Every symmetry of physics laws leads to a conservation law, and every conservation law arises from a symmetry in the laws of physics.
Symmetry is the casual structure built into the creation module. The creation module has a two-way arrow of time built into it. All current information is always passed back into the versatile storage unit. These informational totals can’t be changed or deleted.
The closed sub-atomic quantum system is a duplicate of the macro quantum system. The two systems interact on a binary basis.
Researchers have developed a new theory for observing a quantum vacuum that could lead to new insights into the behavior of black holes. The Unruh effect combines quantum physics and the theory of relativity. The Unruh effect suggests that if you fly through a quantum vacuum with extreme acceleration, the vacuum no longer looks like a vacuum: instead, it seems like a warm bath full of particles.
Quantum technology is considered an emerging field of physics and engineering, which relies on principles of quantum physics.
Quantum entanglement is a physical phenomenon that occurs when a pair or group of particles are generated, interact, or share spatial proximity in a way such that the quantum state of each particle of the pair or group cannot be described independently of the state of the others, including when a considerable distance separates the particles. Einstein and others considered such behavior impossible, as it violated the local realism view of causality. (Science is slow to change when a tenant of their religion is no longer viable).
The Higgs mass is 10/17th times smaller than the Planck mass, but quantum corrections from Higgs interactions with other particles should cause the two masses to be nearly equal. This dilemma is deemed the electroweak hierarchy problem. The particles of the standard model and their mirror counterparts act in tandem to control the self-energy of the Higgs, explaining at least some (but not all) of the hierarchy between the weak scale and the Planck scale. The discovery of the Higgs boson at the Large Hadron Collider (LHC) in 2012 illuminated the mechanism of electroweak symmetry breaking, through which the electromagnetic and weak nuclear forces emerge from a unified electroweak force. But if the Higgs discovery answered the question of how electroweak symmetry breaking occurs, it opened the further question of why this breaking occurs at around 250 GeV—an energy far removed from other energy scales in particle physics. This energy mismatch goes by the name of the electroweak hierarchy problem, and it is one of the great mysteries in physics.
Another possibility is that symmetry plays no decisive role; instead, the Higgs mass is determined dynamically by the evolution of other fields in the early Universe.
A new spin on atoms gives scientists a closer look at quantum weirdness.
When atoms get incredibly close, they develop intriguing interactions that could be harnessed to create new generations of computing and other technologies. These interactions in the realm of quantum physics have proven challenging to study experimentally due to the fundamental limitations of optical microscopes. Studying atoms and their interactions at tiny distances allows scientists to explore and control a quantum property known as spin. Entangled particles behave as if they share one existence, no matter how far apart they later become. Entanglement is the essential phenomenon that separates quantum mechanics from the classical world, and it’s at the center of the vision for quantum technologies. Entangled particles behave as if they share one existence, no matter how far apart they later become. Entanglement is the essential phenomenon that separates quantum mechanics from the classical world, and it’s at the center of the vision for quantum technologies. The new Princeton device is a stepping stone for scientists to study these spin interactions with unprecedented clarity.
Direct visualization of quantum dots reveals the shape of the quantum wave function. Trapping and controlling electrons in bilayer graphene quantum dots yields a promising platform for quantum information technologies. Researchers have now achieved the first direct visualization of quantum dots in bilayer graphene, revealing the shape of the quantum wave function of the trapped electrons. These results provide the fundamental knowledge to develop quantum information technologies based on bilayer graphene quantum dots. While conventional digital technologies encode information in bits represented as either 0 or 1, a quantum bit or qubit can mean both states simultaneously due to quantum superposition. In theory, technologies based on qubits will increase computing speed and capacity for certain types of calculations. Understanding the nature of the quantum dot wave function in bilayer graphene is essential because this fundamental property determines several relevant features for quantum information processing, such as the electron energy spectrum, the interactions between electrons, and the coupling of electrons to their environment.
A scanning tunneling microscope was used to create quantum dots in monolayer graphene. With the graphene resting on an insulating hexagonal boron nitride crystal, a large voltage applied with the STM tip makes charges in the boron nitride that serve to electrostatically confine electrons in the bilayer graphene. The electric field produces a corral that traps the electrons in the quantum dot like an invisible electric fence. This work provides crucial information, such as the energy spectrum of the electrons, needed to develop quantum devices based on this system.
THE LAW THAT CONTROLS ALL PARTICLE INTERACTIONS IS THIS:
ALL THINGS ARE TRIUNE, WITH BINARY INTERACTIVES. THIS IS THE LINKAGE BETWEEN MATTER AND FORCE-CARRYING PARTICLES. THE LINKAGE BETWEEN THE PARTICLE ZOO IS CONTROLLED BY FERMIONS AND BOSONS.
THE REALITY OF HOW LIFE FORMS CAME ABOUT ON THIS REMOTE BLUE MARBLE IS THIS: THE EVENT ORIGINATOR WROTE THE CODE, PRODUCED THE BLUEPRINT, AND USED AN EVOLVEMENT PROCESS TO OBTAIN THE REQUISITE RESULT. IT’S ALL JUST A BINARY SOFTWARE.
IT’S ALL ABOUT THE CODE THAT YOU START WITH.
THE DESIGNER/CREATOR’S PROCESS : (recap).
1ST: Write the code for the upcoming big bang to create another universe. (One Universe does not an infinity make.)
2nd: Write the code for the design and descent for all intended results as the event unfolds. ( One event does not require an eternity to make).
3rd: Set the event in motion. All things are triune, with binary interactives.
4th: Monitor, fine-tune, adjust, and select out ongoing.
5th: Use DESIGN AND DECENT as the process. Write a separately coded blueprint for the consciousness of the known thought reposers.
6th: It’s not the people; it’s the event.
7th: Harvesting new crops of known thought reposers was the intended result.
