allow for control of the electron beam and prevent degradation of the tube.
3. X-ray output is determined by tube voltage (kVp), current (mAs), and filtration - with higher kVp and mAs producing higher quality and quantity respectively.
Infrared spectroscopy depends on the vibrational and rotational energy levels of molecules. The frequency of infrared light absorbed is determined by the masses of bonded atoms and the bond strength. IR absorption peaks provide information about molecular structure through functional groups. Selection rules limit transitions between energy levels to certain vibrational changes. Anharmonicity and vibrational coupling affect peak positions and intensities. IR spectroscopy is used to study molecular vibrations and identify chemical structures and compounds.
X-ray diffraction was discovered in 1895 by Wilhelm Röntgen. It involves using x-rays and analyzing the diffraction patterns formed after x-rays interact with the ordered structure of crystals. Bragg's law describes the conditions under which constructive interference of x-rays occurs leading to diffraction. X-ray diffraction is used to determine the atomic and molecular structure of crystals. It has applications in fields like materials science, chemistry, and structural biology.
Production of x rays
Components of X-ray
Cathode
kVp , mA , mAs .
Line focus principle
Heel effect
anode
Stationary anode x ray tube
Rotating anode x-ray tube
Grid controlled x-ray tube
Saturation voltage
Metal ceramic x – ray tube
Processes of x- ray generation
intensity of the x-ray beams
Effect of kVp on x- ray beam
Effect of tube current on x- ray beam
learn with Me...........MK
if you notice any mistake comment please ......
- LEDs emit light when forward biased due to electron-hole recombination in materials like gallium arsenide. The color emitted depends on the material used, with variations in elements like gallium, phosphorus, and arsenic producing different colors.
- Tunnel diodes exhibit negative resistance between peak and valley voltages due to quantum mechanical tunneling effects. This property can be used for oscillation in tunnel diode oscillators.
- Varactor diodes act as variable capacitors, with capacitance varying inversely with applied reverse voltage, allowing them to be used for voltage-controlled oscillation.
1) Certain metals exhibit zero electrical resistance below a critical temperature known as the superconducting transition temperature. This phenomenon is called superconductivity.
2) Superconductors can be classified as either Type I or Type II, depending on their behavior in magnetic fields. Type I superconductors exhibit the Meissner effect and have a sharp transition to the normal state, while Type II superconductors allow some magnetic field penetration.
3) The BCS theory explains superconductivity as arising from electrons forming Cooper pairs via an attractive interaction mediated by phonons in the crystal lattice. The Cooper pairs behave as a superfluid with zero resistance.
Carbon nanotubes have unique electrical, mechanical, and thermal properties that make them promising for a variety of applications. They have very high tensile strength and thermal conductivity. Their properties depend on their geometry, with single-walled nanotubes being metallic or semiconducting depending on their structure. Common synthesis methods include arc discharge, laser ablation, and chemical vapor deposition. Raman spectroscopy is useful for characterizing carbon nanotubes and can determine their diameter and identify defects. Potential applications of carbon nanotubes include use in electronics, gas sensors, field emission displays, and energy storage.
When the energy of the accelerated electrons is higher than a certain threshold value (which depends on the metal anode), a second type of spectrum is obtained superimposed on top of the white radiation. It is called the characteristic radiation and is composed of discrete peaks.
The energy (and wavelength) of the peaks depends solely on the metal used for the target and is due to the ejection of an electron from one of the inner electron shells of the metal atom.
This results in an electron from a higher atomic level dropping to the vacant level with the emission of an X-ray photon characterised by the difference in energy between the two levels.
The document describes the principles and components of flame photometry. Flame photometry measures the intensity of light emitted from metal atoms excited by the heat of a flame. When a solution is sprayed into the flame, the solvent evaporates and the metal atoms are excited and emit light of characteristic wavelengths. A mirror collects the light, which is separated into its wavelengths by a prism or grating. A photodetector measures the light intensities, which correspond to concentrations of metals in the original solution. Common applications include analyzing body fluids, soils, and water.
1) Lasers were first theorized in 1917 and the first working laser was developed in 1960.
2) Lasers work through a process of absorption, stimulated emission, and light amplification that produces a coherent, monochromatic beam of light.
3) Common types of lasers include solid state lasers like ruby lasers, gas lasers like helium-neon lasers, and semiconductor lasers. Lasers have a wide variety of applications in fields like engineering, medicine, science, and the military.
Gender and Mental Health - Counselling and Family Therapy Applications and In...PsychoTech 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!
The chapter Lifelines of National Economy in Class 10 Geography focuses on the various modes of transportation and communication that play a vital role in the economic development of a country. These lifelines are crucial for the movement of goods, services, and people, thereby connecting different regions and promoting economic activities.
ISO/IEC 27001, ISO/IEC 42001, and GDPR: Best Practices for Implementation and...PECB
Denis is a dynamic and results-driven Chief Information Officer (CIO) with a distinguished career spanning information systems analysis and technical project management. With a proven track record of spearheading the design and delivery of cutting-edge Information Management solutions, he has consistently elevated business operations, streamlined reporting functions, and maximized process efficiency.
Certified as an ISO/IEC 27001: Information Security Management Systems (ISMS) Lead Implementer, Data Protection Officer, and Cyber Risks Analyst, Denis brings a heightened focus on data security, privacy, and cyber resilience to every endeavor.
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What sets Denis apart is his comprehensive understanding of Business and Systems Analysis technologies, honed through involvement in all phases of the Software Development Lifecycle (SDLC). From meticulous requirements gathering to precise analysis, innovative design, rigorous development, thorough testing, and successful implementation, he has consistently delivered exceptional results.
Throughout his career, he has taken on multifaceted roles, from leading technical project management teams to owning solutions that drive operational excellence. His conscientious and proactive approach is unwavering, whether he is working independently or collaboratively within a team. His ability to connect with colleagues on a personal level underscores his commitment to fostering a harmonious and productive workplace environment.
Date: May 29, 2024
Tags: Information Security, ISO/IEC 27001, ISO/IEC 42001, Artificial Intelligence, GDPR
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This presentation was provided by Rebecca Benner, Ph.D., of the American Society of Anesthesiologists, for the second session of NISO's 2024 Training Series "DEIA in the Scholarly Landscape." Session Two: 'Expanding Pathways to Publishing Careers,' was held June 13, 2024.
Philippine Edukasyong Pantahanan at Pangkabuhayan (EPP) CurriculumMJDuyan
(𝐓𝐋𝐄 𝟏𝟎𝟎) (𝐋𝐞𝐬𝐬𝐨𝐧 𝟏)-𝐏𝐫𝐞𝐥𝐢𝐦𝐬
𝐃𝐢𝐬𝐜𝐮𝐬𝐬 𝐭𝐡𝐞 𝐄𝐏𝐏 𝐂𝐮𝐫𝐫𝐢𝐜𝐮𝐥𝐮𝐦 𝐢𝐧 𝐭𝐡𝐞 𝐏𝐡𝐢𝐥𝐢𝐩𝐩𝐢𝐧𝐞𝐬:
- Understand the goals and objectives of the Edukasyong Pantahanan at Pangkabuhayan (EPP) curriculum, recognizing its importance in fostering practical life skills and values among students. Students will also be able to identify the key components and subjects covered, such as agriculture, home economics, industrial arts, and information and communication technology.
