The correct options are
A 5→1
D 7→5
Let:
initial state (1) have orbit number =n1
final state (2) have orbit number =n2
Bohr's radius for nth orbit, (rn)=0.529[n2Z]∘A
where, n=Orbit number, Z=Atomic number
Given: Difference in orbit radius =r1−r2=24×radius of 1st Bohr orbit
As the element taken is hydrogen, hence Z=1
For 1st Bohr orbit, n=1
Radius for first Bohr orbit, r0=0.529 ∘A
Hence, rn1−rn2=24×r0=12.7 ∘A
For n1,
rn1=0.529[n21Z]=0.529 n21 ...(i)
For n2,
rn2=0.529[n22Z]=0.529 n22 ...(ii)
Taking the difference of equations 1 and 2, we get
rn1−rn2=(0.529 n21)−(0.529 n22)
=0.529 (n21−n22)
⇒12.7=0.529 (n21−n22)
⇒(n21−n22)=12.70.529=24
⇒(n1−n2)(n1+n2)=24
Now there are 3 possibilities:
1. (n1−n2)(n1+n2)=12×2
2. (n1−n2)(n1+n2)=6×4
3. (n1−n2)(n1+n2)=8×3
For case (1),
Let (n1−n2)=2 and (n1+n2)=12
Upon solving, we get
n1=7 and n2=5
Hence the transition would be 7→5
For case (2),
Let (n1−n2)=4 and (n1+n2)=6
Upon solving, we get
n1=5 and n2=1
Hence the transition would be 5→1
For case (3),
Let (n1−n2)=3 and (n1+n2)=8
Upon solving, we get
n1 = 5.5 and n2 = 2.5 which are not possible
Only 7→5 and 5→1 transitions are the correct answers.