The roots of polynomial $ p(x) $ are:
$$ \begin{aligned}x_1 &= -1\\[1 em]x_2 &= 1.3549\\[1 em]x_3 &= 4.5495\\[1 em]x_4 &= 0.0478+1.5063i\\[1 em]x_5 &= 0.0478-1.5063i \end{aligned} $$Step 1:
Use rational root test to find out that the $ \color{blue}{ x = -1 } $ is a root of polynomial $ x^5-5x^4+3x^3-5x^2+14 $.
The Rational Root Theorem tells us that if the polynomial has a rational zero then it must be a fraction $ \dfrac{ \color{blue}{p}}{ \color{red}{q} } $, where $ p $ is a factor of the constant term and $ q $ is a factor of the leading coefficient.
The constant term is $ \color{blue}{ 14 } $, with a single factor of 1, 2, 7 and 14.
The leading coefficient is $ \color{red}{ 1 }$, with a single factor of 1.
The POSSIBLE zeroes are:
$$ \begin{aligned} \dfrac{\color{blue}{p}}{\color{red}{q}} = & \dfrac{ \text{ factors of 14 }}{\text{ factors of 1 }} = \pm \dfrac{\text{ ( 1, 2, 7, 14 ) }}{\text{ ( 1 ) }} = \\[1 em] = & \pm \frac{ 1}{ 1} \pm \frac{ 2}{ 1} \pm \frac{ 7}{ 1} \pm \frac{ 14}{ 1} ~~ \end{aligned} $$Substitute the possible roots one by one into the polynomial to find the actual roots. Start first with the whole numbers.
We can see that $ p\left( -1 \right) = 0 $ so $ x = -1 $ is a root of a polynomial $ p(x) $.
To find remaining zeros we use Factor Theorem. This theorem states that if $ \dfrac{p}{q} $ is root of the polynomial then the polynomial can be divided by $ \color{blue}{qx − p} $. In this example we divide polynomial $ p $ by $ \color{blue}{ x+1 }$
$$ \frac{ x^5-5x^4+3x^3-5x^2+14}{ x+1} = x^4-6x^3+9x^2-14x+14 $$Step 2:
The next rational root is $ x = -1 $
$$ \frac{ x^5-5x^4+3x^3-5x^2+14}{ x+1} = x^4-6x^3+9x^2-14x+14 $$Step 3:
Polynomial $ x^4-6x^3+9x^2-14x+14 $ has no rational roots that can be found using Rational Root Test, so the roots were found using quartic formulas.