Inducing a current through moving charges or electromagnetic radiation

Click For Summary

Discussion Overview

The discussion revolves around the concept of electromagnetic induction, particularly in the context of radio signals and the potential for inducing current through various means, including charged particles and electromagnetic waves. Participants explore the mechanisms of induction, the characteristics of antennas, and the implications of different frequencies on induced currents.

Discussion Character

  • Exploratory
  • Technical explanation
  • Debate/contested
  • Conceptual clarification

Main Points Raised

  • Anna inquires whether a circuit schematic for picking up radio signals without a battery exemplifies electromagnetic induction and questions the induced voltage and current levels.
  • Some participants suggest that while a crystal radio might not be a classic example of induction, it can involve induction if a loop antenna is used.
  • Discussion includes the interaction of radio waves with antennas, noting that the design of the antenna affects how the radio wave induces current.
  • Anna asks for specifics on the voltage and current generated in a crystal radio receiver, with one participant indicating it depends on the radio signal strength and antenna gain, typically measured in microamperes.
  • Anna questions whether a stream of charged particles can induce current in a coil, with responses indicating that a steady stream would not induce current unless it creates a varying magnetic field.
  • There is a proposal that varying the charge density or speed of charged particles could induce voltage/current, leading to further exploration of conditions required for induction.
  • Anna raises the question of whether induction is limited to radio waves or if other frequencies like IR, visible light, X-rays, and gamma rays can also induce current, with some noting that quantum effects become significant at smaller wavelengths.
  • Concerns are expressed about how Tesla could light bulbs with induced current from electromagnetic waves, with suggestions that he must have used a significant amount of power.
  • Participants discuss the breakdown of classical electrodynamics at quantum levels and whether induction operates on groups of atoms rather than individual particles.

Areas of Agreement / Disagreement

The discussion contains multiple competing views regarding the nature of electromagnetic induction, the conditions under which it occurs, and the implications of different frequencies. There is no consensus on several points, particularly regarding the specifics of induction mechanisms and the role of quantum effects.

Contextual Notes

Participants acknowledge limitations in their understanding of the specifics of induction, including the dependence on antenna design, signal strength, and the nature of the electromagnetic waves involved. There are unresolved questions about the mathematical relationships governing induced currents.

mavc
Messages
17
Reaction score
0
I have recently found a circuit schematic that can pick up radio signals without the need of a battery.

Is this an example of electromagnetic induction? If so, how much voltage/current is induced?

Does it change the properties of the electromagnetic wave, e.g. energy, wavelength, etc?

Thanks,
Anna.
 
Physics news on Phys.org
If it is a crystal radio, it is not what we would call induction but technically yes it might be.

The term Induction usually refers to processes ocurring around nearby arrangements of conductors and/or magnets. Examples are motors and electric transformers.

If the radio uses a loop antenna then technically it is receiving via induction. If the antenna is not a loop then you would not call it induction.
 
mavc said:
I have recently found a circuit schematic that can pick up radio signals without the need of a battery.

Is this an example of electromagnetic induction? If so, how much voltage/current is induced?

Does it change the properties of the electromagnetic wave, e.g. energy, wavelength, etc?
Sounds like a crystal radio receiver.

The way the radio wave interacts with an antenna depends on the design of the antenna. The time dependent magnetic field component of the radio wave can induce a current in the antenna. Or the time dependent electric field component of the radio wave can cause current oscillations in the antenna.

Antennas can be complicated. You would need to know particular details of the antenna, and the radio signal to determine the strength of the signal in the antenna and how it interacts with the radio wave.

AM
 
Thank you both for your replies.

In the project details, it says that the antenna is just a really long wire. Do you have further details on the amount of voltage & current generated in the crystal radio receiver?

I forgot the second half of my question - is it possible to induce a current in a coil via a stream of charged particles (i.e. electrons or protons) traveling in a straight line through the coil?

Regards,
Anna.
 
mavc said:
Thank you both for your replies.

In the project details, it says that the antenna is just a really long wire. Do you have further details on the amount of voltage & current generated in the crystal radio receiver?
It depends on the strength of the radio signal and the gain of the antenna and other technical details. It will be measured in microamperes.

I forgot the second half of my question - is it possible to induce a current in a coil via a stream of charged particles (i.e. electrons or protons) traveling in a straight line through the coil?
No. A steady current creates a steady magnetic field. You need a time dependent magnetic field to create an induced emf (Faraday's law: [itex]\text{Emf} = d\phi/dt[/itex]

AM
 
Hi AM,

Thanks for the info on induction in an antenna.

