P+ -e= -P
2P + 5Cl2 -> 2PCL5
If there is an excess of air, the reaction should produce diphosphorus pentoxide as its only product. If additionally the phosphorus molecule is simply a phosphorus atom, the balanced equation is: 4 P + 5 O2 -> 2P2O5. If phosphorus is considered to form a tetraatomic molecule, the equation would be: P4 + 5 O2 -> 2 P2O5
p2+5o2 to give p2o10
According to my science teacher it's: P4 + (5)O2 = (2)P2O5 (The brackets are the balancing values).
Phosphorus burns at very high temperatures, about 1600-1800oC, phosphorus is the red tip at the end of a kitchen match. The chemical formula for the combustion of Phosphorus is: P4 + 5 O2 yields P4O10
Electron affinity is the energy released when an electron is added to a neutral atom to form a negative ion. It measures an atom's attraction for electrons. A higher electron affinity indicates a stronger tendency for an atom to gain an electron.
If you express your answer as a chemical equation with all forms given, you would get: Mg+(g) + e- -> Mg (g)
The word equation for the reaction between calcium and phosphorus is: calcium + phosphorus → calcium phosphide.
The eigenvalues of an electron in a three-dimensional potential well can be derived by solving the Schrödinger equation for the system. This involves expressing the Laplacian operator in spherical coordinates, applying boundary conditions at the boundaries of the well, and solving the resulting differential equation. The eigenvalues correspond to the energy levels of the electron in the potential well.
If you are meaning phosphorus tribromide then it is PBr3
The balanced chemical equation for phosphorus reacting with oxygen to form phosphorus pentoxide is: 4 P + 5 O2 -> P4O10
The chemical equation for the reaction of phosphorus with oxygen to form phosphorus pentoxide is: 4 P + 5 O2 → P4O10.
2P + 5Cl2 -> 2PCL5
You r question does not make sense, as it ends in 'and?'. However, Phosphorus oxide is usually named as 'phosphorus pentoxide. The formula being 'P2O5'. Phosphorus pentoxide often form the dimer 'P4O10',
p4+502=p4010
This is the Schrodinger equation from 1925-1926.
Electron clouds in an atom are described by the electron probability distribution function, which is not a single equation but rather a three-dimensional probability density function. It is determined by solving the Schrödinger equation for the electron in the atom. This function gives the probability of finding an electron at a particular location in space around the nucleus.