Editing Atomic nucleus

Warning: You are not logged in. Your IP address will be publicly visible if you make any edits. If you log in or create an account, your edits will be attributed to your username, along with other benefits.

The edit can be undone. Please check the comparison below to verify that this is what you want to do, and then save the changes below to finish undoing the edit.
Latest revision Your text
Line 1: Line 1:
[[Category: Physics]]
+
[[Category:Physics]]
 
== Explanation ==
 
== Explanation ==
 
An atomic nucleus is the center of an [[atom]], made up of [[proton|protons]] and [[neutron|neutrons]]. These are together known as nucleons. The protons and neutrons in a nucleus are held together by the [[nuclear force]], which is a remnant of the strongest fundamental force in nature, the [[strong interaction]]. The nucleus makes up most of the mass of the atom.
 
An atomic nucleus is the center of an [[atom]], made up of [[proton|protons]] and [[neutron|neutrons]]. These are together known as nucleons. The protons and neutrons in a nucleus are held together by the [[nuclear force]], which is a remnant of the strongest fundamental force in nature, the [[strong interaction]]. The nucleus makes up most of the mass of the atom.
Line 5: Line 5:
 
== Frequently Asked Questions ==
 
== Frequently Asked Questions ==
 
=== Why electrons don’t fall into the nucleus due to attraction? ===
 
=== Why electrons don’t fall into the nucleus due to attraction? ===
[[Electron]]s tend to stay away from the nucleus because it would violate the [[uncertainty principle]]. If the electron is confined inside a space as small as the nucleus, then its position and momentum could be determined, which is impossible. So that doesn’t actually happen when you try to confine an electron inside a nucleus. According to the uncertainty principle, the energy of the electron will increase as it moves closer to the nucleus. This increases the momentum uncertainty and tends to push the electron away from the nucleus, battling the electrostatic force. The point at which these two cancels out each other will be the electron’s stable configuration in an atom. But there is a special type of decay called as the beta plus decay, where a proton-rich nucleus would absorb an electron to decay itself into a neutron by emitting a positron and a neutrino.
+
[[Electron]]s tend to stay away from the nucleus because it would violate the [[uncertainty principle]]. If the electron is confined inside a space as small as the nucleus, then its position and momentum could be determined, which is impossible. So that doesn’t actually happen when you try to confine an electron inside a nucleus. According to the uncertainty principle, the energy of the electron will increase as it moves closer to the nucleus. This increases the momentum uncertainty and tends to push the electron away from the nucleus, battling the electrostatic force. The point at which these two cancel out each other will be the electron’s stable configuration in an atom. But there is a special type of decay called as the beta plus decay, where a proton-rich nucleus would absorb an electron to decay itself into a neutron by emitting a positron and a neutrino.
  
 
=== What happens when you split the atomic nucleus? ===
 
=== What happens when you split the atomic nucleus? ===
 
[[Nuclear fission]] happens. When the atomic nucleus is split, a tremendous amount of [[energy]] is released, forming two lighter nuclei in the process. A well-known example of a fissile element is [[uranium]] <sup>235</sup>U, which when bombarded with neutrons split into two lighter nuclei. The total mass before splitting is higher than that of the combined mass of the two nuclei and any neutrons emitted. This difference is mass will be the energy of the fission reaction, and it will be enormous. When the emitted neutrons are made to bombard more <sup>235</sup>U nuclei, there will be a [[chain reaction]] that keeps on splitting more <sup>235</sup>U nuclei, exponentially releasing immense amounts of energy.
 
[[Nuclear fission]] happens. When the atomic nucleus is split, a tremendous amount of [[energy]] is released, forming two lighter nuclei in the process. A well-known example of a fissile element is [[uranium]] <sup>235</sup>U, which when bombarded with neutrons split into two lighter nuclei. The total mass before splitting is higher than that of the combined mass of the two nuclei and any neutrons emitted. This difference is mass will be the energy of the fission reaction, and it will be enormous. When the emitted neutrons are made to bombard more <sup>235</sup>U nuclei, there will be a [[chain reaction]] that keeps on splitting more <sup>235</sup>U nuclei, exponentially releasing immense amounts of energy.
 
=== How could the atomic radius of the atomic nucleus be defined? ===
 
The density of the atomic nucleus is usually concentrated towards the centre where the nucleons exist. An approximate radius of that dense region can be found by using the formula - '''R = R<sub>0</sub>A<sup>1/3</sup>''', where '''R<sub>0</sub>''' is 1.2 fm, and '''A''' is the [[Atomic_mass#What.27s_the_difference_between_atomic_mass_and_mass_number.3F|atomic mass number]]. Some specific cases like the [[halo nucleus]] of [[lithium]], the radius of the nucleus will be higher, and hence this formula fails. In such cases experimental methods like x-ray [[spectroscopy]] are used.
 
Help
Cancel

Swyde is a collaborative science project that involves other members of the Swyde community members editing and refining your contributions here. By submitting your content, you agree to these terms and confirm that the above content belongs to you, and if copied, you have received permissions from the copyright holder to use it here. All your contributions will be licensed under the Creative Commons license. See copyrights for more details.

Retrieved from "http://swyde.com/s/Atomic_nucleus"