According to quantum theory, the act of observing affects the observed reality. This means that when someone is watching, they affect the observed reality. 

In the quantum realm, objects exist in a probability smudge and only come into focus when observed. Some physicists say that there are endless worlds with countless versions of you, and that even if you’ll never meet those other yous, they’re out there. 

Quantum theory can also be used to explain natural phenomena such as the color of the sky or photosynthesis.

Quantum physics is used indirectly in everyday life. It provides information about the dynamics of atomic and subatomic particles. Quantum physics has led to the development of many devices, including: 

• Lights: Fluorescent lights and tube lights 
• Computers and mobile phones 
• Transistors 
• GPS 
• MRI 
• Telecommunications 
• Lasers

Quantum physics can also explain some effects in nature that classical physics can’t, such as:

• Blackbody radiation 
• The stability of electrons in atoms 
• The workings of biological systems, including smell receptors and protein structures Quantum physics also suggests that our thoughts and emotions emit energy that can influence our experiences. Some say that by consciously raising our vibration and aligning with positive frequencies, we can attract desired outcomes

It has also given insight into the workings of many different biological systems, including smell receptors and protein structures. Recent work on photosynthesis has provided evidence that quantum correlations play an essential role in this fundamental process of plants and many other organisms

Quantum physics describes reality as a relativistic object that expands and experiences a deceleration of physical time. It also explains the behavior of light and matter at the smallest scales, including wave-particle duality and entanglement

Quantum physics supports a non-deterministic pattern for reality. This means that reality can be comprehended by choosing a way to measure it. For example, quantum objects like electrons and photons can behave as either particles or waves. This means that when detecting something, the photons can be measured as waves or particles, which can lead to different realities. 

Quantum mechanics is a set of mathematical rules that describe reality. It’s considered one of the most successful theories in science, and its equations can accurately predict how tiny particles behave. However, the rules at the level of atoms and subatomic particles seem different from the ones we’re used to in our everyday experience. For example, particles appear to be fuzzy and spread out, or in two places at once

At its roots, reality is described by the mysterious set of mathematical rules known as quantum mechanics. Conceived at the turn of the 20th century and then emerging in its full form in the mid-1920s, quantum mechanics is the math that explains matter

According to some, quantum physics suggests that anything is possible, regardless of the probability. This is because quantum mechanics suggests that any space could contain any matter at any time. However, others say that quantum mechanics does not say that everything is possible. For example, a bound electron orbiting a hydrogen atom can only have certain discrete energy values

The “many-worlds interpretation” (MWI) of quantum mechanics is a popular theory that suggests that the universe splits into multiple realities with each measurement. The MWI states that there are many worlds that exist in parallel at the same space and time as our own

The MWI’s fundamental idea is that every time a quantum experiment with different possible outcomes is performed, all outcomes are obtained, each in a different newly created world. 

The MWI began in 1926, when Austrian physicist Erwin Schrödinger mathematically demonstrated that the subatomic world is fundamentally blurry. However, one criticism of the MWI is that it doesn’t deliver any new insights into how nature works. 

Some say that quantum physics does prove the multiverse:

• Quantum superposition Quantum superposition is a basic concept in quantum physics that states that what we think of as a single universe is actually the interference of an infinite number of universes. 
• Spooky action at a distance This interpretation states that every time a quantum particle interacts with another quantum particle, the universal wave function splits into multiple sections. Each of these sections contains a different possible result, which leads to a multiverse. 
• Quantum computers Quantum computers create a special environment that allows communication between parallel universes. Some say that quantum computers would prove that resources beyond the known physical universe exist. 

The Quantum Realm is a fictional microscopic subatomic dimension in the Marvel Comics multiverse. It was first introduced in 1963 and has been used in various storylines, including the Ant-Man and Doctor Strange comic book series. 

In the Marvel Cinematic Universe (MCU), the Quantum Realm is a separate reality in the multiverse. It’s a combination of two different dimensions from the comics: the Quantum Zone and the Microverse. The Quantum Zone is the realm where all the energy of the universe comes from, and the Microverse consists of many different sub-atomic dimensions. 

Some say that the Quantum Realm exists apart from the Multiverse and doesn’t follow its rules. Others say that the “realms” of the MCU, such as the Ancestral Plane, the Noor Dimension, and the Quantum Realm itself seem to be on a different plane of existence from the alternate realities of the Multiverse.

The Quantum Realm exists apart from the Multiverse and doesn’t follow its rules, providing a theoretical “constant” to form the foundation of the MCU’s reality. It’s also difficult to leave the Quantum Realm once you’ve arrived, as evinced by the various travails of the Ant Family and Kang himself

In quantum mechanics, an observer is anything that detects a quantum particle. This includes any physical object, such as a particle, atom, subatomic particle, or molecule

An observer is also a physical system that can trigger the collapse of a wave function when it comes into contact with a quantum system. However, which system can trigger wave function collapse is only determined experimentally. 

Observation is also called measurement. It requires a transfer of energy between the observer and the observed. For example, a photon from the sun gives energy to an electron in a retina. 

Observation is observer-dependent, meaning there is no objective observation. This is because humans are quantum systems, and different observers can observe different things. 

Some interpretations of quantum mechanics posit a central role for an observer of a quantum phenomenon. The quantum mechanical observer is tied to the issue of observer effect, where a measurement necessarily requires interacting with the physical object being measured, affecting its properties through the interaction

In quantum mechanics, the observer effect states that observing a particle changes its behavior. This is due to the interaction between the particle and the measuring instrument

The observer effect is especially prominent in physics, where observation and uncertainty are fundamental aspects of modern quantum mechanics. 

Here are some examples of what happens when a quantum particle is observed:

• Double slit experiment Watching the experiment can change the results. This shows how our presence can change reality. 
• Quantum interactions Even a single photon will change the state of the measured particle. This is how the particle “knows” that it is being “observed”. 
• Standard quantum mechanics The measurement causes the system’s multiple possible states to randomly “collapse” into one definite state. 

A notable example of the observer effect occurs in quantum mechanics, as demonstrated by the double-slit experiment. Physicists have found that observation of quantum phenomena by a detector or an instrument can change the measured results of this experiment

According to the observer effect, observing a photon changes its behavior. This is because the observer interacts with the photon, and in this interaction, the information about the superposition of states is lost

For example, in the double slit experiment, if either path is monitored, a photon will seemingly pass through one slit or the other, and no interference will be seen. However, if neither is checked, a photon will appear to have passed through both slits simultaneously before interfering with itself, acting like a wave. 

The observer effect is a phenomenon in quantum mechanics where the act of observation changes the behavior of the particles being observed. This effect is due to the wave-like nature of matter, which means that particles can exist in multiple states simultaneously. 

While the effects of observation are often negligible, the object still experiences a change. This effect can be found in many domains of physics, but can usually be reduced to insignificance by using different instruments or observation techniques

However, a 1998 study reported in Nature demonstrated that observation affects reality. The experiment involved controlling the properties of a quantum observer to control its influence on the behavior of electrons. 

Quantum mechanics states that when a quantum observer is watching, particles can also behave as waves. This can be true for electrons at the sub-micron level. 

According to Goodreads, quantum physics tells us that nothing that is observed is unaffected by the observer. This means that everyone sees a different truth, because everyone is creating what they see

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