𝐄𝐱𝐩𝐥𝐚𝐢𝐧 𝐭𝐡𝐞 𝐍𝐚𝐭𝐮𝐫𝐞 𝐚𝐧𝐝 𝐒𝐜𝐨𝐩𝐞 𝐨𝐟 𝐚𝐧 𝐄𝐧𝐭𝐫𝐞𝐩𝐫𝐞𝐧𝐞𝐮𝐫:
-Define entrepreneurship, distinguishing it from general business activities by emphasizing its focus on innovation, risk-taking, and value creation. Students will describe the characteristics and traits of successful entrepreneurs, including their roles and responsibilities, and discuss the broader economic and social impacts of entrepreneurial activities on both local and global scales.
Temple of Asclepius in Thrace. Excavation resultsKrassimira Luka
The temple and the sanctuary around were dedicated to Asklepios Zmidrenus. This name has been known since 1875 when an inscription dedicated to him was discovered in Rome. The inscription is dated in 227 AD and was left by soldiers originating from the city of Philippopolis (modern Plovdiv).
Beyond Degrees - Empowering the Workforce in the Context of Skills-First.pptxEduSkills OECD
Iván Bornacelly, Policy Analyst at the OECD Centre for Skills, OECD, presents at the webinar 'Tackling job market gaps with a skills-first approach' on 12 June 2024
Level 3 NCEA - NZ: A Nation In the Making 1872 - 1900 SML.pptHenry Hollis
The History of NZ 1870-1900.
Making of a Nation.
From the NZ Wars to Liberals,
Richard Seddon, George Grey,
Social Laboratory, New Zealand,
Confiscations, Kotahitanga, Kingitanga, Parliament, Suffrage, Repudiation, Economic Change, Agriculture, Gold Mining, Timber, Flax, Sheep, Dairying,
A Visual Guide to 1 Samuel | A Tale of Two HeartsSteve Thomason
These slides walk through the story of 1 Samuel. Samuel is the last judge of Israel. The people reject God and want a king. Saul is anointed as the first king, but he is not a good king. David, the shepherd boy is anointed and Saul is envious of him. David shows honor while Saul continues to self destruct.
electron, photon and x-ray-(theory) BY ANURAG TYAGI CLASSES (ATC)
1. Electron, Photon, Photoelectric Effect and X-rays 1
Lig
ht
µ
+ –
Electric Discharge Through Gases.
At normal atmospheric pressure, the gases are poor conductor of electricity. If we establish a potential difference (of the order of 30 kV) between two
electrodes placed in air at a distance of few cm from each other, electric conduction starts in the form of sparks.
The passage of electric current through air is called electric discharge through the air.
The discharge of electricity through gases can be systematically studied with the help of discharge tube shown below
High
potential
– difference +
Length of discharge tube ≈ 30 to 40 cm
Gas
The discharge tube is filled with the gas through which discharge is to be studied. The pressure of the enclosed gas of the tube ≈ 4cm the help of a vacuum
Diameter can be reduced with
pump and it's value is read by manometer.
Sequence of phenomenon
Manometer
As the pressure inside the discharge tube is gradually reduced, the following is the sequence of phenomenon that are observed.
Vacuum pump Negative glow Positive column
– Streamers + – Positive column + – +
10 mm of Hg Below 4 mm of Hg F.D.S. 1.65 mm of Hg
Negative glow Positive column Cathode glow Negative glow
– + – +
Cathode glow C.D.S. F.D.S. C.D.S. F.D.S. Striations Greenish light
(1) At normal pressure no of Hg
0.8 mm discharge takes place.
0.05 mm of Hg 0.01 mm of Hg
(2) At the pressure 10 mm of Hg, a zig-zag thin red spark runs from one electrode to other and cracking sound is heard.
(3) At the pressure 4 mm. of Hg, an illumination is observed at the electrodes and the rest of the tube appears dark. This type of discharge is called dark
discharge.
(4) When the pressure falls below 4 mm of Hg then the whole tube is filled with bright light called positive column and colour of light depends upon the nature
of gas in the tube as shown in the following table.
Gas Colour
Air Purple red
H2 Blue
N2 Red
Cl2 Green
CO2 Bluish white
Na Yellow
Neon Dark red
(5) At a pressure of 1.65 mm of Hg :
(i) Sky colour light is produced at the cathode it is called as negative glow.
(ii) Positive column shrinks towards the anode and the dark space between positive column and negative glow is called Faradays dark space (FDS)
(6) At a pressure of 0.8 mm Hg : At this pressure, negative glow is detached from the cathode and moves towards the anode. The dark space created between
cathode and negative glow is called as Crook's dark space length of positive column further reduced. A glow appear at cathode called cathode glow.
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2. 2 Electron, Photon, Photoelectric Effect and X-rays
(7) At a pressure of 0.05 mm of Hg : The positive column splits into dark and bright disc of light called striations.
(8) At the pressure of 0.01 or 10–2 mm of Hg some invisible particle move from cathode which on striking with the glass tube of the opposite side of cathode
cause the tube to glow. These invisible rays emerging from cathode are called cathode rays.
(9) Finally when pressure drops to nearly 10–4 mm of Hg, there is no discharge in tube.
Cathode Rays.
Cathode rays, discovered by sir Willium Crooke are the stream of electrons. They can be produced by using a discharge tube containing gas at a low pressure
of the order of 10–2 mm of Hg. At this pressure the gas molecules ionise and the emitted electrons travel towards positive potential of anode. The positive ions hit the
cathode to cause emission of electrons from cathode. These electrons also move towards anode. Thus the cathode rays in the discharge tube are the electrons produced
due to ionisation of gas and that emitted by cathode due to collision of positive ions.
(1) Properties of cathode rays
(i) Cathode rays travel in straight lines (cast shadows of objects placed in their path)
(ii) Cathode rays emit normally from the cathode surface. Their direction is independent of the position of the anode.
(iii) Cathode rays exert mechanical force on the objects they strike.
(iv) Cathode rays produce heat when they strikes a material surface.
(v) Cathode rays produce fluorescence.
(vi) When cathode rays strike a solid object, specially a metal of high atomic weight and high melting point X-rays are emitted from the objects.
(vii) Cathode rays are deflected by an electric field and also by a magnetic field.
(viii) Cathode rays ionise the gases through which they are passed.
(ix) Cathode rays can penetrate through thin foils of metal.
1 1
(x) Cathode rays are found to have velocity ranging th to th of velocity of light.
30 10
(2) J.J. Thomson's method to determine specific charge of electron
It's working is based on the fact that if a beam of electron is subjected to the crossed electric field
E and magnetic field
B , it experiences a force due to
each field. In case the forces on the electrons in the electron beam due to these fields are equal and opposite, the beam remains undeflected.
