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THERMIONIC EMISSION &RADIOACTIVITY

Vipul Sharma
Vipul Sharma

THERMIONIC EMISSION AND RADIOACTIVITY

EducationTechnologyBusiness
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THERMIONIC EMISSION AND RADIOACTIVITY BY:- VIPUL SHARMA 36 SHIV GHOSH 13 ABHINAV SAGAR 37
THERMIONIC EMISSION
THERMIONIC EMISSION Thermionic emission is the heat-induced flow of charge carriers from a surface or over a potential-energy barrier. This occurs because the thermal energy given to the carrier overcomes the binding potential, also known as work function of the metal. The charge carriers can be electrons or ions, and in older literature are sometimes referred to as "thermions". After emission, a charge will initially be left behind in the emitting region that is equal in magnitude and opposite in sign to the total charge emitted. But if the emitter is connected to a battery, then this charge left behind will be neutralized by charge supplied by the battery, as the emitted charge carriers move away from the emitter, and finally the emitter will be in the same state as it was before emission. The thermionic emission of electrons is also known as thermal electron emission.
EDISON’S EXPERIMENT Thomas Edison on February 13, 1880, while trying to discover the reason for breakage of lamp filaments and uneven blackening of the bulbs in his incandescent lamp built several experiment bulbs, some with an extra wire, a metal plate, or foil inside the bulb which was electrically separate from the filament, and thus could serve as an electrode. He connected a galvanometer to the output of the extra metal electrode. When the foil was charged negatively relative to the filament, no charge flowed between the filament and the foil. In addition, charge did not flow from the foil to the filament because the foil was not heated enough to emit charge. However, when the foil was given a more positive charge than the filament, negative charge could flow from the filament through the vacuum to the foil. This one-way current was called the Edison effect. He found that the current emitted by the hot filament increased rapidly with increasing voltage, and filed a patent application for a voltage-regulating device using the effect on November 15.
EDISON’S EXPERIMENT
FACTORS AFFECTING THE RATE OF THERMIONIC EMISSION
i. Nature of the metal surface Lower the work function of the metal, greater is the rate of emission of electrons from the surface. ii. Temperature of the surface Higher is the temperature, more will be the rate of emission as the electrons will have more kinetic energy to leave the surface. iii.Surface area of the metal Larger the surface area of the metal, more is the rate of emission as thermionic emission to some extent is like evaporation.
CONDITIONS FOR GOOD ELECTRON EMITTER
i. Low work function The work function of the body should be low so that the electrons could be emitted even when the substance is not heated to a high temperature. ii. High melting point The melting point of the substance should be low so that the metal does not get melted when heated.
CATHODE RAY TUBE The cathode ray tube is a vacuum tube containing an electron gun (a source of electrons or electron emitter) and a fluorescent screen used to view images. It has a means to accelerate and deflect the electron beam onto the fluorescent screen to create the images. The images may represent electrical waveforms (oscilloscope), pictures (television, computer monitor), radar targets and others. CRTs have also been used as memory devices, in which case the visible light emitted from the fluorescent material is not intended to have significant meaning to a visual observer (though the visible pattern on the tube face may cryptically represent the stored data).
CATHODE RAY TUBE
PARTS OF A CATHODE RAY TUBE
ELECTRON GUN • An electron gun (also called electron emitter) is an electrical component that produces an electron beam that has a precise kinetic energy and is most often used in television sets and computer displays that use cathode ray tube (CRT) technology, as well as in other instruments, such as electron microscopes and particle accelerator. A direct current, electrostatic thermionic electron gun is formed from several parts: a hot cathode, which is heated to create a stream of electrons via thermionic emission, electrodes generating an electric field which focus the beam (such as a Wehnelt cylinder), and one or more anode electrodes which accelerate and further focus the electrons accelerators.
