The discussion revolves around the behavior of current in a series R-L circuit that incorporates superconductive components, specifically focusing on the time it takes for current to build up after the power is turned on. Participants explore various aspects of inductance, resistance, and the implications of using superconductors in this context.
Participants express differing views on the role of resistance, the nature of the power source, and the implications of high-frequency effects. The discussion remains unresolved, with no consensus on the time constant or the impact of various factors on current build-up.
The discussion highlights the complexity of the circuit's behavior, including the influence of geometry on radiation resistance and the potential for differing resonances within the circuit components. Assumptions about ideal conditions and the nature of the power source are also noted as limitations in the analysis.
Why are you putting a resistor in series with a superconducting inductor? That kind of defeats the purpose, no?Karmyogi01 said:TL;DR Summary: Inductance of a superconductive coil
For a series R-L circuit that uses superconductive components, how long would it take for current to build up after the power is turned on?
There is no resistor in series. All components are superconductive. R is vanishingly smallberkeman said:Why are you putting a resistor in series with a superconducting inductor? That kind of defeats the purpose, no?
I am assuming an ideal power source with zero impedance for clarity. However, the fundamental logic will not change even if it were not an ideal power source.berkeman said:What is the source impedance of the power supply that you are using to build the current? How is it connected to the superconducting coil?
For a series circuit the power supply is connected in series.Karmyogi01 said:I am assuming an ideal power source with zero impedance for clarity. However, the fundamental logic will not change even if it were not an ideal power source.
Good insight indeed! However, here we do not have the high frequency situation.Dale said:The time constant will depend on the radiation resistance of the superconductor. Superconductors have no resistance at DC, but at high frequencies they do have resistance and effective resistance.
Are you sure? The idealized version of "the power is turned on" is a step-function in time, which contains Fourier components with arbitrarily high frequency.Karmyogi01 said:Good insight indeed! However, here we do not have the high frequency situation.
As @renormalize mentioned, you have arbitrarily high frequencies for switching on an ideal source.Karmyogi01 said:Good insight indeed! However, here we do not have the high frequency situation.
The series R+L will need a return circuit, that has not yet been defined.Karmyogi01 said:For a series R-L circuit that uses superconductive components, how long would it take for current to build up after the power is turned on?
The radiation resistance is supposed to be very small and does not change the logic in a fundamental way. The time constant (TC) does not match what we observe. In addition, the question is not constrained to only an ideal power source.renormalize said:Are you sure? The idealized version of "the power is turned on" is a step-function in time, which contains Fourier components with arbitrarily high frequency.
Karmyogi01 said:the question is not constrained to only an ideal power source
Hmmm.Karmyogi01 said:I am assuming an ideal power source
What makes you think that? Do you have a reference that shows an experiment where it doesn’t match?Karmyogi01 said:The time constant (TC) does not match what we observe.
As stated above, I mentioned "ideal source" for the sake of clarity only and mentioned already that we do not necessarily have to assume that. I stated this already. To answer your question regarding TC, please tell me your estimate of "radiation resistance."Dale said:Hmmm.
What makes you think that? Do you have a reference that shows an experiment where it doesn’t match?
Who is "we"? If we knew the actual application, that would help us to focus our responses.Karmyogi01 said:As stated above, I mentioned "ideal source" for the sake of clarity only and mentioned already that we do not necessarily have to assume that.
This depends on the geometry but is typically in the range of 50 to 300 ohms.Karmyogi01 said:, please tell me your estimate of "radiation resistance."
Sorry but that doesn't make sense. If you have a circuit comprising only 'ideal' elements then you can draw no valid conclusions about how it will behave. If you say that the radiation resistance is very small then it will still be the highest value resistance in the circuit so it will, in fact be very big and it will be the resistance that determines the time constant.Karmyogi01 said:The radiation resistance is supposed to be very small and does not change the logic in a fundamental way. The time constant (TC) does not match what we observe. In addition, the question is not constrained to only an ideal power source.
What does that mean? There will be an exponential change as with any other 'time constant' (that's a definition of time constant). I'm afraid you're going round in circles with this argument. An example of where the time constant is frequently measured. Charging up a superconducting magnet takes many hours or even days (google time to switch on a superconducting magnet). That's a practical application for your question.Karmyogi01 said:in an almost linear fashion
Karmyogi01 said:The time constant (TC) does not match what we observe.
You keep pointing to contrary "observations". To support that claim, please cite a scholarly reference that exhibits what is observed experimentally for the configuration you are discussing.Karmyogi01 said:This is contrary to our observations!
That's not what I said. Please read the whole post. Your first paragraph states the obvious!sophiecentaur said:Sorry but that doesn't make sense. If you have a circuit comprising only 'ideal' elements then you can draw no valid conclusions about how it will behave. If you say that the radiation resistance is very small then it will still be the highest value resistance in the circuit so it will, in fact be very big and it will be the resistance that determines the time constant.
What does that mean? There will be an exponential change as with any other 'time constant' (that's a definition of time constant). I'm afraid you're going round in circles with this argument. An example of where the time constant is frequently measured. Charging up a superconducting magnet takes many hours or even days (google time to switch on a superconducting magnet). That's a practical application for your question.
The physical arrangement of the circuit components will be important. You have not described the complete circuit. Depending on the construction of the inductor, you may have a slow-wave structure that ignores the bulk inductance.Karmyogi01 said:We can expect the current to rise at a rate of about (V/L) amps/sec. in an almost linear fashion (initially) and take almost forever to reach its final value. This is contrary to our observations!
Ramping up a MRI magnet is almost linear, it takes a few hours which is not almost forever, and I don’t see what you think is contrary to what in any of that.Karmyogi01 said:in an almost linear fashion (initially) and take almost forever to reach its final value. This is contrary to our observations!
Thanks for making my point! Yes, “hours” is not forever! However, the analysis says times required are likely to be much longer than that. I am calling it a “paradox” and NOT a contradiction. I believe there is an explanation, but the discussion here has not yet yielded the resolution! Following your advice, I will try to post a scientific paper. I honestly appreciate the valuable inputs from all. Please, stay tuned! I expect to find the resolution soon and post it here.Dale said:Ramping up a MRI magnet is almost linear, it takes a few hours which is not almost forever, and I don’t see what you think is contrary to what in any of that.
You are making random assertions of some contradiction, please post the professional scientific reference that describes the actual observations you are discussing. So far it just seems like your unfounded opinion
What analysis? All I have seen is your unfounded assertions to that effect.Karmyogi01 said:However, the analysis says times required are likely to be much longer than that.
Indeed. Please do.Karmyogi01 said:Following your advice, I will try to post a scientific paper. I honestly appreciate the valuable inputs from all. Please, stay tuned! I expect to find the resolution soon and post it here.
If you measure a linear ramp then the source impedance must be designed to be constant current. No problem but one can't draw conclusions about a circuit where 'R' varies.Dale said:Ramping up a MRI magnet is almost linear, it takes a few hours which is not almost forever, and I don’t see what you think is contrary to what in any of that.
Agreed. You could design circuits with a superconducting component and a long time constant and you could design circuits with a superconducting component and a short time constant. So this personal-opinion-in-place-of-evidence approach is not a sound basis on which to claim a contradictionsophiecentaur said:It would be nice to be given the full story from the OP - with some evidence and a description of the system.
When there's any implied claim about a paradox, one has to be skeptical
Yes - merely by increasing the source resistance but there's a lot of energy stored in a big magnet and you would want an efficient charging system which would not be a simple resistive source (with I squared R losses) . So the term should be something like "charge time" and not "time constant".Dale said:You could design circuits with a superconducting component and a long time constant