Fractals are mathematical objects that can represent systems that show self-similarity across both space and time. They can describe a new kind of order in systems that may have otherwise been overlooked. 

Fractals are of particular relevance in the field of chaos theory. They show up in the geometric depictions of most chaotic processes. 

Fractals can offer a new way to see the quantum realm by: 

• Describing a new kind of order 
• Allowing the possibility of a new form of macroscopic quantum-type behavior 
• Representing systems that display self-similarity across both space and time 

The concept of fractals provides a connection between different scientific disciplines, including quantum mechanics and biology

As such, the value of fractals is that they describe a new kind of order in systems that we may have otherwise overlooked. They pave the way to potential new insights from otherwise familiar shapes like lines, planes, and points, in the unfamiliar milieu of a space with non-integer dimensions.

Fractals are important because they can help us understand complex systems and predict patterns in data. They can also help us understand: 

• Scientific concepts: Such as the growth of bacteria, brain waves, and patterns in freezing water 
• Objects: Such as coastlines, rivers, plant distributions, architecture, wind gusts, music, and the cardiovascular system 
• Nature: Such as mountains, clouds, and trees 

Fractals have many practical uses, including: 

• Computer graphics 
• Computer file compression 
• Internet architecture 
• Diagnosing diseases 

Fractals can also be used for focusing and meditating. Studies have shown that exposure to fractal patterns in nature can reduce stress levels by up to 60%

In the Marvel Cinematic Universe (MCU), the Quantum Realm is a dimension that’s located between atoms. It’s made up of two dimensions from the comics: the Quantum Zone and the Microverse. The Quantum Zone is where the universe’s energy comes from, and the Microverse is made up of many sub-atomic dimensions. 

The Quantum Realm is depicted as a strange and surreal place where time and space function differently. It’s possible for objects and beings to exist in multiple places at once. The Quantum Realm is home to many strange creatures and entire civilizations. 

In the MCU, there are two ways to enter the Quantum Realm: 

• Magical teleportation: Using a Sling Ring, like Doctor Strange 
• Shrinking down: Becoming smaller than atoms 

In physics, the Quantum Realm is the scale where quantum mechanical effects become important. This usually means distances of 100 nano meters (10−9 meters) or less, or at very low temperatures

Here are some more facts about fractals: 

• Self-similarity: Fractals are infinitely complex patterns that are self-similar across different scales. 
• Non-integer dimension: Fractals have non-integer dimensions. 
• Zoom symmetry: Fractals have zoom symmetry. 
• Complexity from simplicity: Fractals have complexity from simplicity. 
• Infinite intricacy: Fractals have infinite intricacy. 
• Fractional dimensions: Fractals have fractional dimensions. 
• Non-uniform shapes: Fractals address the more non-uniform shapes found in nature. 
• Rough objects: Fractals provide a systematic method to capture the “roughness” of some objects. 
• Snowflakes: Snowflakes are one of the most famous and impressive fractals in nature.

The Quantum Realm is too small to see. It’s a different way of looking at the universe, not a different place. The Quantum Realm is where quantum mechanics is needed to understand the behavior or solution of small things. 

Quantum microscopy can measure and image the microscopic properties of matter and quantum particles. Scientists have also observed quantum behavior in macroscopic objects that are big enough to see with the naked eye. 

The cold atom lab in the International Space Station can create macroscopic quantum objects. These objects are put into space so they have more time to interact with gravity

It’s not possible to see individual subatomic particles with the human eye. The wavelengths of light that humans can perceive are not affected by subatomic particles. 

However, it is possible to infer the existence of subatomic particles by observing their indirect effects. For example, if many subatomic particles are emitting radiation, or if radiation is shined on them and a response is received, then it can be inferred that the particles exist. 

Quantum microscopy can measure and image the microscopic properties of quantum particles and matter. Physicists have also observed quantum behavior in macroscopic objects that are visible to the naked eye

Yes, quantum entanglement has been observed. Quantum entanglement is a phenomenon that binds particles together across any distance. It was predicted in the 1930s and has been observed experimentally since the 1970s. 

Here are some examples of quantum entanglement: 

• Light source: A light source that emits two photons at a time. The polarizations of the individual photons can be random, but photons of a pair always have matching polarizations. 
• Human body: Hundreds of molecules in the human body become entangled. 
• Metals and magnets: Molecules in metals and magnets become entangled. 

Quantum entanglement has been demonstrated with: Photons, Electrons, Small diamonds. 

The 2022 Nobel Prize in Physics was awarded for investigations into quantum entanglement. Research and development is currently being done on the use of entanglement in: Communication, Computation, Quantum radar. 

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