Answer
$${a_N} = - 10{\bf{k}}{\text{ and }}{a_T} = 0$$
Work Step by Step
$$\eqalign{
& {\bf{r}}\left( t \right) = \left\langle {10\cos t, - 10\sin t} \right\rangle \cr
& {\text{Calculate }}{\bf{v}}\left( t \right){\text{, }}\left| {{\bf{v}}\left( t \right)} \right|{\text{ and }}{\bf{a}}\left( t \right) \cr
& {\bf{v}}\left( t \right) = {\bf{r}}'\left( t \right) \cr
& {\bf{v}}\left( t \right) = \left\langle { - 10\sin t, - 10\cos t} \right\rangle \cr
& \left| {{\bf{v}}\left( t \right)} \right| = \sqrt {100{{\sin }^2}t + 100{{\cos }^2}t} \cr
& \left| {{\bf{v}}\left( t \right)} \right| = 10 \cr
& \cr
& {\bf{a}}\left( t \right) = {\bf{v}}'\left( t \right) \cr
& {\bf{a}}\left( t \right) = \left\langle { - 10\cos t,10\sin t} \right\rangle \cr
& \cr
& {\text{Find the components of acceleration: }}{a_N}{\bf{N}} + {a_T}{\bf{T}}, \cr
& {\text{Where }}{a_N} = \kappa {\left| {\bf{v}} \right|^2} = \frac{{\left| {{\bf{v}} \times {\bf{a}}} \right|}}{{\left| {\bf{v}} \right|}}{\text{ and }}{a_T} = \frac{{{d^2}s}}{{d{t^2}}} = \frac{{{\bf{v}} \cdot {\bf{a}}}}{{\left| {\bf{v}} \right|}} \cr
& {\text{Then}}{\text{,}} \cr
& {\bf{v}} \times {\bf{a}} = \left\langle { - 10\sin t, - 10\cos t} \right\rangle \times \left\langle { - 10\cos t,10\sin t} \right\rangle \cr} $$
\[{\mathbf{v}} \times {\mathbf{a}} = \left| {\begin{array}{*{20}{c}}
{\mathbf{i}}&{\mathbf{j}}&{\mathbf{k}} \\
{ - 10\sin t}&{ - 10\cos t}&0 \\
{ - 10\cos t}&{10\sin t}&0
\end{array}} \right|\]
$$\eqalign{
& {\bf{v}} \times {\bf{a}} = \left( {0 - 0} \right){\bf{i}} - \left( {0 - 0} \right){\bf{j}} + \left( { - 100{{\sin }^2}t - 100{{\cos }^2}t} \right){\bf{k}} \cr
& {\bf{v}} \times {\bf{a}} = - 100{\bf{k}} \cr
& \left| {{\bf{v}} \times {\bf{a}}} \right| = 100 \cr
& {a_N} = \frac{{\left| {{\bf{v}} \times {\bf{a}}} \right|}}{{\left| {\bf{v}} \right|}} = \frac{{100}}{{10}} \cr
& {a_N} = 10 \cr
& \cr
& and \cr
& \cr
& {\bf{v}} \cdot {\bf{a}} = \left\langle { - 10\sin t, - 10\cos t} \right\rangle \cdot \left\langle { - 10\cos t,10\sin t} \right\rangle \cr
& {a_T} = \frac{{{\bf{v}} \cdot {\bf{a}}}}{{\left| {\bf{v}} \right|}} \cr
& {a_T} = 0 \cr
& \cr
& {a_N} = - 10{\bf{k}}{\text{ and }}{a_T} = 0 \cr} $$