S
P′
C A X
+
P
Y –
L.T. Magnetic P′′
(H.T.) field S′
C = Cathode, A = Anode, F = Filament, LT = Battery to heat the filament, V = potential difference to accelerate the electrons, SS' = ZnS coated screen, XY =
metallic plates (Electric field produced between them)
(i) When no field is applied, the electron beam produces illuminations at point P.
(ii) In the presence of any field (electric and magnetic) electron beam deflected up or down (illumination at P' or P '' )
(iii) If both the fields are applied simultaneously and adjusted such that electron beam passes undeflected and produces illumination at point P.
E
In this case; Electric force = Magnetic force ⇒ eE = evB ⇒ v= ; v = velocity of electron
B
As electron beam accelerated from cathode to anode its potential energy at the cathode appears as gain in the K.E. at the anode. If suppose V is the potential
difference between cathode and anode then, potential energy = eV
1 1 e v2 e E2
And gain in kinetic energy at anode will be K.E. = mv 2 i.e. eV = mv 2 ⇒ = ⇒ =
2 2 m 2V m 2VB 2
e
Thomson found, = 1 .77 × 1 0 1 1 C /kg .
m
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3. Electron, Photon, Photoelectric Effect and X-rays 3
1 eE l2
Note : The deflection of an electron in a purely electric field is given by y= . ; where l length of each plate, y = deflection of
2 m v2
electron in the field region, v = speed of the electron.
Positive Rays. +
y
Positive rays are sometimes known as the canal rays. These were discovered by Goldstein. If the cathode of a discharge tube has holes in it and the pressure of
→
the gas is around 10–3 mm of Hg then faint luminous glow comes out from each hole onE ethe backside of the cathode.
–
It is said positive rays which are coming out from the holes. –
l
←⊕ ⊕→ ←⊕ ⊕→
(1) Origin of positive rays ←⊕ ←⊕ ←⊕ ⊕→
When potential difference is applied across the electrodes, electrons are emitted from the cathode. As they ←⊕ ⊕→ ←⊕
move towards anode, they gain energy. These energetic electrons when collide with the atoms of the gas in the
discharge tube, they ionize the atoms. The positive ions so formed at various places between cathode and anode, Positive rays
travel towards the cathode. Since during their motion, the positive ions when reach the cathode, some pass through
the holes in the cathode. These streams are the positive rays.
(2) Properties of positive rays
(i) These are positive ions having same mass if the experimental gas does not have isotopes. However if the gas has isotopes then positive rays are group of
positive ions having different masses.
(ii) They travels in straight lines and cast shadows of objects placed in their path. But the speed of the positive rays is much smaller than that of cathode
rays.
(iii) They are deflected by electric and magnetic fields but the deflections are small as compared to that for cathode rays.
(iv) They show a spectrum of velocities. Different positive ions move with different velocities. Being heavy, their velocity is much less than that of cathode
rays.
(v) q /m ratio of these rays depends on the nature of the gas in the tube (while in case of the cathode rays q/m is constant and doesn't depend on the gas in
the tube). q/m for hydrogen is maximum.
(vi) They carry energy and momentum. The kinetic energy of positive rays is more than that of cathode rays.
(vii) The value of charge on positive rays is an integral multiple of electronic charge.
(viii) They cause ionisation (which is much more than that produced by cathode rays).
Mass Spectrograph.
It is a device used to determine the mass or (q/m) of positive ions.
(1) Thomson mass spectrograph
It is used to measure atomic masses of various isotopes in gas. This is done by measuring q/m of singly ionised positive ions of the gas.
Y
S Screen or
Cathode – P – Photo plate S
Low y
pressure
gas +q v
The positive ions are produced in the bulb at the left hand side. These ions are accelerated towards cathode. Some of the positive ions pass through the fine hole
Z
in the cathode. This fine ray of positive ions is subjected to electric field E and magnetic field B and then allowed to strike a fluorescent screen ( z || B but E or
Q E
+
N
B ⊥v ).
Pump N
If the initial motion of the ions is in +x direction and electric and magnetic fields are applied along + y axis thenDforce due to electric field is in the
direction of y-axis and due to magnetic field it is along z-direction.
qE LD
The deflection due to electric field alone y= .........(i)
mv 2
qBLD
The deflection due to magnetic field alone z= .........(ii)
mv
From equation (i) and (ii)
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4. 4 Electron, Photon, Photoelectric Effect and X-rays
q
z 2 = k y , where k = B LD ; This is the equation of parabola. It means all the charged particles moving with different velocities but of same q/
2
m E
m value will strike the screen placed in yz plane on a parabolic track as shown in the above figure.
Note : All the positive ions of same. q/m moving with different velocity lie on the same parabola. Higher is the velocity lower is the value of y and z.
The ions of different specific charge will lie on different parabola.
Y q/m q/m q/m q/m
V
V2 V3 4 large small small large
V1>V2>V3>V4
V1 Light mass
Z Heavy mass
The number of parabola tells the number of isotopes present in the given ionic beam.
(2) Bainbridge mass spectrograph
In Bainbridge mass spectrograph, field particles of same velocity are selected by using a velocity selector and then they are subjected to a uniform magnetic
field perpendicular to the velocity of the particles. The particles corresponding to different isotopes follow different circular paths as shown in the figure.
(i) Velocity selector : The positive ions having a certain velocity v gets isolated from all other velocity particles. In this chamber the electric and magnetic
E
fields are so balanced that the particle moves undeflected. For this the necessary condition is v= .
B
(ii) Analysing chamber : In this chamber magnetic field B is applied perpendicular to the direction of motion of the particle. As a result the particles move
along a circular path of radius
mE q E r1 m Velocity spectrum • •
r= ⇒ = also = 1 • • •
qBB ' m BB ' r r2 m 2 m v • • • •
→•
• • B′
• • •
In this way the particles of different masses gets deflected on circles of different radii and reach +q • • • •
on different points on the photo plate. 2r1 •
2r2 m1 • • •
→ → •
•
E ⊥B m2 •
2v(m 2 − m 1 ) r •
•
•
Note : Separation between two traces = d = 2 r2 − 2 r1 ⇒ d = . • •
qB ' Photographic plate • •
Matter waves (de-Broglie Waves).
According to de-Broglie a moving material particle sometimes acts as a wave and sometimes as a particle.
or
A wave is associated with moving material particle which control the particle in every respect.
The wave associated with moving particle is called matter wave or de-Broglie wave and it propagates in the form of wave packets with group velocity.
(1) de-Broglie wavelength
According to de-Broglie theory, the wavelength of de-Broglie wave is given by
h h h 1 1 1
λ= = = ⇒λ∝ ∝ ∝
p mv 2 mE p v E
Where h = Plank's constant, m = Mass of the particle, v = Speed of the particle, E = Energy of the particle.
The smallest wavelength whose measurement is possible is that of γ -rays.
The wavelength of matter waves associated with the microscopic particles like electron, proton, neutron, α -particle etc. is of the order of 1 0 −1 0
m.
(i) de-Broglie wavelength associated with the charged particles.
