Begin from the original form of torture and become immortal

Chapter 1431 The Search for Dragon Ball Begins

In order to further analyze the microscopic world of Dragon Ball, Ivan turned to the powerful analytical tool of nuclear magnetic resonance spectrometer (NMR).

NMR technology reveals the internal structural information of molecules, including the type of chemical bonds, the spatial configuration of molecules, and the dynamic behavior of molecules, by detecting the energy level transitions of atomic nuclei in an external magnetic field.

For complex and unknown samples like dragon balls, the application of NMR is particularly critical.

After careful preparation, Ivan placed the Dragon Ball in a strong magnetic field and carefully adjusted the frequency of the radio frequency waves to stimulate the resonance of the atomic nuclei inside the Dragon Ball.

As data accumulated, NMR spectra gradually emerged, revealing the amazing complexity within the Dragon Ball molecule.

Ivan discovered that there is a type of chemical bond in the dragon balls that is extremely rare on Earth - a metal-metal bond. This type of bond usually only appears under extreme conditions or in specific types of compounds. Its existence indicates that the dragon balls may contain one or more unknown high-performance materials.

In addition, NMR also hints at the possible existence of a highly ordered structure within the molecule, which may be closely related to the special functions of Dragon Balls.

Ivan's excitement was beyond words. He realized that the Dragon Ball was not only a mysterious tool for making wishes, but also a window to an unknown area.

Through in-depth research on Dragon Ball, humans may be able to unlock the technological secrets of alien civilizations and even discover new forms of energy that transcend current cognition.

This prospect deeply shocked Ivan and strengthened his determination to continue exploring.

In the field of electromagnetic experiments, Ivan used sophisticated electromagnetic measurement equipment to conduct a comprehensive analysis of the electromagnetic wave emission characteristics of Dragon Ball.

He discovered that dragon balls can emit a weak electromagnetic wave with a unique wavelength. This wave is different from common electromagnetic waves such as radio waves, visible light, X-rays, and gamma rays, and belongs to an understudied area of ​​the electromagnetic spectrum.

The wavelength of the electromagnetic waves released by Dragon Ball is between microwaves and far-infrared waves, a frequency band called "terahertz waves".

Electromagnetic waves in this area have long been relatively neglected in scientific research because they are difficult to generate and detect, but they have unique properties such as strong penetration and sensitivity to material structure.

The terahertz waves emitted by Dragon Ball have extremely high frequency stability and carry a certain information pattern, which is completely different from the electromagnetic waves generated randomly in nature, suggesting the possibility of a non-natural source.

This discovery not only means that the dragon ball has some form of electromagnetic activity, but also may mean that it can interact with the outside world in some way electromagnetically.

"If the Dragon Ball can emit electromagnetic waves, then theoretically we can detect it with radar."

There was a gleam in Ivan's eyes.

In order to verify the idea of ​​using radar to detect dragon balls, Ivan began to design a customized radar system.

This system not only requires the ability to transmit and receive electromagnetic waves in the terahertz band, but also needs to have high-resolution imaging capabilities in order to accurately track the position and dynamics of the dragon balls.

He introduced phased array radar technology, which electronically controls the transmit and receive phases of multiple antenna units to achieve simultaneous multi-angle scanning of targets, greatly improving the detection accuracy and flexibility of the radar system.

Ivan's work in elemental analysis was equally meticulous. The use of a mass spectrometer allowed him to analyze the chemical composition of the dragon balls at the atomic level.

The atoms or molecules in the dragon ball sample are ionized into ions through an ion source, and then these ions are accelerated and separated by electric or magnetic fields, forming a specific mass spectrum according to their different mass-to-charge ratios (m/z). This process not only reveals that the dragon ball contains basic elements such as carbon, hydrogen, oxygen, and nitrogen, but also detects the presence of trace metal elements such as iron and silicon, which are usually associated with complex organic structures or biomineralization.

The application of energy dispersive spectroscopy provides key clues to understanding how these elements are organized inside dragon balls.

When X-rays or high-energy electron beams are irradiated onto the Dragon Ball sample, they interact with the atoms in the sample, causing elastic scattering (i.e., Rayleigh scattering) and inelastic scattering (such as Compton scattering, Auger electron emission, etc.).

By analyzing the energy distribution and angular distribution of scattered light, Ivan can infer the chemical state of the element (such as oxidation state), chemical bond type (covalent bond, ionic bond, etc.) and molecular structure information.

The results showed that the chemical bond network inside dragon balls is extremely complex, with a large number of conjugated systems, ring structures and special stereoisomers. These characteristics are far beyond the level that can be achieved by organic matter formed under natural conditions.

This explains why Dragon Balls are physically and chemically very different from ordinary matter.

Ivan noticed that although the elemental composition of the Dragon Balls seemed ordinary, there was a surprising amount of complexity and functionality hidden within them, a property that could have been carefully designed and manufactured by an alien civilization using highly advanced technology.

"Are there really aliens in this world?"

Ivan asked silently in his heart. Although he had personally measured these strange properties of the dragon ball, he still couldn't believe it.

After all, so far, no planet with life has been discovered in the known universe observed by humans.

The earth and human society seem so lonely and insignificant in this vast universe, as if they are the lucky ones favored by fate.

Although the elemental composition of Dragon Balls may seem ordinary, the complexity and functionality of their molecular structure are incredibly amazing, which may point to the design of some advanced intelligence.

Although the possibility of extraterrestrial civilizations sounds incredible, humans' understanding of life in the vast universe is still far from enough.

Given the age and size of the universe, and the vast regions we have yet to explore, the loneliness of life on Earth seems increasingly untenable.

Ivan began to collect theories and hypotheses about extraterrestrial civilizations and interstellar communication. Among them, the Fermi Paradox is particularly thought-provoking: If extraterrestrial civilizations are common, why haven't we found any traces of them so far?

Perhaps Dragon Ball is one of the key clues to solving this mystery.

It may have been created or abandoned by an alien civilization for some purpose, and its unique electromagnetic properties and complex chemical structure may be designed to interact with specific environments or life forms.

He began to think, if Dragon Ball is really the product of alien civilization, then why did it appear on Earth? Did it fall accidentally, or is it used as a medium for communication?

"Anyway, I hope it will be successful."

Ivanvanko built the radar in just one day.

(End of this chapter)