0
Electrons are held around the nucleus of an atom by the electrostatic force of attraction between the positively-charged protons in the nucleus and the negatively-charged electrons. This force keeps the electrons in orbit around the nucleus in specific energy levels.
This question goes right to the heart of why quantum mechanics became the model for describing what happens at the microscopic level of matter and energy. At the beginning of the 1900's, it became apparent that the best way to model an atom was to conceive of a very dense central part (the nucleus) with a positive charge (and almost all the mass) surrounded at a relatively large distance (compared to the size of the nucleus) by a cloud of elementary, negatively-charged electrons. These very light electrons would be in orbit around the nucleus. The problem, though, was that according to the classical physics of the time, if an electrical charge is accelerating (as anything spinning around in an orbit does), then it must radiate energy (as light). A calculation shows that in that case, the electrons would spiral into the nucleus within a tiny fraction of a second. Since the electron clouds are responsible for chemical bonding, this means that all matter would simply collapse and the universe we live in would cease to exist. As we also know, this doesn't happen. So what's going on? In all its glory, the full answer (as we understand it) is very complicated and has lots of subtleties. Some very large-brained people worked on this problem and worked out a model that became known as quantum mechanics. It describes atomic phenomena to a precision never known before in science. It really works! However, it also has the trademark of being extremely mathematical and abstract. Still, I think I can tell you about one way about thinking about this stuff which is pretty close to the actual truth. It is well known that Musical Instruments operate by the principle of resonance. That is, they are so constructed that only certain sounds can be made by them. Sounds are waves and, as such, can be mathematically described by their size (loudness) and their frequency (pitch). Musical instruments will only make certain frequencies and combinations of frequencies. That is what makes a guitar or an organ sound as they do. Now back to the electrons in the atom. It was found that the electrons could not orbit any old way they wanted to. They could only orbit at certain fixed energies (just as the guitar can only emit certain frequencies). Again, the scientists used the idea of a wave to describe this, but in this case, the wave was about the probability of where the electron could be. One could not pin down the exact position in space for the particle, but one could know exactly what energy the electron could have. The bottom line is that the old picture of the electron spinning around in an orbit (like a tiny solar system) is simply not right. The electrons are allowed to exist at certain very precise energies, but their position is spread out, described by this "wave of probability." If you use enough outside energy to eject an electron from an atom, then this probability wave collapses to a much smaller size, thereby allowing you to know its position much better than within an atom. Then the electron tends to act a lot more like the billiard ball picture that we like to use. The usual question is - why not simply look very carefully inside the atom to "see" the electron? It turns out that in order to "see" the electron, one has to bump it (in physics lingo - change its momentum). But by bumping it, one changes its position in space. One finds that there is always a tradeoff - if you can get its position real good, then you've bumped too hard, and vice versa, one can bump very softly but then find that you cannot know its position so well. This is called the Heisenberg Uncertainty Principle (and is the source for the fictional Star Trek device known as the "Heisenberg Compensators"). Interestingly enough, there is a General Uncertainty Principle which actually defines, for a particular physical system, what things can and cannot be known completely. It turns out that one of things that one can know precisely is the energy of the electron in the atom. If you want to learn more about this at a fairly simple level I would recommend reading Isaac Asimov's "Understanding Physics" or Gerald Feinberg's "What Is The World Made Of?"
And On the Lighter Note.. It should be "Electrons"
The electromagnetic force that acts between the nucleus and the electron keep it in orbit about that nucleus. The nucleus is positive, and the electron is negative. In the world of electric charges, like charges repel and opposite charges attract. The electron is attracted to the nucleus where the protons, which are positive, hang out.
both centrifugal and electrostatic forces are responsible for the movement of electrons around the nucleus .
centrifugal force and electro static forces are quite opposite and equal hence the electrons are stable and are moving around the nucleus in specified orbits.
The centrifugal force comes from the vector energy Ev=mcV and the centrifugal force is mcDel.V = -mcv/r cos(VR )= -nhc/r2cos(VR). This centrifugal force is the basis for the redshift in electrical and gravitational orbits.