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5. Electron, Photon, Photoelectric Effect and X-rays 5
1
The energy of a charged particle accelerated through potential difference V is E = mv 2 = qV
2
h h h
Hence de-Broglie wavelength λ= = =
p 2 mE 2 mqV
1 2 .27 0.286 0.202 × 1 0 −1 0 0.1 01
λ electron = Å, λ proton = Å, λ deutron = Å, λα − particle = Å
V V V V
(ii) de-Broglie wavelength associated with uncharged particles.
0.286 × 1 0 −1 0 0.286
For Neutron de-Broglie wavelength is given as λ Neutron = m= Å
E (in eV ) E (in eV )
Energy of thermal neutrons at ordinary temperature
h
E = kT ⇒ λ = ; where k = Boltzman's constant = 1 .38 × 1 0 −23 Joules/kelvin , T = Absolute temp.
2 mkT
6.62 × 1 0 −34 30.83
So λ Therm al N eutron = = Å
2 × 1 .07 × 1 0 −1 7
× 1 .38 × 1 0 − 23
T T
(2) Some graphs
λ
λ
λ Slope = h
1/b
Small m
Large m
p v
λ Small m λ Small m
Large m
Large m
λ
1 E
1/V
Note : A photon is not a material particle. It is a quanta of energy. Small m
Large m
E
When a particle exhibits wave nature, it is associated with a wave packet, rather then a wave.
(3) Characteristics of matter waves
(i) Matter wave represents the probability of finding a particle in space.
(ii) Matter waves are not electromagnetic in nature.
(iii) de-Brogile or matter wave is independent of the charge on the material particle. It means, matter wave of de-Broglie wave is associated with every
moving particle (whether charged or uncharged).
(iv) Practical observation of matter waves is possible only when the de-Broglie wavelength is of the order of the size of the particles is nature.
(v) Electron microscope works on the basis of de-Broglie waves.
(vi) The electric charge has no effect on the matter waves or their wavelength.
(vii) The phase velocity of the matter waves can be greater than the speed of the light.
(viii) Matter waves can propagate in vacuum, hence they are not mechanical waves.
(ix) The number of de-Broglie waves associated with nth orbital electron is n.
(x) Only those circular orbits around the nucleus are stable whose circumference is integral multiple of de-Broglie wavelength associated with
the orbital electron.
(4) Davision and Germer experiment
It is used to study the scattering of electron from a solid or to verify the wave nature of electron. A beam of electrons emitted by electron gun is made to fall
on nickel crystal cut along cubical axis at a particular angle. Ni crystal behaves like a three dimensional diffraction grating and it diffracts the electron beam
obtained from electron gun.
Electron
gun F
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electrons
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θ φθ
Diffracted beam of
electrons
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Nickel crystal
6. 6 Electron, Photon, Photoelectric Effect and X-rays
The diffracted beam of electrons is received by the detector which can be positioned at any angle by rotating it about the point of incidence. The energy of the
incident beam of electrons can also be varied by changing the applied voltage to the electron gun.
According to classical physics, the intensity of scattered beam of electrons at all scattering angle will be same but Davisson and Germer, found that the
intensity of scattered beam of electrons was not the same but different at different angles of scattering.
Incident beam
Incident beam
Incident beam
Incident beam
Intensity is maximum at 54 V potential difference and 50o diffraction angle.
If the de-Broglie waves exist for electrons then these should be diffracted as X-rays. Using the Bragg's formula 2 d sin θ = nλ , we can determine the
wavelength of these waves. 50o
44 V 48 V 64 V
(1 80 − φ )
Where d = distance between diffracting planes, θ = = 54 V
glancing angle for incident beam = Bragg's
2 θ=65° φ =50°
angle. D
The distance between diffraction planes in Ni-crystal for this experiment is d = 0.91Å and the Bragg's angle = 65o. This gives θ
d
−1 0 o
for n = 1, λ = 2 × 0.91 × 1 0 sin 65 = 1 .65 Å Atomic planes
1 2 .27 1 2 .27
Now the de-Broglie wavelength can also be determined by using the formula λ= = = 1 .67 Å
V 54
.
Thus the de-Broglie hypothesis is verified.
Heisenberg Uncertainty Principle.
According to Heisenberg's uncertainty principle, it is impossible to measure simultaneously both the position and the momentum of the particle.
h
Let ∆x and ∆p be the uncertainty in the simultaneous measurement of the position and momentum of the particle, then ∆x ∆p = ; where = and h
2π
= 6.63 × 10–34 J-s is the Planck's constant.
If ∆x = 0 then ∆p = ∞
and if ∆p = 0 then ∆x = ∞ i.e., if we are able to measure the exact position of the particle (say an electron) then the uncertainty in the measurement of the
linear momentum of the particle is infinite. Similarly, if we are able to measure the exact linear momentum of the particle i.e., ∆p = 0, then we can not measure the
exact position of the particle at that time.
Photon.
According to Eienstein's quantum theory light propagates in the bundles (packets or quanta) of energy, each bundle being called a photon and possessing
energy.
(1) Energy of photon
hc
Energy of each photon is given by E = hν = ; where c = Speed of light, h = Plank's constant = 6.6 × 10–34 J-sec, ν = Frequency in Hz, λ = Wavelength of light
λ
hc 1 2375 1 2400
Energy of photon in electron volt E (eV ) = = ≈
eλ λ ( Å) λ ( Å)
(2) Mass of photon
Actually rest mass of the photon is zero. But it's effective mass is given as
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7. Electron, Photon, Photoelectric Effect and X-rays 7
E hν h
E = mc 2 = hν ⇒ m= 2 = 2 = . This m ass is also known as kine tic m ass o f the photon
c c cλ
(3) Momentum of the photon
E hν h
Momentum p = m ×c = = =
c c λ
(4) Number of emitted photons
P P Pλ
The number of photons emitted per second from a source of monochromatic radiation of wavelength λ and power P is given as (n) = = = ;
E hν hc
where E = energy of each photon
(5) Intensity of light (I)
Energy crossing per unit area normally per second is called intensity or energy flux
E P E
i.e. I= = = P = rad iation power
At A t
P 1
At a distance r from a point source of power P intensity is given by I= ⇒ I∝
4πr 2 r2
Concepts
Discovery of positive rays helps in discovering of isotopes.
The de-Broglie wavelength of electrons in first Bohr orbit of an atom is equal to circumference of orbit.
