The octahedral complex of a metal ion `M^(3+)` with four monodentate ligands `L_(1),L_(2),L_(3)` and `L_(4)` absorb wavelengths in the region of red,green, yellow and bule, respectively The increasing order of ligand strengh of the four ligands is

Homoleptic octahedral complexes of a metal ion ' M^(3+) ' with three monodentate ligands L_(1),L_(2) and L_(3) absorb wavelengths in the region of green, blue and red respectively. The increasing order of the ligand strength is :

Graph of a function y=f(x) is shown in the adjacent figure.Four limits l_(1),l_(2),l_(3) and I_(4), are given as:

Consider atoms H, He^(+), Li^(++) in their ground states. If L_(1), L_(2) and L_(3) are magnitude of angular momentum of their electrons about the nucleus respectively then:

In a laboratory four convex lenses L_(1), L_(2), L_(3) and L_(4) of focal lengths 2,4,6 and 8 cm respectively are available. Two of these lenses form a telescope of length 10 cm and magnifying power 4 . The objective and eye lenses are

For an octahedral complex MX_4Y_2 (M=a transition metal, X and Y are monodenate achiral ligands), the correct statement, among the following, is

Number of units of three different products P_(1),P_(2) and P_(3) produced (nits in hundreds) at four different locations (L_(1),L_(2)=L_(3) and L_(4)) By what approximate percent is the number of units of P1 poroduced more than the number of units of P3 produed in the four locations together ?

When a string is divided into three segments of lengths l_(1),l_(2) and l_(3) the fundamental frequencies of these three segments are v_(1), v_(2) and v_(3) respectively. The original fundamental frequency (v) of the string is