In theory all elements have all the orbitals. Zinc has electrons in four of them.
There are 9 occupied orbitals in a phosphorus atom's ground state: one 1s orbital, one 2s orbital, three 2p orbitals, one 3s orbital, and three 3p orbitals.
The electrons in beryllium occupy a total of four orbitals. Beryllium has 4 electrons, which fill the 1s, 2s, and 2p orbitals.
If the question is an attempt to ask "How many orbitals are there with principal quantum number n = 2", then 4 orbitals which can hold a total of 8 electrons.
3 The electron configuration for nitrogen is 1s22s22p3.
Iodine has 7 electron-containing orbitals, corresponding to its 7 valence electrons in the p subshell. These orbitals can hold a maximum of 2 electrons each.
5 orbitals
7 Orbitals
[Kr] 5s2 4d2
When two atomic orbitals interact, they produce two molecular orbitals.
16 orbitals
Ne has three p-orbitals.
There are 4 orbitals in H2O , one s and 3 p
Beryllium has four orbitals in its electron configuration.
The 3rd period contains 2 of the 3 orbitals for the third sublevel. It has the s and p orbitals in it.
There is one s orbital and three p orbitals and five d orbitals in the third energy level.
All p sublevels contain three orbitals, including the 4p sublevel.
The number of molecular orbitals in the system depends on the number of atomic orbitals that are combined. If two atomic orbitals combine, they form two molecular orbitals: a bonding orbital and an antibonding orbital. So, in general, the number of molecular orbitals in a system is equal to the number of atomic orbitals that are combined.