A particle having zero rest mass and non zero energy and momentum must travels with a speed equal to speed of light.
h h
de-Broglie wave length associates with gas molecules is given as λ = mv = (Energy of gas molecules at temperature T is
rms 3 mkT
3
E = kT )
2
Examples
Example: 1 The ratio of specific charge of an α -particle to that of a proton is [BCECE 2003]
(a) 2 : 1 (b) 1 : 1 (c) 1:2 (d) 1 : 3
q (q /m )α q mp 1
Solution : (c) Specific charge = ; Ratio = = α × = .
m (q /m ) p q p mα 2
Example: 2 The speed of an electron having a wavelength of 1 0 −1 0 m is [AIIMS 2002]
(a) 7. 25 × 1 0 6 m/s (b) 6.26 × 1 0 6 m /s (c) 5 .25 × 1 0 6 m /s (d) 4.24 × 1 0 6 m /s
h h 6.6 × 1 0 −34
Solution : (a) By using λ electron = ⇒ v= = = 7. 25 × 1 0 6 m / .
s
m ev m e λe 9.1 × 1 0 − 31 × 1 0 −1 0
Example: 3 In Thomson experiment of finding e/m for electrons, beam of electron is replaced by that of muons (particle with same charge as of electrons
but mass 208 times that of electrons). No deflection condition in this case satisfied if
[Orissa (Engg.) 2002]
(a) B is increased 208 times (b) E is increased 208 times
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8. 8 Electron, Photon, Photoelectric Effect and X-rays
(c) B is increased 14.4 times (d) None of these
e E 2
Solution : (c) In the condition of no deflection = . If m is increased to 208 times then B should be increased by 208 = 1 4. 4 tim es.
m 2VB 2
Example: 4 In a Thomson set-up for the determination of e/m, electrons accelerated by 2.5 kV enter the region of crossed electric and magnetic fields of
strengths 3. 6 × 1 0 4 Vm −1 and 1 . 2 × 1 0 −3 T respectively and go through undeflected. The measured value of e/m of the electron is equal
to [AMU 2002]
1 .0 × 1 01 1 C-kg 1 .76 × 1 01 1 C-kg-1 1 .80 × 1 01 1 C-kg 1 .85 × 1 01 1 C-kg
(a) -1 (b) (c) -1 (d) -1
e E2 e (3.6 × 1 0 4 )2
Solution : (c) By using = ⇒ = = 1 .8 × 1 0 1 1 C /kg .
m 2VB 2 m 2 × 2 .5 × 1 0 3 × (1 .2 × 1 0 − 3 )2
Example: 5 In Bainbridge mass spectrograph a potential difference of 1000 V is applied between two plates distant 1 cm apart and magnetic field in B = 1T.
The velocity of undeflected positive ions in m/s from the velocity selector is
[RPMT 1998]
(a) 1 07 m /s (b) 1 04m /s (c) 1 05 m /s (d) 1 02 m /s
E V 1 000 1 05
Solution : (c) By using v= ; where E = = = 1 0 5 V /m ⇒ v= = 1 05 m / .
s
B d 1 ×1 0 −2
1
Example: 6 An electron and a photon have same wavelength. It p is the momentum of electron and E the energy of photon. The magnitude of p/ E in
S.I. unit is
(a) 3.0 × 108 (b) 3.33 × 10–9 (c) 9.1 × 10–31 (d) 6.64 × 10–34
h h hc
Solution : (b) λ= (for electron) or p = and E = (for photon)
p λ λ
p 1 1
∴ = = = 3.33 × 1 0 −9 s /m
E c 3 × 1 0 8 m /s
Example: 7 The energy of a photon is equal to the kinetic energy of a proton. The energy of the photon is E. Let λ1 be the de-Broglie wavelength of the
proton and λ2 be the wavelength of the photon. The ratio λ1/λ2 is proportional to
[UPSEAT 2003; IIT-JEE (Screening) 2004]
−1
(a) E 0 (b) E 1 /2 (c) E (d) E −2
hc h
Solution : (b) For photon λ2 = ……. (i) and For proton λ1 = …….(ii)
E 2 mE
λ1 E 1 /2 λ1
Therefore = ⇒ ∝ E 1 /2 .
λ2 2m c λ2
−31
Example: 8 The de-Broglie wavelength of an electron having 80eV of energy is nearly ( 1 eV = 1 .6 × 1 0 −1 9 J , Mass of electron 9 × 1 0 kg and
Plank's constant 6. 6 × 1 0 −34 J-sec) [EAMCET (Engg.) 2001]
(a) 140 Å (b) 0.14 Å (c) 14 Å (d) 1.4 Å
h 1 2 .27
Solution : (d) By using λ= = . If energy is 80 eV then accelerating potential difference will be 80 V. So
2 mE V
1 2 .27
λ= = 1 .37 ≈ 1 .4 Å.
80
Example: 9 The kinetic energy of electron and proton is 1 0 −32 J . Then the relation between their de-Broglie wavelengths is
[CPMT 1999]
(a) λp < λe (b) λp > λe (c) λp = λe (d) λp = 2 λe
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9. Electron, Photon, Photoelectric Effect and X-rays 9
h 1
Solution : (a) By using λ= E = 10–32 J = Constant for both particles. Hence λ∝
2mE m
Since m p > me so λ p < λe .
Example: 10 The energy of a proton and an α particle is the same. Then the ratio of the de-Broglie wavelengths of the proton and the α is
[RPET 1991]
(a) 1 : 2 (b) 2 : 1 (c) 1 : 4 (d) 4 : 1
h 1 λ proton mα 2
Solution : (b) By using λ= ⇒ λ∝ (E – same) ⇒ = = .
2mE m λα − particle mp 1
Example: 11 The de-Broglie wavelength of a particle accelerated with 150 volt potential is 1 0 −1 0 m. If it is accelerated by 600 volts p.d., its wavelength
will be [RPET 1988]
(a) 0.25 Å (b) 0.5 Å (c) 1.5 Å (d) 2Å
1 λ1 V2 1 0 −1 0 600
Solution : (b) By using λ∝ ⇒ = ⇒ = =2 ⇒ λ2 = 0.5 Å.
V λ2 V1 λ2 1 50
Example: 12 The de-Broglie wavelength of an electron in an orbit of circumference 2πr is [MP PET 1987]
(a) 2πr (b) πr (c) 1 /2πr (d) 1 /4πr
h h
Solution : (a) According to Bohr's theory mv r = n ⇒ 2π r = n = nλ
2π mv
For n = 1 λ = 2πr
Example: 13 The number of photons of wavelength 540 nm emitted per second by an electric bulb of power 100W is (taking h = 6 × 1 0 −34 J-sec)
[Kerala (Engg.) 2002]
(a) 100 (b) 1000 (c) 3 × 1 0 20 (d) 3 × 1 01 8
Pλ 1 00 × 540 × 1 0 −9
Solution : (c) By using n= = = 3 × 1 0 20
hc 6.6 × 1 0 − 34 × 3 × 1 0 8
Example: 14 A steel ball of mass 1kg is moving with a velocity 1 m/s. Then its de-Broglie waves length is equal to
(a) h (b) h /2 (c) Zero (d) 1/h
h λ
Solution : (a) By using λ= ⇒ λ= = h.
mv 1 ×1
Example: 15 The de-Broglie wavelength associated with a hydrogen atom moving with a thermal velocity of 3 km/s will be
(a) 1 Å (b) 0.66 Å (c) 6.6 Å (d) 66 Å
h 6.6 × 1 0 −34
Solution : (b) By using λ= ⇒ λ= = 0.66 Å
mv rms 2 × 1 .67 × 1 0 − 27 × 3 × 1 0 3
Example: 16 When the momentum of a proton is changed by an amount P0, the corresponding change in the de-Broglie wavelength is found to be 0.25%. Then,
the original momentum of the proton was [CPMT 2002]
(a) p0 (b) 100 p0 (c) 400 p0 (d) 4 p0
1 ∆p ∆λ ∆p ∆λ p0 0. 25 1
Solution : (c) λ∝ ⇒ =− ⇒ = ⇒ = = ⇒ p = 400 p0 .
