April 2027, Liangguo Rocket City
Professor Braun is more than ten years older than David Halsey, but David is obviously more experienced in intelligence analysis.
On May 25, the crisis was approaching. Apart from the demonstrative hints of the Yuhan people, there were almost no other clues, and the entire investigation was at a deadlock.
David is not so anxious anymore. Years of experience tell him that the closer the time is, more new clues will emerge by themselves, and what he can do now is to sort out the information that may have been missed again.
He and Professor Braun carefully looked through the files on the kidnapping case page by page, and the two of them stopped at the enlarged photo of the metronome.
"I think the frequency corresponding to the five scales on the metronome is the key to the problem. Can you tell me more about it?" David stared at the five scales, which are: 30, 60, 240, 245, and 470.
"David, I'm worried about you too. What issues in these frequencies are you concerned about?" Professor Braun asked worriedly.
"You told me before that Tesla calculated the wavelength of ultra-light waves to be 170,360 kilometers. How did he calculate it? Did he use these frequencies?" David asked.
Professor Braun nodded in affirmation.
All objects in nature, as large as the sun, as small as jelly beans, and even the human body itself, radiate energy in the form of electromagnetic waves all the time.
Radiation is described from the perspective of frequency and wavelength. The radiation of any natural object has a wavelength range from 0 to infinity. Correspondingly, the frequency range is also from 0 to infinity. The professional terms are full-band and full-frequency band.
However, due to the different surface temperatures of objects, there is a peak frequency and a peak wavelength in its full-band and full-band radiation.
It is easier to describe and refer to a radiation event using peak frequency and peak wavelength.
When physicist William Wien was studying the problem of blackbody radiation, he experimentally discovered that the peak frequency and peak wavelength are related to the blackbody surface temperature. The formula he gave is the famous Wien's displacement law.
The product of the peak wavelength and the blackbody surface temperature is a constant.
That is, λmax T=b=0.00289777 m∙K.
This law can also be expressed in frequency form:
That is, fmax/T=5.879×10^10 Hz·K^-1.
For the same black body, according to Wien's displacement law, the calculated peak frequency and peak wavelength cannot be directly multiplied. The product does not follow the formula that wavelength multiplied by frequency equals the speed of light, because they do not belong to the same wave.
When Nikola Tesla was thinking about the wavelength of super-light waves, the upper limit of his estimate was the diameter of the smallest star that has been observed, which is about 180,000 kilometers, and the lower limit is larger than the diameter of Jupiter, which is about 145,000 kilometers, but the exact value is how much?
By 1936, the year Tesla wrote the relevant paper, physicists had already studied electromagnetic waves very deeply.
But Tesla believes that we still know nothing about the nature of super-light waves. Is the super-light wave itself a full-band radiation or is it like background radiation with only a single frequency? Will it be reflected when it hits a star?
In addition to the frequencies above 10 16 Hertz, is it possible for the frequency of this reflection to cause the object's own electromagnetic wave radiation to produce an extremely low-frequency radiation in response to the unit wavelength of the super-light wave?
Records show that Tesla showed great interest in extremely low frequencies. He once dug a one-meter-deep mud pit on the dirt floor of a cafe in Nidu and used a homemade iron rod-shaped pole. Low frequency transmitters emit extremely low frequency waves into the ground.
Reporters around Tesla witnessed and recorded this experiment, which resulted in an earthquake of magnitude 3 or above in Nidu!
Wien's displacement law was originally an empirical formula. Later, Planck introduced the light particle hypothesis and proposed and proved Planck's black body radiation law.
Wien's displacement law is proved because it is a special case of Planck's law. Planck postulated that light has particle nature, and the energy of each photon is the same, which is defined as h and is called Planck's constant.
Tesla thought about why Planck's constant is a constant and where the energy in photons comes from. This has become a question that modern physics cannot ask deeply.
It is precisely based on this assumption and actual measurement results that the two corresponding constants of Wien's displacement law are verified. Why can't these two constants be multiplied?
What is the physical meaning of multiplication? Of course their product is also a constant. Is the starting point of the entire logic related to the wavelength of the hyperlight wave?
So Tesla broke with the rules and simply multiplied the two constants of Wien's displacement law.
That is 5.879×10^10 Hz∙K^-1×0.00289777 m∙K=170360 km∙Hz.
If the super-light wave has such a property, that is, when it is incident on a star, a complete wavelength will correspond to the star not only radiating electromagnetic waves in the full frequency range, but also corresponding to an electromagnetic radiation with a frequency of 1 Hz, then the wavelength of the super-light wave is 170360 kilometers.
In an astronomy paper studying the cross-system resonance of planets and satellites, it was mentioned that it is unknown what force determines it. The semi-major axes of the 269 satellites discovered in the solar system are distributed in a band, with the "best position" distance in the middle Occupied by the top ten satellites in diameter.
Since large satellites will occupy "good positions", the satellite with the largest mass and diameter in the solar system is Ganymede, with its semi-major axis being 1,070,400 kilometers.
Will the biggest take the “best” spot?
If the "optimal" distance for Ganymede's stable orbit is not accidental, but is determined by super-light waves.
