f_n= c/(2*pi*r) * sqrt(n(n+1))

f_n = (n * c_l)/ 2L

c_l / (4 * r) = c_t / (2 * pi * r) * sqrt(6)

c_l = 2/pi * sqrt(6) * c_t

Eric suggested more authors to study. He said look up the work of Helmholtz, "Sensations of Tone" (This seems to give insight into Eric's understanding of the music/electric relation) and that Helmholtz gave the equations for longitudinal transmission. Also Tesla liked Helmholtz. He also said to study everything by J.J. Thomson, especially "Experimental Researches into Electricity and Magnetism" (The only thing that I could find was "Elements of the mathematical theory of electricity and magnetism", maybe this is what he meant?).

The Helmholtz resonator is a narrow-bandwidth device, designed and used to target specific single frequency anomalies. The margin for design or constructional error, therefore, is minimal. One area often overlooked is that of port end-correction, without which a design may be rendered ineffective. Basically speaking, the air immediately outside either end of the port acts in sympathy with the design air mass in the port. This has the effect of increasing the apparent length of the port (fig1), and hence affects the tuning frequency of the resonator.

In order for the waves to travel with low loss, the pipe dimensions must be large enough for the lowest-order waveguide mode, the TE 11 mode, to propagate. In circular waveguide, the cutoff wavelength for this mode is 1.706×D (diameter) so the minimum waveguide diameter is 1/1.706, or 0.59 λ. The diameter of the copper water pipe I used is nominally 3/ 4-inch, type M, which has a larger inner diameter than other types. The typical inner diameter is 0.81 inches, but that may vary slightly because this is not precision tubing. Thus, the cutoff wavelength is 1.38 inches, so the minimum frequency is 8.55 GHz. Clearly, 10 GHz is comfortably above the minimum.

Moving in the other direction, a large waveguide diameter would permit additional higher-order waveguide modes to propagate. While the additional modes also propagate with low loss, they often arrive at the far end with different phase, so that they interfere with the TE11 wave and we are unable to extract them without losses. The next mode, TM 01, needs a minimum diameter of 0.76 λ to propagate, setting the maximum operating frequency without any additional modes. For the 3/4-inch pipe, this upper frequency limit is 11.08 GHz, but it isn’t a hard limit like the lower cut-off frequency.

Open cylindrical tubes resonate at the approximate frequencies
where n is a positive integer (1, 2, 3...) representing the resonance node, L is the length of the tube and v is the speed of sound in air (which is approximately 343 meters per second at 20 °C and at sea level).

Since it cannot be shielded by metal or even dielectric material, why do you think you can feed a dish with a spherical termination and reflect it, concentrated, to the moon? Why do you think it will be reflected by the moon? Two big problems to my thinking.

Instantaneous applications of high current and high voltage could literally convert thin wires into vapor. Charged to high direct current potentials, his capacitors were allowed to discharge across a section of thin wire. Tesla configured his test apparatus to eliminate all possible current alternations. The application of a single switch contact would here produce a single, explosive electrical surge: a direct current impulse resembling lightning.

[...]

Placing a large glass plate between himself and the exploding wire, he performed the test again. Bang! The wire again turned to vapor...but the pressured stinging effect was still felt. But, what was this? How were these stinging effects able to penetrate the glass plate? Now he was not sure whether he was experiencing a pressure effect or an electrical one. The glass would have screened any mechanical shrapnel, but would not appreciably shield any electrical effects.

Through careful isolation of each experimental component, Tesla gradually realized that he was observing a very rare electrical phenomenon. Each "bang" produced the same unexpected shock response in Tesla, while exploding small wire sections into vapor. The instantaneous burst produced strange effects never observed with alternating currents. The painful shocking sensation appeared each time he closed or opened the switch. These sudden shock currents were IMPULSES, not alternations. What surprised him was the fact that these needle-like shocks were able to reach him from a distance: he was standing almost ten feet from the discharge site!

[...]

The secret lay principally in the direct current application in a small time interval. Tesla studied this time increment, believing that it might be possible to eliminate the pain field by shortening the length of time during which the switch contact is made. In a daring series of experiments, he developed rapid mechanical rotary switches, which handled very high direct voltage potentials. Each contact lasted an average of one ten-thousandth second.

Exposing himself to such impulses of very low power, he discovered to his joy and amazement that the pain field was nearly absent. In its place was a strange pressure effect, which could be felt right through the copper barriers. Increasing the power levels of this device produced no pain increase, but did produce an intriguing increased pressure field. The result of simple interrupted high voltage DC, the phenomenon was never before reported except by witnesses of close lightning strokes. This was erroneously attributed however to pressure effects in air.

[...]

Analysis of this situation proved that electrical energy or electrically productive energies were being projected from the impulse device as rays, not waves. Tesla was amazed to find these rays absolutely longitudinal in their action through space, describing them in a patent as "light-like rays". These observations conformed with theoretical expectations described in 1854 by Kelvin.

In another article Tesla calls them "dark-rays", and "rays which are more light-like in character". The rays neither diminished with the inverse square of the distance nor the inverse of the distance from their source. They seemed to stretch out in a progressive shock-shell to great distances without any apparent loss.

As far back as 1897, I disclosed before the New York Academy of Sciences the discovery that Roentgen, or X-rays, projected from certain bulbs have the property of strongly charging an electrical condenser at a distance.

I have disintegrated atoms in my experiments with a high potential vacuum tube I brought out in 1896 which I consider one of my best inventions. I have operated it with pressures ranging from 4.000.000 to 18.000.000 volts. More recently I have designed an apparatus for 50.000.000 volts which should produce many results of great scientific importance.

But as to atomic energy, my experimental observations have shown that the process of disintegration is not accomtpained by a liberation of such energy as might be expected from the present theories.

And as for the cosmic ray: I called attention to this radiation while investigating Roentgen rays and radioactivity. In 1899 I erected a broadcasting plant at Colorado Springs, the first and only wireless plant in existence at that time, and there confirmed my theory by actual observation, My findings are in disagreement with the theories more recently advanced.

I have satisfied myself that the rays are not generated by the formation of new matter in space, a process which would be like water running up hill. According to my observations, they come from all the suns of the universe and in such abundance that the part contributed by our own sun is very insignificant by percentage. Some of these rays are of such terrific power that they can traverse through thousands of miles of solid matter.

Eric suggested more authors to study. He said look up the work of Helmholtz, "Sensations of Tone" (This seems to give insight into Eric's understanding of the music/electric relation) and that Helmholtz gave the equations for longitudinal transmission. Also Tesla liked Helmholtz. He also said to study everything by J.J. Thomson, especially "Experimental Researches into Electricity and Magnetism" (The only thing that I could find was "Elements of the mathematical theory of electricity and magnetism", maybe this is what he meant?).

The skin depth is essentially the wave length in the metal. The main thing to notice are that the free space wave length is enormously larger than the skin depth.