Calculate a person's wavelength?

The wizards present were a little incredulous, people actually have fluctuations?

Jeffrey had an expression of disbelief, even though he was one of the pioneers of light volatility, he didn't dare to say such a strange thing as human volatility!

As if he didn't see everyone's surprise, Lynn used his hand as a pen and wrote a few symbols in the void at random, which is the famous De Broglie wavelength formula!

The equation is incredibly simple and easy to see at a glance.

It's even incredibly simple!

λ=h/p！

The symbol λ is the wavelength.

They are very familiar with momentum, the product of the mass and velocity of an object!

The only strange thing is that h.

"This is the quantum constant, which, like the gravitational constant, is a fixed value of 6.626×10^(-34) joules per second!" Lynn explained.

Hearing the word [Quantum Constant], the wizards in the venue who were keen on studying the microscopic realm immediately showed a look of understanding.

This is a concept that Lynn mentioned in his paper "The World of Probability: Quantum Mechanics" published in the Magic Daily, when he explained the study of the particle properties of radiant light and electromagnetic waves.

An electromagnetic wave is an electromagnetic field that propagates in the form of waves, but when it interacts with charged particles, it exhibits a discontinuity of energy and momentum.

So this magic star assumes that it is not emitting and absorbing continuously, but one by one, then there must be a minimum!

This value is the quantum constant – the smallest amount of energy that can be split!

And the whole wavelength calculation formula translates to one thing: the wavelength of an object is equal to the quantum constant divided by its momentum!

With the computing power of the Great Wizard, it only took Anthony a second to calculate that an adult would move at a normal speed with a wavelength of about 10^(-37) meters, a scale that is almost negligible.

Not to mention the naked eye, even the perception of a legendary wizard would never touch such a scale.

"But this quantum constant should only be your hypothesis!" Jeffrey wasn't convinced by the wave formula that Lynn came up with.

After all, isn't it nonsense to use a hypothetical thing to prove the accuracy of your theory?

Before Lynn could speak, Erok on the side couldn't help but explain.

"This is not a hypothesis, but the highest result of the Dean's research on electromagnetic waves and thermal radiation! We have found a way to emit a single light quantum, and this wavelength formula is 100% correct in calculating the wavelength and frequency of light and electricity, and can even predict where microscopic particles may appear, which is almost perfectly consistent with the results of the experiment! ”

Hearing Elok say this, the corners of Lynn's mouth also flashed a smile, once it comes to the quantum realm, Planck's constant becomes something that needs to be confirmed first, because there are too many formulas related to it, and it is also the third thing that can be called a physical constant after the speed of light and the gravitational constant!

Unfortunately, due to limited conditions, Lynn could only measure the value of Planck's constant by reproducing Joseph von Fife's rotary geometry device, which was not very accurate.

If you want to continue to improve your accuracy, you'll have to rely on the Particle Collider.

Hearing that Elok said that they had found the light quantum, Anthony and the others were shocked.

Why were all previous double-slit interference experiments done with electrons? That's because they can't emit photons one by one!

Some staunch wave wizards even believe that photons don't exist at all, and that this thing has been determined to be electromagnetic waves!

It's a wave, not a particle!

But if Erok is not lying, it means that this conclusion will also be overturned, and waves also have the properties of particles!

On the other hand, Arad noticed another, more exciting news, and said excitedly. "You just said that you can predict where microscopic particles will fall?"

The wizards present also reacted, and even the three Speakers, Haroff, Aurora, and Vittorio, couldn't sit still.

Due to the many strange properties of the microscopic realm, and the fact that the volume is too small, there is no way to measure it to any extent, and even the gravitational deformation amplification method used to measure atoms has failed.

So far, there has been a blank space for data on the shape, mass, and trajectory of quanta.

In a double-slit experiment, for example, they don't know where the next electron might be, or even if it will fall on a phosphor screen.

This is also the biggest problem facing the current study of microscopic particles, all its properties seem to be chaotic, and there is no clue to it.

"If you want to talk about prediction, then you can." Lynn laughed, then explained. "It's just that this isn't exactly what you think it's an accurate prediction, it should be called a probability cloud map!"

It is almost impossible to make an accurate single prediction of the location of a quantum moment in time.

Because the Federation has proven countless experiments that this thing is really random and not pseudo-random that loops according to some law.

But if more than 100,000 electron launches are performed, then the accuracy of this probability cloud distribution model can reach more than 90% of the time!

Just like tossing a coin in your hand, as long as you have enough times, the number of times it lands on the front and back will always tend to be close to 50%!

"So every microscopic particle is constantly throwing the dice, deciding where it will appear when it is observed the next moment?" Jeffrey couldn't understand it. "Doesn't that consume energy?"

"Why not the other way around? Maybe it is the probability of collapse that requires energy consumption. Lynn shrugged.

This strange and plausible statement left Jeffrey speechless.

Arad et al. are thinking about Lynn's wavelength formula and probabilistic cloud model.

The latter has not yet been confirmed by experiments, so it is impossible to evaluate it for the time being, but the former is perfectly in line with what Lynn just said, the more macroscopic the volatility of the object, the weaker the result.

After all, the greater the momentum of P as a divisor, the smaller the final wavelength value, and the more insignificant it is compared to its own mass and volume.

Only quanta, which are also in a microscopic state, exhibit particularly significant fluctuations compared to their mass.

Or rather, the conclusion itself is a reversal of the formula!

A contemplative Arad quickly thought that this wavelength formula, along with the probabilistic cloud model, might be one of the entry points for studying the quantum realm......

Wait, aren't they here to oppose probability theory?

Arad snapped into this.

Damn, I almost got around this magic star!

(PS: The second chapter is around four o'clock, and it will be updated at normal times tomorrow, thank you for your support and rewards, and wait for me to save a village these days and add more!) ）

(End of chapter)