No, the number of protons in an atom is determined by its atomic number, which remains constant for a given element. Larger atoms may have more electrons and neutrons, but the number of protons defines the element's identity. The atomic number corresponds to the number of protons in the nucleus, influencing the atom's chemical properties.
Atoms can get larger by adding more protons, neutrons, and electrons. However, there is no theoretical limit to how large an atom could be, although the stability of such large atoms would be limited by factors such as nuclear forces and electron configuration.
More or less, but all atoms are about the same size as each other. You would think that heavy atoms, with many electrons, would be much larger, but they aren’t. The reason is that large atoms have large nuclei with many protons. These exert a strong force on theelectrons, pulling them in closer. So even though there are more electrons in large atoms, they arepulled in closer, leaving the overall size of the heavy atoms the same as for light ones.
There are three particles that make up an atom: electrons, protons, and neutrons. The electron is a tiny, light particle that has a negative charge. The proton is larger and heavier and has a positive charge. The neutron is large and heavy just like a proton, but this particle does not have any charge at all.
As you move from left to right across the Periodic Table, the number of protons in the nucleus of each successive atom increases by one. Correspondingly, the number of electrons also increases by one. However, if the elements in question are on the same energy level, the added ''pull" of the protons serves to pull the orbiting electrons closer to the nucleus, thus causing the radius of the atom to become smalller as you move from left to right. As you move down the periodic table, atoms get larger. As you move down the table, you continue to add protons and electrons. However, you also add energy levels and, in so doing, the orbiting (and available) electrons get further from the nucleus and the pull of the protons. It is the distance between protons and available electrons that allows the radius of the atoms to get larger. It also explains why reactivity increases as you go down the table. The pull of protons on the available electrons of small atoms is much greater than the pull of protons on the available electrons of large atoms, so the large atoms release their electrons much more readily.
Low ionization energies are typically characteristic of atoms that have large atomic size and few protons in their nucleus, such as alkali metals and alkaline earth metals. These atoms have loosely bound electrons that require less energy to remove.
Atoms can get larger by adding more protons, neutrons, and electrons. However, there is no theoretical limit to how large an atom could be, although the stability of such large atoms would be limited by factors such as nuclear forces and electron configuration.
The two main categories are (1) fusion: joining small atoms into larger atoms, such as hydrogen-1 into helium-4, and (2) fission, the splitting of certain large atoms, such as U-235.The two main categories are (1) fusion: joining small atoms into larger atoms, such as hydrogen-1 into helium-4, and (2) fission, the splitting of certain large atoms, such as U-235.The two main categories are (1) fusion: joining small atoms into larger atoms, such as hydrogen-1 into helium-4, and (2) fission, the splitting of certain large atoms, such as U-235.The two main categories are (1) fusion: joining small atoms into larger atoms, such as hydrogen-1 into helium-4, and (2) fission, the splitting of certain large atoms, such as U-235.
Well, in a rather large nutshell, atoms contain protons, neutrons, and electrons. Simple! I learned in a short explanation. Thanks!
Yes. There are infinitely many prime numbers so that the largest prime number is infiitely large. The current understanding of the universe suggests that it is finite, and therefore the number of atoms must be smaller.
Immigrants were encouraged to vote in large numbers in the northern cities.
Of course, as atoms are tiny the nucleus is even smaller, but it depends on the atom. Some atoms have large protons and neutons in the nucleus, others smaller ones.
More or less, but all atoms are about the same size as each other. You would think that heavy atoms, with many electrons, would be much larger, but they aren’t. The reason is that large atoms have large nuclei with many protons. These exert a strong force on theelectrons, pulling them in closer. So even though there are more electrons in large atoms, they arepulled in closer, leaving the overall size of the heavy atoms the same as for light ones.
Atoms are made up of 3 types of particles electrons, protons and neutrons . These particles have different properties. Electrons are tiny, very light particles that have a negative electrical charge (-). Protons are much larger and heavier than electrons and have the opposite charge, protons have a positive charge. Neutrons are large and heavy like protons, however neutrons have no electrical charge. Each atom is made up of a combination of these particles.
Under normal circumstances, a conductor has no overall charge. Even though there are large numbers of free electrons available as charge carriers, for each free electron there is a corresponding proton within the atoms that make up the conductor. With equal numbers of protons and electrons, there is no overall charge.
Large - think they're C25+ The alkane molecules which have small numbers of carbon are Methane (CH4) Ethane (C2H6) etc - they have lower boiling points and are more useful as fuels etc.
Sort of... The general tendency is for a larger atom to be less stable. Above a certain point (after lead) no stable atoms are known to exist.Sort of... The general tendency is for a larger atom to be less stable. Above a certain point (after lead) no stable atoms are known to exist.Sort of... The general tendency is for a larger atom to be less stable. Above a certain point (after lead) no stable atoms are known to exist.Sort of... The general tendency is for a larger atom to be less stable. Above a certain point (after lead) no stable atoms are known to exist.
Yes: Relatively small numbers of them in a few laboratories on Earth and very large numbers of them in stars.