p p λ p λ p 1 00 400
Example: 17 If the electron has same momentum as that of a photon of wavelength 5200Å, then the velocity of electron in m /sec is given by
(a) 103 (b) 1.4 × 103 (c) 7 × 10–5 (d) 7.2 × 106
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10. 10 Electron, Photon, Photoelectric Effect and X-rays
h h 6.6 × 1 0 −34
Solution : (b) λ= ⇒ v= = ⇒ v = 1.4 × 103 m/s.
mv mλ 9.1 × 1 0 − 31 × 5200 × 1 0 − 1 0
Example: 18 The de-Broglie wavelength of a neutron at 27oC is λ. What will be its wavelength at 927oC
(a) λ / 2 (b) λ/3 (c) λ /4 (d) λ/9
1 λ1 T2 λ (273 + 927 ) 1 200 λ
Solution : (a) λneutron ∝ ⇒ = ⇒ = = =2 ⇒ λ2 = .
T λ2 T1 λ2 (273 + 27 ) 300 2
Example: 19 The de-Broglie wavelength of a vehicle is λ. Its load is changed such that its velocity and energy both are doubled. Its new wavelength will be
λ λ
(a) λ (b) (c) (d) 2λ
2 4
h 1 hv
Solution : (a) λ= and E = mv 2 ⇒ λ= when v and E both are doubled, λ remains unchanged i.e. λ' = λ.
mv 2 2E
Example: 20 In Thomson mass spectrograph when only electric field of strength 20 kV/m is applied, then the displacement of the beam on the screen is 2 cm. If
length of plates = 5 cm, distance from centre of plate to the screen = 20 cm and velocity of ions = 106 m/s, then q/m of the ions is
(a) 106 C/kg (b) 107 C/Kg (c) 108 C/kg (d) 1011 C/kg
qE LD
Solution : (c) By using y= ; where y = deflection on screen due to electric field only
mv 2
q yv 2 2 × 1 0 −2 × (1 0 6 )2
⇒ = = = 1 0 8 C /kg .
m ELD 20 × 1 0 3 × 5 × 1 0 − 2 × 0.2
Example: 21 The minimum intensity of light to be detected by human eye is 1 0 −1 0 W /m 2 . The number of photons of wavelength 5 . 6 × 1 0 −7 m entering the
eye, with pupil area 1 0 −6 m 2 , per second for vision will be nearly
(a) 100 (b) 200 (c) 300 (d) 400
P
Solution : (c) By using I = ; where P = radiation power
A
nh c n IAλ
⇒ P = I×A ⇒ = IA ⇒ =
tλ t hc
−1 0
n 10 × 1 0 −6 × 5 . 6 × 1 0 −7
Hence number of photons entering per sec the eye = = 300.
t 6.6 × 1 0 − 34 × 3 × 1 0 8
Tricky example: 1
A particle of mass M at rest decays into two particles of masses m 1 and m 2 , having non-zero velocities. The ratio of the de-Broglie
wavelengths of the particles, λ1 /λ 2 is [IIT-JEE 1999]
(a) m 1 /m 2 (b) m 2 /m 1 (c) 1.0 (d) m1 / m1
Solution : (c) According to conservation of momentum i.e. p1 = p 2
→
p1
h λ1 p 1 m1
Hence from λ= ⇒ = 1 =
p λ2 p2 1 M
m2
→
p2
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11. Tricky example: 2
Electron, Photon, Photoelectric Effect and X-rays 11
The curve drawn between velocity and frequency of photon in vacuum will be a [MP PET 2000]
(a) Straight line parallel to frequency axis
(b) Straight line parallel to velocity axis
(c) Straight line passing through origin and making an angle of 45o with frequency axis
(d) Hyperbola
Solution : (a) Velocity of photon (i.e. light) doesn’t depend upon frequency. Hence the graph between velocity of photon and frequency will be as
follows.
Velocity of
photon (c)
Photo-electric Effect.
It is the phenomenon of emission of electrons from the surface of metals, when light radiations (Electromagnetic radiations) of suitable frequency fall on them.
The emitted electrons are called photoelectrons and the current so produced is called photoelectric current.
This effect is based on the principle of conservation of energy.
(1) Terms related to photoelectric effect Frequency (ν)
(i) Work function (or threshold energy) (W0) : The minimum energy of incident radiation, required to eject the electrons from metallic surface is defined as
work function of that surface.
hc
W0 = hν 0 = Joules ; ν0 = Threshold frequency; λ0 = Threshold wavelength
λ0
hc 1 2375
Work function in electron volt W0(eV) = =
e λ0 λ 0 ( Å)
Note : By coating the metal surface with a layer of barium oxide or strontium oxide it's work function is lowered.
(ii) Threshold frequency (ν 0) : The minimum frequency of incident radiations required to eject the electron from metal surface is defined as threshold
frequency.
If incident frequency ν < ν0 ⇒ No photoelectron emission
(iii) Threshold wavelength (λ 0) : The maximum wavelength of incident radiations required to eject the electrons from a metallic surface is defined as
threshold wavelength.
If incident wavelength λ > λ0 ⇒ No photoelectron emission
(2) Einstein's photoelectric equation
According to Einstein, photoelectric effect is the result of one to one inelastic collision between photon and electron in which photon is completely absorbed. So
if an electron in a metal absorbs a photon of energy E (= hν), it uses the energy in three following ways.
(i) Some energy (say W) is used in shifting the electron from interior to the surface of the metal.
(ii) Some energy (say W0) is used in making the surface electron free from the metal.
Incident photon
(iii) Rest energy will appear as kinetic energy (K) of the emitted photoelectrons.
Hence E = W + W0 + K K
Work
For the electrons emitting from surface W = 0 so kinetic energy of emitted electron will be function W0
max. e–
Hence E = W0 + Kmax ; This is the Einstein's photoelectric equation W
(3) Experimental arrangement to observe photoelectric effect e– Metal
When light radiations of suitable frequency (or suitable wavelength and suitable energy)
falls on plate P, photoelectrons are emitted from P.
Radiations
(i) If plate Q is at zero potential w.r.t. P, very small current flows in the circuit because of
some electrons of high kinetic energy are reaching to plate Q, but this current has no practical e–→ e– e–→ e–→ –→
e–→ e e–→ e →
→ –
utility.
P e–→ e–→ e–→ e–→ Q
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mA
Battery
12. 12 Electron, Photon, Photoelectric Effect and X-rays
(ii) If plate Q is kept at positive potential w.r.t. P current starts flowing through the circuit because more electrons are able to reach upto plate Q.
