Please don't post under different names.
I will be happy to critique your thinking on this.
At time t=0, a 2kg particle has position vector r=(5.0m)i+(-8.0m)j relative to the origin. Its velocity just then is given by v=(-5.0t^2m/s)i. For the following answers, use t for the time. A) About the origin and for t>0, what is the particle's angular momentum? B) About the origin and for t>0, what is the torque acting on the particle? C) Repeat A and B for a point with coordinates (-7.0m, -4.0m, 0.0m) instead of the origin.
3 answers
L = R x m V
where R is position vector from reference point origin for a and b) to mass
V is velocity vector
x means cross or vector product
the x coordinate of the position vector is 5 at the start but changes with time because the thing has x velocity of -5t^2
integral = 5-(5/3) t^3
so for part a
L = (5-5t^3/3) i - 8 j)x(-5 t^2 i + 0 j)
(5-5t^3/3) -8 0
-5t^2 0 0 = -40 t^2 k
i j k
for part b
Torque = rate of change of angular momentum
dL/dt = d/dt(40 t^2 k) = 80 t
for part c
Rx = 5-5t^3/3 - (-7) = 12 - 5 t^3/3
Ry = -8 -(-4) = -4
Rz = 0 still
just do it again
where R is position vector from reference point origin for a and b) to mass
V is velocity vector
x means cross or vector product
the x coordinate of the position vector is 5 at the start but changes with time because the thing has x velocity of -5t^2
integral = 5-(5/3) t^3
so for part a
L = (5-5t^3/3) i - 8 j)x(-5 t^2 i + 0 j)
(5-5t^3/3) -8 0
-5t^2 0 0 = -40 t^2 k
i j k
for part b
Torque = rate of change of angular momentum
dL/dt = d/dt(40 t^2 k) = 80 t
for part c
Rx = 5-5t^3/3 - (-7) = 12 - 5 t^3/3
Ry = -8 -(-4) = -4
Rz = 0 still
just do it again
(5-5t^3/3) -8 0
-5t^2 0 0 = +40 t^2 k
i j k
-5t^2 0 0 = +40 t^2 k
i j k