With the moving stream of particles, what if the charge density was changing/oscillating over time? Would that induce a voltage/current?

Thanks,
Anna.
 
Say you send a bunch of charged particles trough a coil. Such a bunch would generate a varying magnetic field, thus there would be an induced emf.
 
Thanks Gordianus.

If I need the charged particles to go in a straight line, what other options do I have to be able to induce an emf?

And is there an equation predicting how much voltage/current will be induced?

Regards,
Anna.
 
mavc said:
Thanks Gordianus.

If I need the charged particles to go in a straight line, what other options do I have to be able to induce an emf?
If you vary the number of charged particles per unit time or if you vary the speed of the charged particles the current will not be constant. You need a time dependent current to create a time dependent magnetic field, which will then create an induced emf.

And is there an equation predicting how much voltage/current will be induced?
The induced emf is determined by Faraday's law. The induced current depends on the circuit (eg. resistance) you are using.

AM
 
  • #10
Thanks AM.

Going back to the question about electromagnetic induction, is it limited to radio waves or can other frequencies like IR, visible light, x-rays and gamma rays induce a current?

Regards,
Anna.
 
  • #11
Hi again,

If the current induced from electromagnetic waves is in the order of microamperes, how did Tesla light up few hundred watts of light bulbs kilometres away?

Thanks,
Anna.
 
  • #12
mavc said:
Thanks AM.

Going back to the question about electromagnetic induction, is it limited to radio waves or can other frequencies like IR, visible light, x-rays and gamma rays induce a current?
For very small wavelengths, quantum effects become important. Some light as well as Xrays and gamma rays interact with individual particles (e.g. atoms, electrons) and classical electrodynamics (of which induction is a part) starts to break down.

AM
 
  • #13
mavc said:
Hi again,

If the current induced from electromagnetic waves is in the order of microamperes, how did Tesla light up few hundred watts of light bulbs kilometres away?
He must have used an enormous amount of power.

AM
 
  • #14
Andrew Mason said:
For very small wavelengths, quantum effects become important. Some light as well as Xrays and gamma rays interact with individual particles (e.g. atoms, electrons) and classical electrodynamics (of which induction is a part) starts to break down.

AM

Then how does induction work? I would have thought that the explanation would be at a quantum level too, in terms of photons interacting with electrons?

Regards,
Anna.
 
  • #15
mavc said:
Hi again,

If the current induced from electromagnetic waves is in the order of microamperes, how did Tesla light up few hundred watts of light bulbs kilometres away?

Thanks,
Anna.

Fortunately, the outcome of Tesla’s tests were more of an inconvenience than a cataclysmic world-ending event. Well, depending on your perspective anyway. The area around his experiement became electrified, but not enough to kill anyone, and there were some very impressive bolts of man-made lightning which stopped when he blew up the town’s generator and caused a blackout over several miles. There might have been one other small side effect. At almost exactly the same time that this experiment was taking place, a mysterious explosion rocked a remote section of Siberia, to the tune of about a 15-megaton blast (40 years before the first Atomic Bomb test).
 
  • #16
AM, thinking about it a little more, is it possible that induction works on groups of atoms rather than atoms themselves, in the same way that diffraction needs planes of atoms to work?

Quinzio, that's an interesting story. How did he electrify the area around him? Is it related to the Earth's resonant frequencies, or is it to do with wireless em induction?

Thanks,
Anna.
 

Similar threads

Graduate Voltage and current waves in a transmission line
  • · Replies 4 ·
Replies
4
Views
3K
Undergrad DIY Electromagnetic Induction Experiment
  • · Replies 2 ·
Replies
2
Views
3K
Graduate Help understanding the electromagnetic radiation; mainly near field.
  • · Replies 9 ·
Replies
9
Views
3K
Graduate Electromanetic radiation induce electrical current in neuron and create dream
  • · Replies 2 ·
Replies
2
Views
3K
High School Is the Kink in the Electromagnetic Wave Responsible for Delayed Motion?
  • · Replies 8 ·
Replies
8
Views
2K
High School Experiment issues (electromagnetism)
  • · Replies 42 ·
2
Replies
42
Views
4K
Graduate Can a solenoid emit/receive electromagnetic radiation?
  • · Replies 6 ·
Replies
6
Views
10K
Undergrad Doubts regarding Electromagnetic fields
  • · Replies 9 ·
Replies
9
Views
2K
Undergrad Mutual inductance in a transformer
  • · Replies 16 ·
Replies
16
Views
5K
Undergrad Can current be induced in a uniform magnetic field?
  • · Replies 5 ·
Replies
5
Views
7K