Electron gun; potentials around charged plates
An electron gun releases electrons by thermionic emission and accelerate the electron through charged plates, and that the electrons are not gaining any energy after they leave the gap between the plates. I'm confused about charges/potentials around the charged plates.
An infinitely long and wide plate will, indeed, produce a constant potential. The electrostatic force acting on a charge in a constant potential is zero, so in the ideal case the charges won't move. The solution to your paradox is that plates of infinite extensions don't exist.
What we mean by "infinite size plates" are plates that are so large that the potential sufficiently close to them is sufficiently constant. It can never be exactly constant, except on a conducting surface.
In the region between two parallel plates of different charge that are close enough together the potential is a linear function and the force is constant. This is a plate capacitor that can also be used to accelerate charges. Outside of the plates there is a substantial fringe field with a complicated field that extends all the way to infinity.
The beam of electrons as a result of thermionic emission.
In an electron gun, the emitted electrons from the cathode become incident at a point on the other end of the tube, as they travel through a gap allocated in the anode. the motion of the electrons from the cathode to the anode is as a result of the electric field, and as a result, the electrons are accelerated towards the positively charged anode.
- the cool thing about the parallel plate arrangement of electrodes in an electron gun. The field is strong and (fairly) uniform in the the space between the plates but much less outside of the plates. In the ideal case of a pair of infinitely large plates with an equal and opposite uniform charge distribution, the field outside the plates would be zero. If you have a point charge the electric field strength decreases proportionally to the distance from it squared. If you have an infinitely long line of charge the electric field strength decreases proportionally to the distance (not distance squared). But, if you have an infinite plane of charge the electric field strength it produces is the same - independent of the distance to the plane. Now, say you put your positive plate on the bottom it will produce an electric field directed upwards above it (away from the positive plate). If you then put a negatively charged plate above the positive plate it will produce an upward field below it (towards the negative plate). These two fields are both in the same direction and so result in a strong field. But, the negative plates field above itself is downwards (still towards it) and the field there from the positive plate is upwards (still away from it). So in the region above the negative plate (or below the positive plate) the fields from each are in opposite directions and, since the distance from the plates does not affect their strength, they cancel out completely. Obviously in an electron gun the anode and cathode are not infinitely large but even with finite plates the field "outside" of the anode is much, much smaller than on the field between the plates so the electron is not pulled back. Having written all this and then looked at some images of electron guns I realize the the version I described is a simplified one with a hot filament between two planar electrodes. The geometry of practical electron guns is a bit different.
- Thermionic emission gets the electrons out of the metal filament but I don't think you can really call the electrons a cathode ray until you accelerate them. A regular incandescent light bulb will produce thermionic emission but the emitted electrons are just attracted back to filament. There are cold cathode devices that emit electrons by means other than thermionic emission.
A series of cathode ray tubes graphically demonstrate various properties of the electron. Cathode Ray Tube provides evidence that cathode rays are not visible to human eyes. Cathode Ray Tube cathode rays cast a shadow behind a Maltese Cross. Cathode Ray Tube light shined on a pinwheel inside a CRT does not cause the pinwheel to move. However, when cathode rays strike the pinwheel inside the CRT, the pinwheel begins to spin and move. Cathode Ray Tube in a darkened room, the electron beam (cathode rays) shows up on a phosphor screen as a bright blue line. The electron beam is deflected by an electric field and a magnetic field.
Electrons travel in straight lines from the cathode towards the anode (Maltese Cross CRT). Cathode Rays are particles and have mass because cathode rays cause a metal pinwheel inside a CRT to turn. Cathode rays have a negative charge because J.J. Thompson's experiment showed the cathode rays being pulled toward the positive capacitor plate and away from the negative charge plate and a magnetic field deflects the cathode rays in a direction consistent with the rays being negatively charged particles.
The electrons are emitted by a heated filament and are accelerated by a positively charged screen in the electron gun. When the electrons strike the phosphorescent screen they excite the electrons of the phosphorescent material into higher energy states. As the electrons move back down into ground state they emit visible light.
Deflection of Cathode Rays by an Electric Field - The application of high voltage to capacitor plates creates an electric field. When a cathode ray is passed through this electric field, the negatively charged electrons are deflected toward the positive charged plate and away from the negatively charged plate. Like charges repel, unlike charges attract.
