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Question
An object is falling freely under gravitational force. Its velocity after travelling a distance h is v. If v depends upon gravitational acceleration g and distance, prove with the dimensional analysis that v = k`sqrt"gh"` where k is a constant.
Solution
Given = v = k`sqrt"gh"`
v ∝ gh
v = kgahb ...(i)
| Quantity | Dimension |
| Velocity (v) | [L1 M0 T-1] |
| Height (h) | [L1 M0 T0] |
| Gravitational acceleration (g) |
[L1 M0 T-2] |
k being constant is assumed to be dimensionless.
v = k ga hb
[L1 M0 T-1] = k `["L"^1 "M"^0 "T"^-2]^"a" ["L"^1 "M"^0 "T"^0]^"b"`
[L1 M0 T-1] = k `["L"^"a" "M"^0 "T"^ -"2a"] ["L"^"b" "M"^0 "T"^0]`
[L1 M0 T-1] = k `["L"^("a + b") "M"^0 "T"^(- 2"a")]`
∴ a + b = 1 ...(ii)
∴ - 2a = - 1
⇒ a = `bb(1/2)`
Put a = `1/2` in equation (ii)
∴ a + b = 1
⇒ `1/2` + b = 1
⇒ b = `1 - 1/2`
⇒ b = `2/2 -1/2`
⇒ b = `bb(1/2)`
∴ v = k ga hb
v = k `"g"^(1/2) "h"^(1/2)`
v = k`sqrt"gh"`
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