ELECTRON GUN
THE DEFLECTING SYSTEM • It is the part of the cathode ray tube that deflects the electron beam. It consists of two pairs of plates, one is kept horizontal called the Y- plates and the other vertical called the X-plates. These are placed with the plane parallel to the beam. When a potential difference is applied across the plate the electric field is set up which deflects the electron beam. The Y-plates deflect the beam in vertical direction while the X- plates deflect in horizontal direction. It should be noted that the deflection caused by the magnetic field is much larger than compared to the same length of electric field.
THE FLUORESCENT SCREEN • The end of the tube is made of a screen whose inside part is coated with zinc sulphide or barium platinocyanide etc. the electron beam on striking the screen gives a bright spot. If a varying potential is applied on the deflecting plates, the beam deflects according to the variation of potential on the plates and the spot traces out a pattern.
FLUORESCENT SCREEN
USES OF CATHODE RAY TUBE • i)To investigate the wave form of the unknown alternating potential by applying it on the Y-plates and a known periodic time base potential on the X-plates. • ii) In determining the frequency of an alternating potential by applying it on one pair of deflecting plates. iii) For checking the wave form of an electric signal. iv) For measuring the short time interval. v) In television as a picture tube.
USES OF CATHODE RAY TUBE
RADIOACTIVITY
RADIOACTIVITY AS ALPHA,BETA AND GAMMA RADIAIONS
ALPHA PARTICLES
ALPHA PARTICLES • Alpha Particles-An alpha particle has two protons and two neutrons, so it has a positive charge. (Since it has two protons it is a helium nucleus.) It is produced from large nuclei. • When an atom emits an alpha particle, the atom's mass number decreases by four due to the loss of the four nucleons in the alpha particle. The atomic number of the atom goes down by exactly two, as a result of the loss of two protons – the atom becomes a new element. Examples of this are when uranium becomes thorium, or radium becomes radon gas due to alpha decay. • Alpha particles are commonly emitted by all of the larger radioactive nuclei such as uranium, thorium, actinium, and radium, as well as the transuranic elements. Unlike other types of decay, alpha decay as a process must have a minimum-size atomic nucleus which can support it. The smallest nuclei which have to date been found to be capable of alpha emission are the lightest nuclides of tellurium (element 52), with mass numbers between 106 and 110.
ALPHA PARTICLE
BETA PARTICLES
BETA PARTICLES • Beta emission is when a high speed electron (negative charge) leaves the nucleus. Beta emission occurs in elements with more neutrons than protons, so a neutron splits into a proton and an electron. The proton stays in the nucleus and the electron is emitted. • Beta particles are high-energy, high-speed electrons or positrons emitted by certain types of radioactive nuclei such as potassium-40. The beta particles emitted are a form of ionizing radiation also known as beta rays. The production of beta particles is termed beta decay. They are designated by the Greek letter beta (β). There are two forms of beta decay, β− and β+, which respectively give rise to the electron and the positron
BETA PATICLE
GAMMA PARTICLES
GAMMA PARTICLES • Gamma radiation, also known as gamma rays, and denoted by the Greek letter γ, refers to electromagnetic radiation of high frequency and therefore high energy per photon. Gamma rays are ionizing radiation, and are thus biologically hazardous. They are classically produced by the decay from high energy states of atomic nuclei (gamma decay), but are also created by other processes. Paul Villard, a French chemist and physicist, discovered gamma radiation in 1900, while studying radiation emitted from radium. Villard's radiation was named "gamma rays" by Ernest Rutherford in 1903. Natural sources of gamma rays on Earth include gamma decay from naturally occurring radioisotopes, and secondary radiation from atmospheric interactions with cosmic ray particles. Rare terrestrial natural sources produce gamma rays that are not of a nuclear origin, such as lightning strikes and terrestrial gamma-ray flashes.
GAMMA PARTICLE
SOME USES OF RADIOACTIVITY
SOME USES OF RADIOACTIVITY
DISADVANTAGES OF RADIOACTIVITY • If radiation collides with molecules in the air or in your body, it throws out of them electrons. By throwing out electrons you produce charged particles called ions. This means it is the radiation responsible for ionising molecules. • If this happens in our body, the cells may die or they may undergo a change called a mutation. The result is called radiation sickness. A large dose of radiation will cause death! • Small doses of radiation over a long period of time can cause the cells to multiply. However, these cells are mutated. Some time later cancer may occur.
