This initial rapid fall-off you see on your slopes -- it's not skin-effect. When you excite your target, circulating currents can flow in any which direction they like. Those that go in tight loops, because they are constrained by a thin sheet, or a wires' edge-profile etc, decay quicker. What's left later on are the 'big' circulating loops, whose size is related to the larger dimensions of the target. It's nothing to do with skin effect.
Remember that pdf Eric linked to, about the test jig that measured long rods of metal decaying ? The maths of that showed the multiple decays, and then stated that the 'big' one is the one they want to measure and analyse. It involved Bessell Functions, which are called upon when things happen in two (or three) dimensions ... vibrating drumskins? heat transfer through a solid? Digital filtering of images? I've little exposure to their intricacies ...

Skin effect is something really relevant to continuous AC signals, like a VLF detector, or 60Hz/50Hz power line currents. The currents only flow in the outermost layer of the item. At microwave freqs, it's just the skin, microns thick that conducts, nothing at all goes on in the core of a wire, it could be a tube, with no difference. You don't see 'the effect of the skin' , it's always there, it doesn't 'show itself' under any particular given circumstance.

[ I hope all that is correct, I don't want to have to ask Carl to edit/delete it..]

Re: your turn-on / off measurement differences. What's different about the circuit? An I correct in saying the damping is different between the two states, one is damped by a resistor, typically 500 Ohms, the other will be a near-zero Ohm turned-on Mosfet ?

Another test. When I tested the 19mm length wires the other day I noticed orientation didn't seem to make much difference. Tested 3 wire sizes and a US nickel. Can get a lot different slopes with the nickel. Wondering if you see much change with 19mm of copper wire with the VLF.

I measured 10 nickels on the conductivity meter ranging in dates from 1964 - 1997 and they all read 5.xx% IACS. The lowest is 5.22 and the highest 5.63%. Doing a quick test for TC the difference appears to account for about 1uS between the two. Further tests still to to be done on the quarter.

Eric.

Another test. When I tested the 19mm length wires the other day I noticed orientation didn't seem to make much difference. Tested 3 wire sizes and a US nickel. Can get a lot different slopes with the nickel. Wondering if you see much change with 19mm of copper wire with the VLF.

"Did you mean 1.95mm?"
No, I meant 1.59mm, based on calculation (density/mass/diameter). The 'official' thickness is what you would get if you stuck vernier calipers on it, and it's probably the thickness of the edge, rather than any inner feature. I calculate the mean thickness of all my coins that I've tested, there's no other way to come up with anything accurate, even mic'ing various points across the surface will give figures in error.
"Thinking flat is one 1inch diameter loop."
Roughly, yes. I reckon that it's bigger, I'm pretty sure the currents do flow into the corners quite a bit, the most obvious effect of this is to give a stronger response. The time-constant doesn't vary that much, as, in simple L & R terms, the R maybe increases 15%, but the loop length of the 'inductor' goes up by a similar amount, so it's the subtleties of inductance varying with the ratio of (loop radius to wire radius), and some minor adjustments related to resistivity that change TC.
"On edge is four 0.25" diameter loops side by side?"
It seems reasonable, though I don't see why they couldn't overlap? And they'll probably be squashed circles, constrained by the 0.25" dimension.
"Does that mean there are smaller faster loops somewhere?"
Initially there could be countless billions of microscopic loops, but they'll presumably decay or combine in some fashion over time.

Hi Green, Here is the graph for a US quarter that I promised. The figures were taken off my later MK2 instrument and I plotted them on a log/lin scale which is what you use. 30uS is the earliest start time although this could be reduced by mods to the clock generator. From 30uS until 100uS you can see the departure from the single exponential due to the 'diffusion' process.

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Eric.

Green: Do you think it's possible your O-8 coil is responsible for the discrepancies? You don't really have a 'central' position, where fields are symmetrical. Above the centre of one half of your 8-RX, you are not in the middle of the O-TX .

Hi Eric, thanks for charting the US clad quarter. I see we don't get the same decay, wonder why. Including the chart I posted reply#164. I had 137us vs 115us TC you got? My data is higher than straight line projection in the beginning where your data is lower?

I thought it would be interesting to measure the TC on the raw signal out of the preamp. According to this we are both out in our instruments. The cursor measurement gives 122.9uS for the TC. It is not easy to set the cursors to the nearest mV on the y scale I used, so there will still be a very small error. I started the measurement at 100uS as this seems to be the start point for the straight line decay. My TX width at 100uS delay is 300uS which appears to be a bit short. TX for 99% target energisation should be 5 x TC, or > 600uS say. If I took a starting measurement at 200uS delay, then I would have a 600uS TX width. I can begin to see the change in amplitude of the RX waveform for a US quarter when I reduce the TX width to 570uS. My TX width is always 3 x the sample delay, e.g. at 500uS delay the TX is 1500uS. The repetition rate drops in proportion and current draw stays the same. TX current flat tops at 250mA.

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Eric.