A block of mass m is held in equilibrium against a vertical wall by a horizontal force. If the coefficient of friction between the wall and the block is µ, the minimum value of the horizontal force is
µmg
(1-µ)mg
(1+µ)mg
mg/µ
Explanation
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The answer is D. mg/u
The horizontal force (F) is equivalent to the normal reaction (R), ie *F=R* = mg..
but The frictional force (Fr) acting vertically upward = the limiting frictional force (u) × normal reaction (R)
ie Fr = u×R.
To balance the vertical upward force(Fr) and vertical downward for (Mg)
Fr=mg. but Fr=uR
uR = mg... recall R=F
uF=mg
F = mg/u
Option D....
the answer is c
horizontal force= frictional force+weight of object
mg+umg=mg(1+u)
B
the question clearly stated at equilibrium
meaning frictional force=normal reaction
uf=mg
f=mg/u
option D is legit 
The answer should be B.
The horizontal force, F, acting on the block must be equal to at least the weight ( mg ) of the Block to keep it in equilibrium. So F ≥ mg
μ = Fr/R
Frictional Force Fr = μR Fr = μmg
Since frictional force, Fr, is already doing part of the work of keeping the block at equilibrium ( acting in opposition, acting vertically upwards while the weight of the block acts vertically downwards, trying to keep the Block from falling down ) then the minimum Force required to keep the block steady in equilibrium is F = mg - Fr
F = mg - μmg
F = mg ( 1 - μ )
The answer should be B.
The horizontal force, F, acting on the block must be equal to at least the weight ( mg ) of the Block to keep it in equilibrium. So F ≥ mg
μ = Fr/R
Frictional Force Fr = μR. Fr = μmg
Since frictional force, Fr, is already doing part of the work of keeping the block at equilibrium ( acting in opposition, acting vertically upwards while the weight of the block acts vertically downwards, Frictional Force is trying to keep the Block from falling down ) then the minimum Force required to keep the block steady in equilibrium is F = mg - Fr
F = mg - μmg
F = mg ( 1 - μ )