(iii) As the positive potential of plate Q increases, current through the circuit increases but after some time constant current flows through the circuit even
positive potential of plate Q is still increasing, because at this condition all the electrons emitted from plate P are already reached up to plate Q. This constant
current is called saturation current.
(iv) To increase the photoelectric current further we will have to increase the intensity of incident light.
Photoelectric current (i) depends upon
(a) Potential difference between electrodes (till saturation) I
(b) Intensity of incident light (I)
(c) Nature of surface of metal
i
(v) To decrease the photoelectric current plate Q is maintained at negative potential w.r.t. P, as the anode Q is made more and more negative, fewer and fewer electrons
will reach the cathode and the photoelectric current decreases.
(vi) At a particular negative potential of plate Q no electron will reach the plate Q and the current will become zero, this negative potential is called
stopping potential denoted by V0.
(vii) If we increase further the energy of incident light, kinetic energy of photoelectrons increases and more negative potential should be applied to stop the
electrons to reach upto plate Q. Hence eV 0 = K max .
Note : Stopping potential depends only upon frequency or wavelength or energy of incident radiation. It doesn't depend upon intensity of light.
We must remember that intensity of incident light radiation is inversely proportional to the square of distance between source of light and
1 1
photosensitive plate P i.e., I∝ so I ∝i∝ )
d2 d2
Important formulae
⇒ hν = hν 0 + K m ax
1 2 h(ν − ν 0 )
⇒ K m ax = eV 0 = h(ν − ν 0 ) ⇒ mv m ax = h(ν − ν 0 )
2
⇒ v m ax =
2 m
1 1 1 λ −λ 2 hc ( λ − λ 0 )
⇒ K m ax = mv m ax = eV 0 = hc − = hc 0
2
λ λ λλ ⇒ v m ax =
2 0 0 m λλ 0
h hc 1 1 1 1
⇒ V0 = (ν − ν 0 ) = −
λ λ = 1 2375
−
λ λ
e e 0 0
(4) Different graphs
(i) Graph between potential difference between the plates P and Q and photoelectric current
i i
I3
I2
I1 ν3 > ν2 > ν1
ν3
ν2 ν
1
– V0 1 V 2 – V0 3
(ii) Graph between maximum kinetic energy / stopping potential of photoelectrons and frequency–of0incident light V
– V0 V
For different intensities of incident For different Frequencies of
light incident light
V0
Kmax
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–W0 ν
–W0/e ν
Slope = tanθ = h
Slope = tanθ = h/e
13. Electron, Photon, Photoelectric Effect and X-rays 13
Photoelectric Cell.
A device which converts light energy into electrical energy is called photoelectric cell. It is also known as photocell or electric eye.
Photoelectric cell are mainly of three types
Photo-emissive cell Photo-conductive cell Photo-voltaic cell
It consists of an evacuated glass or quartz bulb It is based on the principle that conductivity of a
semiconductor increases with increase in the It consists of a Cu plate coated with a thin
containing anode A and cathode C. The cathode
is semi-cylindrical metal on which a layer of
intensity of incident light. layer of cuprous oxide (Cu2O). On this plate is
photo-sensitive material is coated. laid a semi transparent thin film of silver.
Transparent
film of silver
A C
Surface film
Light
In this, a thin layer of some semiconductor (as
selenium) is placed below a transparent foil of A
When light incident on the cathode, it emits When light fall, the electrons emitted from the
Output
some metal. Selenium
This combination is fixed Output an
R
over C
layer of Cu2O and move of Cu2O R
photo-electrons which are attracted by the
Galvanometer iron plate. Selenium light is incident on the
When Semiconducting layer towards the silver film.
anode. The photoelectrons constitute a small
or transparent foil,layerelectrical resistance of
Metal the Then the silver film becomes negatively charged
current which flows through ammeter
Micro the external the semiconductor layer is reduced. Hence a Metal layer of Cu
and copper plate becomes positively charged. A
circuit. current starts flowing in the battery circuit potential difference is set up between these two
connected. and current is set up in the external resistance.
µA
+ –
Note : The photoelectric current can be increased by filling some inert gas like Argon into the bulb. The photoelectrons emitted by cathode ionise the
gas by collision and hence the current is increased.
Compton effect
The scattering of a photon by an electron is called Compton effect. The energy and momentum is conserved. Scattered photon will have less energy (more
wavelength) as compare to incident photon (less wavelength). The energy lost by the photon is taken by electron as kinetic energy.
h
The change in wavelength due to Compton effect is called Compton shift. Compton shift λ f − λi = (1 − cos θ )
m 0c
Compton scattering
–
Target electron
at rest Recoil
electron
hν – θ
φ
Note : Compton effect shows that photon have momentum. λi hν ′
Incident photon
λf
Scattered photon
X-rays.
X-rays was discovered by scientist Rontgen that's why they are also called Rontgen rays.
Rontgen discovered that when pressure inside a discharge tube kept 10–3 mm of Hg and potential difference is 25 kV then some unknown radiations (X-rays) are
emitted by anode.
(1) Production of X-rays
There are three essential requirements for the production of X-rays
(i) A source of electron
(ii) An arrangement to accelerate the electrons
(iii) A target of suitable material of high atomic weight and high melting point on which these high speed electrons strike.
(2) Coolidge X-ray tube
It consists of a highly evacuated glass tube containing cathode and target. The cathode consist of a tungsten filament. The filament is coated with oxides of
barium or strontium to have an emission of electrons even at low temperature. The filament is surrounded by a molybdenum cylinder kept at negative potential w.r.t.
the target.
The target (it's material of high atomic weight, high melting point and high thermal conductivity) made of tungsten or molybdenum is embedded in a copper block.
The face of the target is set at 45o to the incident electron stream.
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14. 14 Electron, Photon, Photoelectric Effect and X-rays
Lead V
chamber Anode
C
Water
T
F
Filament W Target
Window X-rays
The filament is heated by passing the current through it. A high potential difference (≈ 10 kV to 80 kV) is applied between the target and cathode to
accelerate the electrons which are emitted by filament. The stream of highly energetic electrons are focussed on the target.
Most of the energy of the electrons is converted into heat (above 98%) and only a fraction of the energy of the electrons (about 2%) is used to produce X-
rays.
During the operation of the tube, a huge quantity of heat is produced in this target, this heat is conducted through the copper anode to the cooling fins from
where it is dissipated by radiation and convection.
(i) Control of intensity of X-rays : Intensity implies the number of X-ray photons produced from the target. The intensity of X-rays emitted is directly
proportional to the electrons emitted per second from the filament and this can be increased by increasing the filament current. So intensity of X-rays ∝ Filament
current
(ii) Control of quality or penetration power of X-rays : Quality of X-rays implies the penetrating power of X-rays, which can be controlled by varying
the potential difference between the cathode and the target.
For large potential difference, energy of bombarding electrons will be large and hence larger is the penetration power of X-rays.
Depending upon the penetration power, X-rays are of two types
Hard X-rays Soft X-rays
More penetration power Less penetration power
More frequency of the order of ≈ 1019 Hz Less frequency of the order of ≈ 1016 Hz
Lesser wavelength range (0.1Å – 4Å) More wavelength range (4Å – 100Å)
Note : Production of X-ray is the reverse phenomenon of photoelectric effect.