Deflection of Cathode Rays by a Magnetic Field- The magnet creates a magnetic field perpendicular to the electron beam and parallel to the plane of the tabletop. The magnetic field deflects the electrons according to the right hand rule.
Materials
- cathode ray tube
- high voltage DC/ 120 VAC power supply for electron gun and heater coil
- high voltage DC power supply for deflection plates
- power strips
- jumper cables with banana plugs to connect everything
- a fairly powerful magnet
Procedure
Deflection of Cathode Rays (electron beam) by an Electric Field - Turn on the power strip. Turn on the power to both high voltage sources. Dim the houselights. Turn up the power on the high voltage source connected to the electron gun. The trace of a cathode ray should appear on the phosphorescent screen. Turn up the power on the high voltage source connected to the capacitor plates. The cathode ray should be deflected upward. Turn down both power supplies all the way. If desired, switch the leads going to the deflection plates and repeat the process. The cathode ray should be deflected downward.
Deflection of Cathode Rays by a Magnetic Field - Turn on the power strip. Turn on the power to both high voltage sources. Dim the houselights. Turn up the power on the high voltage source connected to the electron gun. The trace of a cathode ray should appear on the phosphorescent screen. Bring one end of the magnet close to the front of the tube perpendicular to the axis of the beam. The cathode ray should be deflected either upward or downward depending on which pole of the magnet is close to the beam. Turning the magnet around so that the other pole is closest to the magnetic field should cause deflection of the cathode rays in the opposite direction. Turn down both power supplies all the way.
Movement of a Pinwheel in a CRT by Interaction with Cathode Rays - cathode rays striking a pinwheel inside a CRT move the pinwheel.
Cathode Rays striking a Maltese Cross inside a CRT, produces a shadow. Provides evidence that the cathode rays originates at the cathode and travels toward the anode.
Safety Precautions
Be careful not to touch any of the high voltage leads while the power is on. The glass tube is fragile and evacuated. Wear eye protection in case of implosion.
Prep. Notes
Cathode Ray Tube
- All materials are obtained from the physics demo prep room.
- Connect the high voltage output from the high voltage DC/ 120 VAC power supply to the electron gun of the cathode ray tube (CRT). The negative lead goes in the jack in the center of the back of the electron gun part of the CRT. The positive lead goes in the jack on the side of the electron gun part of the CRT.
- Connect the leads from the 120 VAC output of the high voltage DC/ 120 VAC power supply to the CRT. One lead piggybacks onto the back of the high voltage negative lead and the other goes into the other jack right beside it, off-center on the back of the electron gun part of the CRT.
- Connect the leads from the other high voltage DC power source to the deflector plates at the top and bottom of the CRT. The positive lead should be connected to the top and the negative lead should be connected to the bottom.
- Plug both of the power supplies into the power strip and plug the power strip into an outlet.
XXX . XXX 4%zero Difference Between Anode and Cathode
Anode vs Cathode
Anode and cathode are two terms that are often used interchangeably with positive and negative in batteries. Most of the time there is no problem with it as the definition would often match the practice. However, there are certain scenarios where this is not true.
The anode, by definition, is the electrode where electricity flows into. In contrast, the cathode is the electrode where the electricity flows out of. If we look at a battery connected to a load, like a bulb for example, the electricity flows from the positive terminal to the negtive terminal. In this case, the positive terminal is the cathode, and the negative terminal is the anode. But when the battery is being charged, the electricity flows into the positive terminal instead of out of it. In this case, the roles are reversed, and the positive terminal becomes the anode and the negative terminal is the cathode.
The reversal is also very noticeable when you are dealing with components like diodes and capacitors since these components absorb electricity unlike batteries. The anode of capacitors and diodes is the side that you connect to the positive terminal since that’s where the electricity enters, and the negative terminal is the cathode because that is where the electricity leaves.
Because of the confusion with regards to the current flow and where the anode and cathode is, it is probably better to use the terms positive and negative terminals instead. It is constant and doesn’t change regardless of the current flow.
Aside from being used together, there are also applications where they are not together. A good example of this is the sacrificial anode coating, usually zinc, used to protect metals. This is common in ships where the flow of water creates a static charge. The sacrificial anode absorbs this charge and slowly disintegrates. In this manner, the underlying metal doesn’t get damaged, and only the coating needs to be restored every so often.
