Sounds like you're asked to find [tex]a[/tex] such that
[tex]\displaystyle\sum_{k=2}^4\mathbb P(k)=\mathbb P(2)+\mathbb P(3)+\mathbb P(4)=1[/tex]
In other words, find [tex]a[/tex] that satisfies
[tex]a^2+a^3+a^4=1[/tex]
We can factorize this as
[tex]a^4+a^3+a^2-1=a^3(a+1)+(a-1)(a+1)=(a+1)(a^3+a-1)=0[/tex]
In order that [tex]\mathbb P(k)[/tex] describes a probability distribution, require that [tex]\mathbb P(k)\ge0[/tex] for all [tex]k[/tex], which means we can ignore the possibility of [tex]a=-1[/tex].
Let [tex]a=y+\dfrac xy[/tex].
[tex]a^3+a-1=\left(y+\dfrac xy\right)^3+\left(y+\dfrac xy\right)-1=0[/tex]
[tex]\left(y^3+3xy+\dfrac{3x^2}y+\dfrac{x^3}{y^3}\right)+\left(y+\dfrac xy\right)-1=0[/tex]
Multiply both sides by [tex]y^3[/tex].
[tex]y^6+3xy^4+3x^2y^2+x^3+y^4+xy^2-y^3=0[/tex]
We want to find [tex]x\neq0[/tex] that removes the quartic and quadratic terms from the equation, i.e.
[tex]\begin{cases}3x+1=0\\3x^2+x=0\end{cases}\implies x=-\dfrac13[/tex]
so the cubic above transforms to
[tex]y^6-y^3-\dfrac1{27}=0[/tex]
Substitute [tex]y^3=z[/tex] and we get
[tex]z^2-z-\dfrac1{27}=0\implies z=\dfrac{9+\sqrt{93}}{18}[/tex]
[tex]\implies y=\sqrt[3]{\dfrac{9+\sqrt{93}}{18}}[/tex]
[tex]\implies a=\sqrt[3]{\dfrac{9+\sqrt{93}}{18}}-\dfrac13\sqrt[3]{\dfrac{18}{9+\sqrt{93}}}[/tex]
