Theres really no example, antimater is an opposite of matter. Scientists have ceated a antimater particle by smashing energy into matter at the spped of light, 2 particles are always created this way: matter and anti matter.
once matter collides with antimatter, they tranform into energy through annhilation.
We want to use this energy to power and heat our homes in the future.
but if anti matter the size of your hand touched matter, which includes anything in this universe, it could destroy whole continents because there is mass energy realeased.
scientists make sure that only a speck of anti matter is used to make energy.
But if antimatter cant touch matter, how did they conserve it, well they want to put an electo shield inside a vacum with no matter, this elecro flow makes the antimatter hover, not touching the walls of the container, which is matter
The antiparticle of a positron is an electron. Both the positron and electron have the same mass but opposite charge, with the positron having a positive charge and the electron having a negative charge.
Answer:I suppose that means that all relevant properties are neutral, so when they are inverted, nothing changes. For example: the proton has a positive electrical charge, but the antiproton has a negative charge. The neutron has no electric charge, so the antineutron has no charge either - but there are still a few other properties where the antineutron is the opposite of the neutron. A photon doesn't have these properties (in other words, it has them equal to zero), so it is its own antiparticle. Answer:There is a relativistic wave equation called the Majorana equation, that predicts that neutrinos and antineutrinos are, in fact, the same thing. Some experimentation is being done to find out whether this is true. There is a link to a Wikipedia article below.
Energy can be turned into mass through the process of pair production, where a high-energy photon creates a particle-antiparticle pair. An example of turning energy into mass is when a gamma-ray photon interacts with an atomic nucleus, leading to the production of an electron-positron pair.
A positron is the antiparticle of an electron; in other words, it is an alternate name for the "anti-electron". Therefore, a positron would anihilate with an electron. I am not sure about the "why".
A pozitron is not a particle that is part of an atom. Protons, electrons, and neutrons are the three main subatomic particles found in an atom. A pozitron is a type of antimatter particle, specifically the antiparticle of an electron.
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.
The antiparticle of a positron is an electron. Both the positron and electron have the same mass but opposite charge, with the positron having a positive charge and the electron having a negative charge.
A particle with the same mass but with an opposite electrical charge of a particular known particle is called an Antiparticle. For example, the antiparticle of the electron is a positron, with equal mass but opposite charge.
The first antiparticle discovered was the positron, which is the antiparticle counterpart to the electron. It was predicted by Paul Dirac in 1928 and confirmed experimentally by Carl Anderson in 1932.
in1932
An antihyperon is the antiparticle of a hyperon.
An antidiquark is an antiparticle of a diquark.
An antipion is the antiparticle of a pion.
An antiphoton is the antiparticle of a photon.
An antinucleon is an antiparticle of a nucleon.
An antiboson is the antiparticle of a boson, which is a type of subatomic particle that follows Bose-Einstein statistics. When an antiboson interacts with a boson, they can annihilate one another, releasing energy in the process.
When a particle and its antiparticle collide, they annihilate each other and release energy in the form of photons or other particles.