Summary:
1. The cathode is typically the negative side while the anode is the positive side.
2. The anode is the electrode where the electricity flows into it.
3. The cathode is the electrode where the electricity flows out of it.
1. The cathode is typically the negative side while the anode is the positive side.
2. The anode is the electrode where the electricity flows into it.
3. The cathode is the electrode where the electricity flows out of it.
Difference between Capacitor and Battery
What is a Battery?
A battery is an electronic device made of one or more cells which converts the chemical energy packed within its active materials into electrical energy to provide a static electrical charge for power.Electrons are produced through electrochemical reactions which involves transfer of electrons via an electronic circuit.
In simple terms, battery is a constant source of power which supplies electricity in the form of direct current (DC). A battery usually contains a positive (+ve) and a negative (-ve) terminal.
The cell is the basic power unit of the battery which consists of three main bits. Plus there are two electrodes and a chemical called an electrolyte which fills the gap between the electrodes.
When the electrodes are connected to a circuit, the electrons cross from the negative to the positive terminal, eventually creating an electrical charge. Energy is stored inside the battery in the form of chemical energy which gets converted into electrical energy, releasing electricity through a chemical reaction which eventually generates an electric current.
Take an example of a flashlight. When you put alkaline batteries into the flashlight and turn the switch on, you do nothing but complete the circuit. The chemical energy stored within the battery gets converted into electrical energy, which then travels out of the battery, causing the flashlight to light up. This is because the electrons are crossing through the circuit.
The cathode and anode are generally made of different materials. The positive electrode contains a material that gives up electrons quite easily such as lithium.
The electrons get to the cathode only through a circuit which is external to the battery. The electrolyte – the most crucial part in the operation of a battery – transports ions between the chemical reactions that occur in the electrodes.
These chemical reactions are collectively called as oxidation-reduction reactions.
What is a Capacitor?
A capacitor (also known as a condenser) is also an electronic component that stores electrostatic energy in an electric field.They are more like a battery but they are used for entirely different purpose. While a battery uses chemical reactions to store electrical energy and releases power very slowly through an electronic circuit, capacitors are capable of releasing energy very rapidly.
A capacitor contains at least two electrical conductors separated by an insulator (dielectric). When an electric field develops across the insulator, it stops the flow and an electric charge is starting to build up on the plates.
can find all types of capacitors ranging from small capacitor beads found in resonance circuits to high power correction capacitors used for large scale operations.
A capacitor basically consists of two or more metal plates which are not connected to each other but are electrically separated by a non-conducting substance such as ceramic, porcelain, cellulose, mica, Teflon, etc.
The dielectric generally dictates what type of capacitor it is and for what it can be used ideally. While some capacitors are ideal for high frequency operations, while some are best suited for high voltage applications.
ADP Motor Run Capacitors
ADP (Metalized Polypropylene) motor run capacitors are compact, self-healing products that find greatest utilization as motor-run capacitors in fractional horsepower electric motors. However, the motor run capacitors may be used in a wide variety of 50/60 Hz. AC or DC applications.
The motor run capacitors are available in capacitances up to 30 microfarads and with voltage ratings of 250, 370, and 440 VAC. The metalized polypropylene film dielectric provides excellent electrical characteristics including stable capacitance over time and temperature and a very low Dissipation Factor (internal heating).
The motor run capacitors’ integral mounting ear makes it an excellent choice for difficult to mount applications and the choice of terminal configurations is another big plus. Terminal configuration includes single or double 0.187 or 0.250 spade terminals fast-on, insulated wire leads, or PC-mount pins. ADP motor run capacitors can be supplied with a “lay-down” type bracket which provides additional mounting options. Other options available include P2 protected segmented film (ADP series).
ADP motor run capacitors offer UL, cUL, VDE, TUV, and CE approvals available. All ADP motor run capacitors are also RoHS compliant.
A capacitor basically consists of two or more metal plates which are not connected to each other but are electrically separated by a non-conducting substance such as ceramic, porcelain, cellulose, mica, Teflon, etc.
The dielectric generally dictates what type of capacitor it is and for what it can be used ideally. While some capacitors are ideal for high frequency operations, while some are best suited for high voltage applications.
