If `s=(1)/(2)t^(3)-6t`, then the find the acceleration at time when the velocity tends to zero.

Displacement s of a particle at time t is expressed as s = (1)/(2) t^(3) - 6t . Find the acceleration at the time when the velocity vanishes (i.e., velocity tends to zero).

Displacement s of a particle at time t is expressed as s=(1)/(2)t^(3)-6t. Find the acceleration at the time when the velocity vanishes (i.e.,velocity tends to zero).

Displacement s of a particle at time t is expressed as s=1/2t^3-6t . Find the acceleration at the time when the velocity vanishes (i.e., velocity tends to zero).

Displacement s of a particle at time t is expressed as s=1/2t^3-6t . Find the acceleration at the time when the velocity vanishes (i.e., velocity tends to zero).

Displacement s of a particle at time t is expressed as s=1/2t^3-6t . Find the acceleration at the time when the velocity vanishes (i.e., velocity tends to zero).

Displacement s of a particle at time t is expressed as s=1/2t^3-6t . Find the acceleration at the time when the velocity vanishes (i.e., velocity tends to zero).

Displacement s of a particle at time t is expressed as s=1/2t^3-6tdot Find the acceleration at the time when the velocity vanishes (i.e., velocity tends to zero).

Displacement s of a particle at time t is expressed as s=1/2t^3-6tdot Find the acceleration at the time when the velocity vanishes (i.e., velocity tends to zero).

A particle moves along a line according to the law s(t)=2t^(3)-9t^(2)+12t-4 , where tge0 . Find the particle's acceleration each time the velocity is zero.