THERMIONIC EMISSION &RADIOACTIVITY

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THERMIONIC EMISSION &RADIOACTIVITY

  • 1. THERMIONIC EMISSION AND RADIOACTIVITY BY:- VIPUL SHARMA 36 SHIV GHOSH 13 ABHINAV SAGAR 37
  • 3. THERMIONIC EMISSION Thermionic emission is the heat-induced flow of charge carriers from a surface or over a potential-energy barrier. This occurs because the thermal energy given to the carrier overcomes the binding potential, also known as work function of the metal. The charge carriers can be electrons or ions, and in older literature are sometimes referred to as "thermions". After emission, a charge will initially be left behind in the emitting region that is equal in magnitude and opposite in sign to the total charge emitted. But if the emitter is connected to a battery, then this charge left behind will be neutralized by charge supplied by the battery, as the emitted charge carriers move away from the emitter, and finally the emitter will be in the same state as it was before emission. The thermionic emission of electrons is also known as thermal electron emission.
  • 4. EDISON’S EXPERIMENT Thomas Edison on February 13, 1880, while trying to discover the reason for breakage of lamp filaments and uneven blackening of the bulbs in his incandescent lamp built several experiment bulbs, some with an extra wire, a metal plate, or foil inside the bulb which was electrically separate from the filament, and thus could serve as an electrode. He connected a galvanometer to the output of the extra metal electrode. When the foil was charged negatively relative to the filament, no charge flowed between the filament and the foil. In addition, charge did not flow from the foil to the filament because the foil was not heated enough to emit charge. However, when the foil was given a more positive charge than the filament, negative charge could flow from the filament through the vacuum to the foil. This one-way current was called the Edison effect. He found that the current emitted by the hot filament increased rapidly with increasing voltage, and filed a patent application for a voltage-regulating device using the effect on November 15.
  • 7. i. Nature of the metal surface Lower the work function of the metal, greater is the rate of emission of electrons from the surface. ii. Temperature of the surface Higher is the temperature, more will be the rate of emission as the electrons will have more kinetic energy to leave the surface. iii.Surface area of the metal Larger the surface area of the metal, more is the rate of emission as thermionic emission to some extent is like evaporation.
  • 9. i. Low work function The work function of the body should be low so that the electrons could be emitted even when the substance is not heated to a high temperature. ii. High melting point The melting point of the substance should be low so that the metal does not get melted when heated.
  • 10. CATHODE RAY TUBE The cathode ray tube is a vacuum tube containing an electron gun (a source of electrons or electron emitter) and a fluorescent screen used to view images. It has a means to accelerate and deflect the electron beam onto the fluorescent screen to create the images. The images may represent electrical waveforms (oscilloscope), pictures (television, computer monitor), radar targets and others. CRTs have also been used as memory devices, in which case the visible light emitted from the fluorescent material is not intended to have significant meaning to a visual observer (though the visible pattern on the tube face may cryptically represent the stored data).
  • 12. PARTS OF A CATHODE RAY TUBE
  • 13. ELECTRON GUN • An electron gun (also called electron emitter) is an electrical component that produces an electron beam that has a precise kinetic energy and is most often used in television sets and computer displays that use cathode ray tube (CRT) technology, as well as in other instruments, such as electron microscopes and particle accelerator. A direct current, electrostatic thermionic electron gun is formed from several parts: a hot cathode, which is heated to create a stream of electrons via thermionic emission, electrodes generating an electric field which focus the beam (such as a Wehnelt cylinder), and one or more anode electrodes which accelerate and further focus the electrons accelerators.