Difference between Capacitor and Battery
- Definition of Capacitor and Battery – While a battery stores its potential energy in the form of chemical reactions before converting it into electrical energy, capacitors store potential energy in an electric field. Unlike a battery, a capacitor voltage is variable and is proportional to the amount of electrical charge stored on the plates.
- Application of Capacitor and Battery – A battery can usually store a larger amount of electrical charge, while a capacitor, on the other hand, are capable of handling high voltage applications and ideal for high frequency uses.
- Charge/Discharge Rate of Capacitor and Battery – The rate at which a capacitor is able to charge and discharge is usually faster than what a battery is capable of because a capacitor stores the electrical energy directly onto the plates. The process gets delayed a bit in case of a battery due to the chemical reaction involved while converting chemical energy into electrical energy.
- Energy Storage of Capacitor and Battery – While both electronic devices are used to store electrical energy, the way they do vary dramatically. A battery stores electrical energy in the form of chemical energy, while a capacitor stores electrical energy in a magnetic field. This is why batteries store a lot of charge but they charge/discharge very slowly.
- Polarity of Capacitor and Battery – The polarity of the electronic circuit must be reverse while charging a battery, while it must be same as it is supposed to be while using in case of a capacitor. A battery maintains a constant voltage flow across the terminals and it is discharged only when the voltage goes down.
Capacitor vs. Battery : Comparison Table
Battery | Capacitor |
A battery stores its potential energy in the form of chemical energy. | A capacitor uses electrostatic field to store electrical energy. |
It has a better energy density which means more energy per volume can be stored. | It has a comparatively low energy density than a battery. |
It is basically a DC component. | It is ideally used for AC applications. |
Charge/discharge rate is relatively slower than capacitors. | Charge/discharge rate is usually faster than a battery because it stores energy directly onto the plates. |
Charges are not separated in a battery. | Electrons are pre-stocked in capacitors. |
Battery runs for a longer time. | Capacitors discharge almost instantaneously. |
Summary points on Capacitor and Battery
Both batteries and capacitors are electronic devices capable of storing electrical charge and they seem awfully similar as they both release electrical energy. However, the way they do it vary dramatically. While a battery stores potential energy in the chemical form, a capacitor stores its potential energy in an electrostatic field. In simple terms, batteries store and distribute energy in a linear form – like a constant electrical flow. Capacitors, on the other hand, distribute energy in short bursts. A capacitor stores energy directly onto the plates which makes charging/discharging a bit faster than batteries. However, batteries are capable of regaining their stored energy much efficiently and for a longer duration than capacitors.ADP Motor Run Capacitors
ADP (Metalized Polypropylene) motor run capacitors are compact, self-healing products that find greatest utilization as motor-run capacitors in fractional horsepower electric motors. However, the motor run capacitors may be used in a wide variety of 50/60 Hz. AC or DC applications.
The motor run capacitors are available in capacitances up to 30 microfarads and with voltage ratings of 250, 370, and 440 VAC. The metalized polypropylene film dielectric provides excellent electrical characteristics including stable capacitance over time and temperature and a very low Dissipation Factor (internal heating).
The motor run capacitors’ integral mounting ear makes it an excellent choice for difficult to mount applications and the choice of terminal configurations is another big plus. Terminal configuration includes single or double 0.187 or 0.250 spade terminals fast-on, insulated wire leads, or PC-mount pins. ADP motor run capacitors can be supplied with a “lay-down” type bracket which provides additional mounting options. Other options available include P2 protected segmented film (ADP series).
ADP motor run capacitors offer UL, cUL, VDE, TUV, and CE approvals available. All ADP motor run capacitors are also RoHS compliant.
Technical Specifications | |
---|---|
Capacitance | 0.12 ~ 30 uF (±5%) |
Rated Voltage | 250 ~ 440 VAC |
Frequency | 50/60 Hz |
Dissipation Factor | ≤ 0.002 (100 Hz) |
Operating Temperature | -25 ~ +85 °C |
Dielectric Material | Metalized Polypropylene |
Case Material | Flame Retardant Plastic (UL94 V-0) |
Terminal Configurations | ||
---|---|---|
(t) | TERMINAL STYLE | IMAGE |
A | Single AMP.187 Fast-On | |
C | Double AMP.187 Fast-On | |
E | Single AMP.250 Fast-On | |
F | Double AMP.250 Fast-On | |
M | Insulated Wire Leads | |
S | PC-mount Pins |
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