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Antimatter is formed using particle accelerator which shoot protons at near the speed of light and collide two protons this creates 2 anti protons. it also creates mini black holes although they are of no concern to anyone living on earth. although antimatter is typically seen as a potentially lethal bomb for humanity to gather enough to be effective at this time it would take about 200 years, as we gain maybe 40 anti protons a day, and anti protons are very small particles. however if it comes in contact with matter it has the highest energy conversion rate off about 99.9% to pure energy, to give you an idea the average nuclear bomb is about 32%.

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Wiki User

14y ago
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AnswerBot

5mo ago

Antiparticles are created through processes such as particle-antiparticle pair production, annihilation, and scattering in high-energy collisions. These processes can occur naturally in certain particle interactions, as well as in controlled environments like particle accelerators. Ultimately, antiparticles are formed with the same mass but opposite charge to their corresponding particles.

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Wiki User

14y ago

E=MC2

When energy gets to a certain level, it creates a particle and an antiparticle, and this process is called pair production

Mr_Adams:

E is energy and M is mass, but the surprise (and explanation behind the existence and creation of antimatter) is C is not a variable, it is a constant: the speed of light in a vacuum. Now, C is a constant, which means that Einstein was claiming that Mass WAS Energy, and vice versa, which shocked the scientific world. So, let's consider what we think we know about matter and energy up until this point, that this tells us is wrong. First, conservation of mass. Second, conservation of energy. Well, if Energy is mass, and mass is energy, we should be able to shift them back and forth between each other. there goes those conservation laws. but, it leaves us with something new: the possibility of negative matter. Now, if we take an electron and a positron (anti-electro), we get a massive amount of gamma radiation (pure energy). So, logically, with enough energy, we should be able to acquire anti particles. In the laboratory, the method used is focusing massive amounts of gamma radiation through the nucleus of an atom. what we are left with is a particle, and it's corresponding anti particle. This is the process of pair production. If these two particles were to collide, they would annihilate each other, and leave behind the previously mentioned gamma radiation. To solve this problem, a penning trap is used. it only works for charged particles, but it works by surrounding a particle with electro magnets of similar charge. because similar charges repel each other, the anti-matter particles are suspended without touching any matter. There are few uses for anti-matter, however a form of medical scanning device called PET scan is currently used to observe the movements of fluids within the body.

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Leo Sun

Lvl 4
2y ago

it is created by two atom a atom and its brother crash together and recombine to make antimatter

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Leo Sun

Lvl 1
2y ago
i already know you know by the way you can also get the answer by going to youtube and bright side.

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Wiki User

14y ago

energy and mass are interchangeable e=mc2 however in such reaction Barron on lepton numbers must be conserved so antimatter must be created in one form or another.

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Q: How are antiparticles created?
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Continue Learning about Natural Sciences

Is uranium an example of lepton?

1. Uranium is an example of an actinoid; also uranium is a solid metal, radioactive, a natural chemical element. 2. Leptons are elementary particles with a very small mass as: electrons, neutrinos and the corresponding antiparticles.


Subatomic particles that carry single electrical charges are?

In a unit of a proton's charge (1.602×10−19 coulombs), there are leptons (such as an electron) and their antiparticles, with a charge of -1 and +1, respectively, and charged baryon (such as a proton) and their antiparticles. Not all baryons have an electric charge; some are neutral, such as the neutron, and others have a charge of +2. For example, the Δ++ (delta plus-plus) particle has a charge of +2. This is because all baryons are composed of particles called quarks, which are never found in isolation. There are a total of six quarks; three have a charge of +2/3 and three have a charge of -1/3 with respect to a proton's charge.


Are h2 molecules created or destroyed?

Hydrogen molecules (H2) can be both created and destroyed. They are commonly formed during chemical reactions involving hydrogen gas, and can be broken down through processes like combustion or reaction with other elements.


What is a discovered particle belongs to antimatter?

The positron is a discovered particle that belongs to antimatter. It is the antimatter counterpart of the electron and has the same mass but opposite charge.


When was The Journal News created?

The News Journal was created in 1785.

Related questions

What is an antiatom?

An antiatom is an atom composed of antiparticles.


What is the name for particles with reversed magnetic polarity?

Particles with reversed magnetic polarity are known as antiparticles. These antiparticles have the opposite charge of their corresponding particles and their behavior is governed by the same physical laws.


What are some antonyms for subatomic particles?

You probable think to antiparticles as antiproton, antineutron, positron.


Eletron have what kind of charge?

Electrons are always negatively charged (-1 charge) Antiparticles of electrons, called positrons, have a positive (+1) charge.


Is there proof that antimatter exist?

Yes, antimatter has been experimentally observed through the creation and study of antiparticles such as the positron (antielectron) and antiproton. These antiparticles have properties opposite to their normal matter counterparts, providing evidence for the existence of antimatter.


Are neutrinos their own antiparticles?

Answer 1There are three different types of neutrinos. Each one is associated with its own antiparticle, but is not an antiparticle itself. Answer 2Particle and antiparticle are distinguished by their charges. The positron, for example, the antiparticle of the negatively charged electron, is positively charged. The neutrino, on the other hand, is electrically neutral-the prerequisite for the ability of being its own antiparticle. However, I assume that the antiparticles of neutrinos are neutrinos with opposite spinning direction.


Each fundamental atomic particle has an opposite particle A collision of these opposites will result in the annihilation of each particle These types of particles are referred to as?

Anti-matter. Antimatter.


Which particles are not affected by the strong force?

Leptons such as electrons, neutrinos, and their antiparticles are not affected by the strong force. This force only acts on particles that contain quarks, like protons and neutrons.


Each fundamental atomic particle has an opposite particle. A collision of these opposites will result in the annihilation of each particle. What are these types of particles called?

These types of particles are called antiparticles. Antiparticles have the same mass as their corresponding particles but opposite charge. When a particle and its antiparticle meet, they can annihilate each other, converting their mass into energy.


Is uranium an example of lepton?

1. Uranium is an example of an actinoid; also uranium is a solid metal, radioactive, a natural chemical element. 2. Leptons are elementary particles with a very small mass as: electrons, neutrinos and the corresponding antiparticles.


Does antimatter have a nucleus?

Antimatter is composed of antiparticles in the same way that normal matter is composed of particles. Consider that atoms are composed of protons, neutrons and electrons. An antimatter atom could be composed of anti-protons, anti-neutrons and anti-electrons (which we know as positrons).


Can a virtual black hole absorb antimatter?

A virtual black hole would probably not exist long, so it won't have much time to absorb anything. Other than that, I don't see any reason why it should make a difference between particles and antiparticles.