  • 15. THE DEFLECTING SYSTEM • It is the part of the cathode ray tube that deflects the electron beam. It consists of two pairs of plates, one is kept horizontal called the Y- plates and the other vertical called the X-plates. These are placed with the plane parallel to the beam. When a potential difference is applied across the plate the electric field is set up which deflects the electron beam. The Y-plates deflect the beam in vertical direction while the X- plates deflect in horizontal direction. It should be noted that the deflection caused by the magnetic field is much larger than compared to the same length of electric field.
  • 16.
  • 17. THE FLUORESCENT SCREEN • The end of the tube is made of a screen whose inside part is coated with zinc sulphide or barium platinocyanide etc. the electron beam on striking the screen gives a bright spot. If a varying potential is applied on the deflecting plates, the beam deflects according to the variation of potential on the plates and the spot traces out a pattern.
  • 19. USES OF CATHODE RAY TUBE • i)To investigate the wave form of the unknown alternating potential by applying it on the Y-plates and a known periodic time base potential on the X-plates. • ii) In determining the frequency of an alternating potential by applying it on one pair of deflecting plates. iii) For checking the wave form of an electric signal. iv) For measuring the short time interval. v) In television as a picture tube.
  • 20. USES OF CATHODE RAY TUBE
  • 21.
  • 24.
  • 26. ALPHA PARTICLES • Alpha Particles-An alpha particle has two protons and two neutrons, so it has a positive charge. (Since it has two protons it is a helium nucleus.) It is produced from large nuclei. • When an atom emits an alpha particle, the atom's mass number decreases by four due to the loss of the four nucleons in the alpha particle. The atomic number of the atom goes down by exactly two, as a result of the loss of two protons – the atom becomes a new element. Examples of this are when uranium becomes thorium, or radium becomes radon gas due to alpha decay. • Alpha particles are commonly emitted by all of the larger radioactive nuclei such as uranium, thorium, actinium, and radium, as well as the transuranic elements. Unlike other types of decay, alpha decay as a process must have a minimum-size atomic nucleus which can support it. The smallest nuclei which have to date been found to be capable of alpha emission are the lightest nuclides of tellurium (element 52), with mass numbers between 106 and 110.
  • 29. BETA PARTICLES • Beta emission is when a high speed electron (negative charge) leaves the nucleus. Beta emission occurs in elements with more neutrons than protons, so a neutron splits into a proton and an electron. The proton stays in the nucleus and the electron is emitted. • Beta particles are high-energy, high-speed electrons or positrons emitted by certain types of radioactive nuclei such as potassium-40. The beta particles emitted are a form of ionizing radiation also known as beta rays. The production of beta particles is termed beta decay. They are designated by the Greek letter beta (β). There are two forms of beta decay, β− and β+, which respectively give rise to the electron and the positron
  • 32. GAMMA PARTICLES • Gamma radiation, also known as gamma rays, and denoted by the Greek letter γ, refers to electromagnetic radiation of high frequency and therefore high energy per photon. Gamma rays are ionizing radiation, and are thus biologically hazardous. They are classically produced by the decay from high energy states of atomic nuclei (gamma decay), but are also created by other processes. Paul Villard, a French chemist and physicist, discovered gamma radiation in 1900, while studying radiation emitted from radium. Villard's radiation was named "gamma rays" by Ernest Rutherford in 1903. Natural sources of gamma rays on Earth include gamma decay from naturally occurring radioisotopes, and secondary radiation from atmospheric interactions with cosmic ray particles. Rare terrestrial natural sources produce gamma rays that are not of a nuclear origin, such as lightning strikes and terrestrial gamma-ray flashes.
  • 35. SOME USES OF RADIOACTIVITY
  • 36. DISADVANTAGES OF RADIOACTIVITY • If radiation collides with molecules in the air or in your body, it throws out of them electrons. By throwing out electrons you produce charged particles called ions. This means it is the radiation responsible for ionising molecules. • If this happens in our body, the cells may die or they may undergo a change called a mutation. The result is called radiation sickness. A large dose of radiation will cause death! • Small doses of radiation over a long period of time can cause the cells to multiply. However, these cells are mutated. Some time later cancer may occur.