Electrostatic attractions keep electrons in their orbit around the nucleus of an atom. Since the nucleus is positively charge, the electrons which are negatively charged are attracted. The electrons are prevented from actually coming into contact with the nucleus via electron electron replusions amongst other things.
The electron-electron repulsion is knonw as the screening effect.Also,for the electron to remain in orbit around the nucleus,the electrostatic force muct balance the centrifugal force,-from Neil Bohr's postulate.
Coloumb attraction. Aka. electric charge. There is insufficient binding energy released to allow the electrons to "bind into" the protons in the nucleus to make neutrons.
It is called the electromagnetic force. It is described mathematically by Coulomb's Law.
The electrostatic force of attraction between the positively charged nucleus (positively charged protons within the nucleus) and the negatively charged electrons around it.
Add your answer:
Earn +20 pts
What holds electrons in their shells?
Electrons are held in their energy levels, or shells, by the attractive force between the positively charged nucleus and the negatively charged electrons. This force, known as electrostatic attraction, keeps electrons in orbit around the nucleus.
Are the number of electrons in the nucleus of an atom that element's atomic number?
There are no electrons in the nucleus of an atom, the electrons are in the orbitals around and outside the nucleus.There are no electrons in the nucleus of an atom, the electrons are in the orbitals outside and around the nucleus.
What is the energy called that attracts the electrons to the nucleus of an atom?
The energy that attracts electrons to the nucleus of an atom is called the electromagnetic force. This force arises due to the interaction between the positively charged protons in the nucleus and the negatively charged electrons. It is responsible for holding the electrons in orbit around the nucleus.
Boron has how many electrons in the nuclei?
No atom has its electrons in its nucleus, and boron has five electrons around its nucleus.
What particles might be found in shells around a nucleus?
The particles found in the area surrounding the nucleus are called electrons. Electrons are attracted to the protons in the nucleus, but are repelled from other electrons. This is why they can be found orbiting the nucleus.
What force holds electrons around a nucleus?
The force that holds electrons around a nucleus is the electrostatic force of attraction between the positively charged nucleus and the negatively charged electrons. This force is known as the electromagnetic force and is responsible for keeping the electrons in orbit around the nucleus.
What force holds the electrons around the nucleas?
Electrostatic force betweeen positive nucleus and negatively charged electrons.
What holds the protons in the atomic nucleus together?
The nucleus holds both neutrons and electrons in it.
What holds earth together Think of the earth as the nucleus of an atom. And around the earth are electrons. These electrons create magnetic energy that holds earth together.?
Electrons produce a magnetic force that holds earth together and trees
What is a nuecleus orbited by?
A nucleus is orbited by electrons in an atom. Electrons are negatively charged particles that move around the positively charged nucleus in specific energy levels or orbits. The interaction between the electrons and the nucleus holds the atom together.
Which parts of the atom move around the nucleous?
Electrons move around the nucleus of an atom. Protons and neutrons are located in the nucleus and do not move around the nucleus like electrons do.
What holds electrons in their shells?
Electrons are held in their energy levels, or shells, by the attractive force between the positively charged nucleus and the negatively charged electrons. This force, known as electrostatic attraction, keeps electrons in orbit around the nucleus.
Is electrons found inside the nucleus?
They are not in the nucleaus, they orbit around the nucleus.
Does electrons make up an atom nucleus?
No, the electrons are around the nucleus, not in the nucleus.
Are electrons located in the layer around the nucleus?
Electrons are located in electron orbitals surrounding the nucleus of an atom, rather than in distinct layers. These orbitals represent the areas where electrons are most likely to be found and are organized into different energy levels based on their distance from the nucleus.
Are electrons next to the nucleus?
No, electrons are around nucleus but at a great distance.
Are the number of electrons in the nucleus of an atom that element's atomic number?
There are no electrons in the nucleus of an atom, the electrons are in the orbitals around and outside the nucleus.There are no electrons in the nucleus of an atom, the electrons are in the orbitals outside and around the nucleus.
