mkbh_10 said:for n=2 & l=1 we have P orbital for which magnetic quantum no. can take values -1,0,1 , now in p orbital we have 2Px, 2Py &2Pz each corresponding to vale of m like 2Px for m=-1 and so on , is this correct or 2Px can be represented by 0 0r 1 also .
cadnr said:From http://www.3rd1000.com/chem301/chem301b.htm :
Orbitals with subshell quantum number l = 1 are called p orbitals. Since the magnetic quantum number m can be -1, 0, or +1 when the value of the subshell quantum number l is one, p orbitals come in sets of three. In each set, one of the orbitals is aligned along each of the three mutually perpendicular axes of the atom; these axes are traditionally designated x, y, and z. The three 2p orbitals are correspondingly designated 2px, 2py, and 2pz
monish said:I think there's a slightly different convention among chemists and physicists for describing the orbitals.
The chemists take three mutually perpendicular orbitals along the x, y, and z axes. Physicists take the z orbital, and then mix the chemists' x and y orbitals into combinations which are basicaly x + iy and x - iy. Now they have three states that are symetrical about the z axis and whose spin is +1, 0, and -1.
A similar thing is done in the d orbitals. The pictures in the chemistry books show orbitals with lobes at 45 degrees, others at 90 degrees, and one with a donut and two lobes. The last one is the one shared with physicists, symetrical about the z axis. The physicists then take mixtures of the chemist's orbitals to get: a pair with spin +/-2, and a pair with spin +/-1 AND a nodal surface through the xy plane (the "equator").
DaTario said:Very interesting. But, then, according to what you said, the answer to the question is that m = 1 does not correspond to what we call Px (or Py).
DaTario said:I feel satisfaction due to this learning moment. Thank you.
Sincerely
DaTario
In atomic orbitals, n represents the principal quantum number and determines the size of the orbital. A higher value of n indicates a larger orbital. Meanwhile, l represents the angular momentum quantum number and determines the shape of the orbital. A value of l=1 corresponds to the P orbital, which has a dumbbell shape and is oriented along the x, y, or z axis.
A P orbital is one of the three types of atomic orbitals, along with S and D orbitals. It has a dumbbell shape with two lobes, and it is oriented along the x, y, or z axis. This is different from S orbitals, which are spherical in shape, and D orbitals, which have four or more lobes.
The magnetic quantum number, represented by the symbol m, determines the orientation of the orbital in space. For a P orbital, there are three possible values of m depending on its orientation along the x, y, or z axis. These values are -1, 0, and 1, corresponding to the three dumbbell lobes.
The magnetic quantum number plays a crucial role in determining the electron configuration of an atom. It specifies the number and type of orbitals occupied by electrons in a particular energy level. For example, in the n=2 energy level, there are three P orbitals with different orientations, each of which can hold a maximum of 2 electrons with opposite spins.
P orbitals play a significant role in the formation of covalent bonds between atoms, which determine the shape of molecules. When two atoms bond, their P orbitals can overlap to form a molecular orbital, resulting in a bond between the atoms. The orientation of the P orbitals involved in the bonding determines the shape of the molecule.