Question 1163225
.


            Since you want to understand concepts, I want to share my vision.



<pre>
(1)  The problem is about the size of the cube edge.

     So, it is about real number solutions, and we have no any reasons (bases) to assume from the very beginning 
     that the answer is in integer numbers.


     Therefore, after you obtained this basic polynomial equation of the third degree, 
     you have no a reason to apply the Rational root theorem to seek the integer roots.


     In such cases, it is much more productive to make a plot of the polynomial and to get an information
     about the roots from the plot.


     If from the plot you see that one (or several) roots are (or are expected to be) integer numbers,
     then you can simply CHECK if these candidates / (these integer numbers) are really the roots.


     If at least one root is integer and you just found it, then you can move further by dividing the polynomial to
     an appropriate linear binomial and reduce the degree.


     Good tool to make plots quickly and easily in seconds is this free of charge Internet site
     www.desmos.com.


     And THEN, when the roots (the integer roots, in this case) are just found, you may apply the Rational root theorem
     to demonstrate to your teacher, how smart you are.


     Do not think, PLEASE, that I discreditate the Rational root theorem.
     It is a nice tool in Algebra.
     But, as I joke from time to time, in complicated cases it works especially good, when the answer / (the solution) is known in advance.



(2)  A person experienced in Algebra may drive his (or her) thoughts by different way.

     
     He (or she) notices that the polynimial  p(x) = {{{x^3 + 8x^2 - 288}}}  was obtained as a product of the three linear binomials
     (x+6)*(x+12)*(x-4)

     Then he needs to solve a modified equation  {{{x^3 - 8x^2 + 288}}} = 0.


     He (or she) notices that the modified polinomial  q(x) = {{{x^3 - 8x^2 + 288}}}  has the coefficients that are opposed 
     to the coefficients  of the polynomial p(x).


     More precisely, he notices that the modified polynomial has opposite coefficients at the term with x^2 and the constant term,
     while the coefficient at x is zero in both polynomials.


     Then the person recalls the Vieta's theorem, which tells him (or her), that IT MEANS THAT the roots of the polynomial q(x)
     are opposed numbers to the roots of the polynomial q(x).


     It means that the roots of the equation  {{{x^3 - 8x^2 + 288}}} = 0  are 6, 12 and -4.


     Probably, this explanation is slightly over than the standard/regular school level; but for an advanced student it may work.
</pre>

------------


Happy learning (!)