The venue was perfectly quiet.
Everyone sat in their seats, attentively listening to Zhao Yi’s presentation on the stage.
Zhao Yi seed quite excited; during his explanation, he occasionally made hand gestures to emphasize certain points.
"The content on these three whiteboards illustrates the mathematical relationship between the composition and acquisition of particle energy and mass. Acquiring mass affects the external energy arrangent of particles, causing changes in characteristics, or to put it another way, transforming into different particles..."
"The mass that particles can acquire is directly related to its boundary energy arrangent—the denser the energy arrangent, the greater the mass it can acquire."
"Concurrently, the energy arrangent of particles will also change under the influence of mass."
"The latter might reflect so kind of energy-mass conservation, such as Einstein’s mass-energy equation. However, whether the microscopic energy composition and acquisition of mass follow the mass-energy equation is hard to determine. Moreover, it could be conceptualized that a fixed energy arrangent could attract higher-dinsional matter or mass."
Zhao Yi added, "Edward Witten’s latest theory suggests that mass may be a product of higher dinsions rather than three-dinsional space. Therefore, it could be subject to spatial repulsion. I have been working on related research and exploration with him..."
"The current verification of the Supersymtry Problem is part of this research."
His genteel reference deflected any potential confrontations.
Edward Witten was delighted and eagerly waved to people on his left, right and those in the back rows.
Sheldon Glashow could only scoff. He made it clear that he did not believe in concepts like ’multi-dinsional spaces,’ ’M Theory,’ or the assertion that ’mass exists in higher dinsions and is repelled by space.’
Zhao Yi continued his explanation, "Returning to the content on the whiteboard, I would like to thank Mr. Glashow. His ’reminder’ provided inspiration."
Sheldon Glashow did not find being referenced as flattering as Edward Witten did. Everyone knew he was pointing out problems, not offering reminders.
When he felt everyone’s gaze on him, so even with a trace of sarcasm, his face grew incredibly dark.
Zhao Yi continued, "I have argued about how energy acquires mass. So of you may not understand towards the end as my explanation is not comprehensive."
"But that’s okay..."
He discussed the timing of the presentation with the host and then returned to the podium and announced, "I decided to adjust the schedule, a detailed explanation about the proof of the Supersymtry Problem will happen tomorrow. If anyone has questions about the verification process, you can co here tomorrow to listen."
"In the afternoon, I will provide on-site calculations and explanations for the new content on the whiteboard!"
The announcent imdiately provoked fervent discussions. Even Sheldon Glashow, unable to hide his surprise, widened his eyes.
The study of theoretical physics is not as simple as doing math problems.
The term "theory" in theoretical physics implies that theories are not yet verifiable—they are constructs of mathematics and imagination.
Math is self-explanatory, but imagination often exposes nurous flaws.
After a study is conducted, it is followed by continuous calculations and adjustnts, sotis to the extent that the original study becos unrecognizable.
This is a standard process.
Zhao Yi claid that he had developed sothing called the ’Mass-Energy Structure Theory,’ involving energy and mass and proving the relationship between energy structure and mass, which sounds like significant research.
If verified to be correct, it could rival Einstein’s mass-energy equation.
Einstein’s most recognized achievent is the Theory of Relativity, for which he received a Nobel Prize for explaining the photoelectric effect. However, the mass-energy equation, which provided the theoretical basis for nuclear reactions, had the most significant influence on humanity.
Mass-energy equation, E=mc².
This simple equation describes the relationship between mass and energy. In classical chanics, there is no relationship between mass and energy, but in relativistic chanics, energy and mass are rely two different aspects of an object’s properties.
Einstein’s interpretation of the mass-energy equation was, "If an object radiates energy, ΔE, its mass will decrease. Whether the energy lost by the object is converted precisely into radiant energy is irrelevant. Thus, we draw a more general conclusion: the mass of an object is a asure of its contained energy."
He further noted, "This result has special theoretical importance. The property of inertia and energy appear as one in the object, and it is impossible to distinguish between ’true’ mass and ’apparent’ mass. It is much more natural to interpret any form of inertia as a type of energy container."
Thus, the independent conservation of mass and energy in classical chanics combined to form the unified "Law of Conservation of Mass-Energy."
This law fully reflects the unity of matter and motion. The mass-energy equation demonstrates that mass and energy are inseparable and interconnected.
The mass-energy equation interprets the relationship between mass loss and energy release.
Now, Zhao Yi’s research on the relationship between microscopic energy composition and mass, once verified and analyzed further, could potentially provide a theoretical basis for microscopic particle experints.
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