One atom of Carbon-12 (6p+ and 6n0) is assigned a mass of 12 uv
An isotope depends on the number of neutrons in the atom. If you consider various isotopes of a particular element, the proton number does not change. Examples: Carbon 12: 6n, 6p Carbon 13: 7n, 6p Hydrogen 1 (protium): 1p Hydrogen 2 (deuterium): 1n, 1p
Isotopes are not designated by atomic number. The element with atomic number 88 is Radium. Because different isotopes of the same element vary by the number of neutrons in the nucleus, the isotope is designated by the atomic mass. For example, most carbon atoms have six protons, so the atomic number is 6. The most common isotope has 6 neutrons, so the isotope (Carbon 12) is the same as the atomic mass, 12 (6P + 6N), but there are isotopes with atomic masses of 13 (6P + 7N) and 14 (6P + 8N). Carbon 14 is familar as a dating tool when organic compounds are present. The only isotope given for Radium in the periodic table is 266.
The heaviest known atom is Oganesson (Og), which has an atomic number of 118. In the context of electron configuration, the p sublevel can hold a maximum of six electrons and is present in elements from groups 13 to 18. For Oganesson, the highest occupied p sublevel is the 6p sublevel, which can contain up to six electrons, but it is only partially filled in this element. Thus, while Oganesson has a 6p sublevel, the number of electrons in this sublevel is subject to ongoing research and may not be fully determined.
The electron configuration 6s² 4f¹⁴ 5d¹⁰ 6p² corresponds to the element lead (Pb), which has an atomic number of 82. In this configuration, the 6p² indicates that lead has two electrons in its outermost p subshell, typical for the group 14 elements in the periodic table.
For this question the exact formula has to be known, distinguishing the four different chloromethanes: mono-, di-, tri- and tetra- chloromethane, in which equal H atoms are substituted by Cl atoms around the (one) centered C atom.p= number of protons, n= number of neutrons, e= number of electronsper C atom: 6p, 6n, 6eper H atom: 1p, 0n, 1eper Cl atom: 17p, (18n or 20n)= average 18.45n, 17eThen add up pro atom p / n / e / values for one of these compoundsExample:CH3Cl : 26p, 24.45n, 26e in monochloromethane (methylchloride)
An isotope depends on the number of neutrons in the atom. If you consider various isotopes of a particular element, the proton number does not change. Examples: Carbon 12: 6n, 6p Carbon 13: 7n, 6p Hydrogen 1 (protium): 1p Hydrogen 2 (deuterium): 1n, 1p
Isotopes are not designated by atomic number. The element with atomic number 88 is Radium. Because different isotopes of the same element vary by the number of neutrons in the nucleus, the isotope is designated by the atomic mass. For example, most carbon atoms have six protons, so the atomic number is 6. The most common isotope has 6 neutrons, so the isotope (Carbon 12) is the same as the atomic mass, 12 (6P + 6N), but there are isotopes with atomic masses of 13 (6P + 7N) and 14 (6P + 8N). Carbon 14 is familar as a dating tool when organic compounds are present. The only isotope given for Radium in the periodic table is 266.
The heaviest known atom is Oganesson (Og), which has an atomic number of 118. In the context of electron configuration, the p sublevel can hold a maximum of six electrons and is present in elements from groups 13 to 18. For Oganesson, the highest occupied p sublevel is the 6p sublevel, which can contain up to six electrons, but it is only partially filled in this element. Thus, while Oganesson has a 6p sublevel, the number of electrons in this sublevel is subject to ongoing research and may not be fully determined.
In all p sublevels there are 3 sublevels, including 6p.
This might be the stable isotope of beryllium, 9Be: alpha + 9Be -> 12C + n alpha: 2p + 2n Be: 4p + 5n left side: 6p + 7n C: 6p + 6n right side: 6p + 7n Incidentally, this would not be a decay, rather an transfer reaction, I think.
The electron configuration 6s² 4f¹⁴ 5d¹⁰ 6p² corresponds to the element lead (Pb), which has an atomic number of 82. In this configuration, the 6p² indicates that lead has two electrons in its outermost p subshell, typical for the group 14 elements in the periodic table.
For this question the exact formula has to be known, distinguishing the four different chloromethanes: mono-, di-, tri- and tetra- chloromethane, in which equal H atoms are substituted by Cl atoms around the (one) centered C atom.p= number of protons, n= number of neutrons, e= number of electronsper C atom: 6p, 6n, 6eper H atom: 1p, 0n, 1eper Cl atom: 17p, (18n or 20n)= average 18.45n, 17eThen add up pro atom p / n / e / values for one of these compoundsExample:CH3Cl : 26p, 24.45n, 26e in monochloromethane (methylchloride)
6p
The electron configuration for lead (Pb), which has an atomic number of 82, is normally written as [Xe] 4f² 5d¹⁰ 6s² 6p². When lead is in the +2 oxidation state (Pb²⁺), it loses two electrons, typically from the 6p subshell. Therefore, the electron configuration for Pb²⁺ is [Xe] 4f² 5d¹⁰ 6s².
6p divide by 3p = 2
3p + 6p = (3 + 6)p = 9p
algebra8p +4 = 10 +6p+8p - 6p = +10 - 42p = 6p = 3