Final answer:
In crystal field theory, if any orbital within a set is asymmetric with respect to a C2 axis, the whole set is considered asymmetric. The e1 and e2 labels for d orbitals depend on their symmetry properties and do not change with different orientations of the axis. Crystal field splitting energy affects the distribution of energies within the d orbitals without changing their total energy.
Step-by-step explanation:
Understanding Symmetry and Crystal Field Splitting in d Orbitals
When examining the symmetry of d orbitals in relation to a C2 axis in a crystal field, it is indeed the case that if even one orbital in a group is asymmetric concerning the C2 element, then the entire group of orbitals is considered asymmetric. This pertains to how the orbitals transform under the operation of the symmetry element (such as a C2 axis), which is perpendicular to the principal axis of an octahedral complex.
For the second concern regarding e1 and e2 sets in linear complexes, it's important to consider the d orbitals' orientations: d(xz) and d(yz) are labeled e1, while d(x2-y2) and d(xy) are labeled e2. This labeling is based on the symmetry properties of these orbitals with respect to the C2 axis that is preserved in the complex. It might seem confusing because changing the orientation of your C2 axis could appear to alter the symmetries, but for proper symmetry assignments, you should keep the axis consistent and not change it arbitrarily. The labels e1 and e2 reflect distinct symmetry properties relative to this axis, and thus, they do not change even when considering different C2 axes in the complex.
The difference in energy between eg and t2g sets of orbitals is termed the crystal field splitting energy (Δ), and though it redistributes the energies of the d orbitals, it does not change the total energy of all five d orbitals. This concept is essential for explaining the electronic structure and properties of coordination complexes.