(3) Properties of X-rays
(i) X-rays are electromagnetic waves with wavelength range 0.1Å – 100Å.
(ii) The wavelength of X-rays is very small in comparison to the wavelength of light. Hence they carry much more energy (This is the only difference between
X-rays and light)
(iii) X-rays are invisible.
(iv) They travel in a straight line with speed of light.
(v) X-rays are measured in Rontgen (measure of ionization power).
(vi) X-rays carry no charge so they are not deflected in magnetic field and electric field.
(vii) λ G ama rays < λ X -rays < λU V rays
(viii) They used in the study of crystal structure.
(ix) They ionise the gases
(x) X-rays do not pass through heavy metals and bones.
(xi) They affect photographic plates.
(xii) Long exposure to X-rays is injurious for human body.
(xiii) Lead is the best absorber of X-rays.
(xiv) For X-ray photography of human body parts, BaSO4 is the best absorber.
(xv) They produce photoelectric effect and Compton effect
(xvi) X-rays are not emitted by hydrogen atom.
(xvii) These cannot be used in Radar because they are not reflected by the target.
(xviii) They show all the important properties of light rays like; reflection, refraction, interference, diffraction and polarization etc.
(4) Absorption of X-rays
X-rays are absorbed when they incident on substance.
I0
I = I 0 e − µx
Emergent X-
Intensity of emergent X-rays rays
So intensity of absorbed X-rays I ' = I 0 − I = I 0 (1 − e − µx ) Incident X-rays
I
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15. Electron, Photon, Photoelectric Effect and X-rays 15
where x = thickness of absorbing medium, µ = absorption coefficient
I0
Note : The thickness of medium at which intensity of emergent X-rays becomes half i.e. I'= is called half value thickness (x1/2) and it is given as
2
0.693
x 1 /2 = .
µ
Classification of X-rays.
In X-ray tube, when high speed electrons strikes the target, they penetrate the target. They loses their kinetic energy and comes to rest inside the metal. The
electron before finally being stopped makes several collisions with the atoms in the target. At each collision one of the following two types of X-rays may get form.
(1) Continuous X-rays
As an electron passes close to the positive nucleus of atom, the electron is deflected from it's path as shown in figure. This results in deceleration of the
electron. The loss in energy of the electron during deceleration is emitted in the form of X-rays.
The X-ray photons emitted so form the continuous X-ray spectrum.
X-ray photon
e–
+
Note : Continuos X-rays are produced due to the phenomenon called "Bremsstrahlung". It means slowing down or braking radiation.
Minimum wavelength
When the electron looses whole of it's energy in a single collision with the atom, an X-ray photon of maximum energy hνmax is emitted i.e.
1 hc
mv 2 = eV = hν m ax =
2 λ m in
where v = velocity of electron before collision with target atom, V = potential difference through which electron is accelerated, c = speed of light = 3 × 108 m/
s
eV
Maximum frequency of radiations (X-rays) ν m ax =
h
hc 1 2375
Minimum wave length = cut off wavelength of X-ray λ m in = = Å
eV V
Note : Wavelength of continuous X-ray photon ranges from certain minimum (λmin) to infinity.
νmax logeνmax λmin logeλmax
Intensity wavelength graph
of logeV
The continuous X-ray spectra consist V all the wavelengths over a given range. These wavelength are of different intensities. V
V loge Following figure shows the
intensity variation of different wavelengths for various accelerating voltages applied to X-ray tube.
For each voltage, the intensity curve starts at a particular minimum wavelength (λmin). Rises rapidly to a
Y
Intensity
maximum and then drops gradually.
The wavelength at which the intensity is maximum depends on the accelerating voltage, being shorter for
higher voltage and vice-versa.
(2) Characteristic X-rays 30 kV
20 kV
Few of the fast moving electrons having high velocity penetrate the surface atoms of the target material 10 kV
and knock out the tightly bound electrons even from the inner most shells of the atom. Now when the electron is
knocked out, a vacancy is created at that place. To fill this vacancy electrons from higher shells jump to fill the λmin Wave length
created vacancies, we know that when an electron jumps from a higher energy orbit E1 to lower energy orbit E2, it radiates energy (E1 – E2). Thus this energy
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16. 16 Electron, Photon, Photoelectric Effect and X-rays
difference is radiated in the form of X-rays of very small but definite wavelength which depends upon the target material. The X-ray spectrum consist of sharp lines
and is called characteristic X-ray spectrum.
e–
X-ray photon
e–
e –
+
K
L
M
K, L, M, …… series
If the electron striking the target eject an electron from the K-shell of the atom, a vacancy is
O n=5
crated in the K-shell. Immediately an electron from one of the outer shell, say L-shell jumps to the K- N n=4
shell, emitting an X-ray photon of energy equal to the energy difference between the two shells. Similarly,
Mα Mβ
if an electron from the M-shell jumps to the K-shell, X-ray photon of higher energy is emitted. The X-ray
M n=3
photons emitted due to the jump of electron from the L, M, N shells to the K-shells gives Kα, Kβ, Kγ lines of M-series
Lα Lβ Lγ
the K-series of the spectrum. L n=2
L-series
If the electron striking the target ejects an electron from the L-shell of the target atom, an Kα Kβ Kγ
electron from the M, N ….. shells jumps to the L-shell so that X-rays photons of lesser energy are emitted. K n=1
K-series
These photons form the lesser energy emission. These photons form the L-series of the spectrum. In a similar
way the formation of M series, N series etc. may be explained.
Energy and wavelength of different lines
Series Transition Energy Wavelength
L →K hc 1 2375
Kα E L − E K = hν K α λK α = = Å
(2 ) (1 ) E L − E K (E L − E K )eV
M→K hc 1 2375
Kβ E M − E K = hν K β λK β = = Å
(3) (1 ) E M − E K (E M − E K )eV
M→ L hc 1 2375
Lα E M − E L = hν L α λLα = = Å
(3) (2 ) EM − EL (E M − E L )eV
Note : The wavelength of characteristic X-ray doesn't depend on accelerating voltage. It depends on the atomic number (Z) of the target material.
λ K α < λ L α < λ Mα and ν K α > ν L α > ν Mα
λ Kα > λ Lβ < λ Kγ
Intensity-wavelength graph
Intensity Kα
At certain sharply defined wavelengths, the intensity of X-rays is very large as marked Kα, Kβ …. As
shown in figure. These X-rays are known as characteristic X-rays. At other wavelengths the intensity varies Kβ
gradually and these X-rays are called continuous X-rays. L
Lγ Lβ α
K-series
Mosley's law L-series
kβ
Mosley studied the characteristic X-ray spectrum of a number of a heavy elements and concluded that
the spectra of different elements are very similar and with increasing atomic number, the spectral lines merely ν
shift towards higher frequencies. λmin kλ Wavelength
He also gave the following relation ν = a (Z − b )
where ν = Frequency of emitted line, Z = Atomic number of target, a = Proportionality constant,
Z
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