So is it possible that the semi-major axis of Ganymede is exactly equal to the circumference of a circle with the superlight wavelength as the radius?
That is 1070400 km/2π=170359.5 km.
The wavelength of the super-light wave calculated based on this is also 170360 kilometers.
What's even more coincidental is that the speed of any beam of light in vacuum is 299,792,458 meters. The wavelength of this beam of light is the peak wavelength of the beam, multiplied by the corresponding frequency of the peak frequency.
That is, the speed of light divided by 170360km·Hz is a constant, equal to 1.7597585.
The orbital base of Callisto is equal to 1, which is the most important dividing line for the satellites of the solar system. Its semi-major axis is also related to the wavelength of super-light waves?
The semi-major axis of Callisto is 1,882,700 kilometers, which is 1.758875 times the semi-major axis of Ganymede, which is consistent with the 2π times superlight wavelength of 170,360 kilometers. The ratio to 1.7597585 is 0.9995.
According to the super-light wave theory, it can be said that the wavelength of the super-light wave determines the semi-major axis of Ganymede, and the semi-major axis of Ganymede determines the orbital position of Callisto. Isn’t it the incredible symmetry of the distribution of satellites in the solar system? Coincidence, but determined by ultra-light waves?
David was confused again and asked: "Professor, what does what you said earlier have to do with the metronome scale?"
Professor Braun signaled David not to worry and continued to introduce the relationship between the wavelength of ultra-light waves and the corresponding frequency of the metronome scale.
Tesla studied the issue of the earth's resonance frequency at least decades earlier than his peers. If super-light waves exist, when they are diffracting the earth, their impact on the earth will resonate with the electromagnetic radiation of various objects on the earth.
Multiple resonances result in a resonant frequency related to the speed of light divided by the circumference of the Earth.
Dividing the speed of light by the circumference of the Earth (about 40,000 kilometers), the resonant frequency should be 7.5 Hz, but the actual measured resonant frequency is 7.83 Hz, which corresponds to 470 BPM in the metronome.
Tesla believed that the actual measured resonance frequency of the earth was the resonance caused by the respective resonances of super-light waves hitting the earth and the incident sun.
The resonance of the earth is 7.5 Hz. If the sun has a resonance of 8.166 Hz, and the average value is taken, the resonance formed is the measured resonance of the earth, 7.83 Hz.
If super light waves are incident on the sun, there is indeed a property that each unit wavelength corresponds to one unit Hertz frequency.
Then the diameter of the sun is about 1.3914 million kilometers divided by 8.166 Hz, and the unit wavelength of the super-light wave is 170340 kilometers.
Wait! 8.How is 166 Hz obtained?
It is calculated back from the expected 7.5 Hz of the earth's resonance and the actual measured 7.83 Hz of the earth's resonance.
The results of this algorithm and Wien's displacement law algorithm are very close, with a close ratio of 0.9999, so Tesla concluded:
The wavelength of super light waves is about 170360 kilometers.
When 8.166 Hz calculated based on the diameter of the sun is received on the earth, it will be interfered by the earth resonance of 7.83 Hz.
Calculated based on the radius of the sun, the frequency is 4.083 Hz, which can be received without interference. 4.083 times per second, 245 times per minute, which is 245BPM.
"The wavelength of ultra-light waves can be calculated based on 245BPM and 470BPM. Is Tesla an alien?" David exclaimed.
"Tesla uses the diameter of the sun when the super light wave enters the sun, and uses the circumference of the earth when it diffracts the earth. The half circumference is π times the radius, and the diameter is 2 times the radius. Therefore, there is a numerical relationship of π-2." Professor Then he said:
"The semi-major axis of Ganymede, the largest satellite in the solar system, is 2π times the superlight wavelength. The semi-major axis of Titan, the second largest satellite in the solar system, is 1221967 kilometers, which is 1.141598 times the semi-major axis of Ganymede. π-2 and The ratio of this multiple is 0.999995."
"Wow! The semi-major axes of the three largest satellites in the solar system, Ganymede, Titan and Callisto, can all be expressed in terms of π, the speed of light and super-light wavelengths?" David was shocked by this incredible phenomenon. After all, Ganymede, Titan and Callisto Titan and Titan belong to different gravitational fields! Could it be that all the satellites of the solar system are a whole, forming a cross-system resonance under the influence of a unified super-light wave?
"Now there are only two frequencies left corresponding to 30BPM and 60BPM." David continued.
"I already have an idea, but I'm not sure yet." Professor Braun said:
"30 and 60 BPM correspond to two frequencies of 0.5 Hz and 1 Hz. According to Tesla's conjecture, a complete wavelength of the super-light wave causes the sun to emit radiation corresponding to the 1 Hz frequency, and the peak part of a complete wavelength will also correspond to frequency of 0.5 Hz."
David asked: "Tesla specifically marked 0.5 Hz and 1 Hz. Is there any other special meaning?"
The professor raised his head, tapped his upper lip with his index finger, and said thoughtfully:
"There are only so many connections between these two frequencies and ultra-light waves. At least for now, I can't see how they are of any use to the Jade Khan people's plans."
