How to solve this? #sqrt(x-2)+root(3)(4-x)=2#

1 Answer
May 28, 2017

#x = 3" "# or #" "x = 14+-6sqrt(3)#

Explanation:

Transform from a radical equation to a polynomial in several steps, find the solutions, then check they are not extraneous...

Given:

#sqrt(x-2)+root(3)(4-x) = 2#

Subtract #sqrt(x-2)# from boh sides to get:

#root(3)(4-x) = 2-sqrt(x-2)#

Cube both sides to get:

#4-x = (2-sqrt(x-2))^3#

#color(white)(4-x) = 8-12sqrt(x-2)+6(x-2)-(x-2)sqrt(x-2)#

#color(white)(4-x) = 6x-4-(x+10)sqrt(x-2)#

Add #(x+10)sqrt(x-2)+x-4# to both sides to get:

#(x+10)sqrt(x-2)=7x-8#

square both sides to get:

#(x^2+20x+100)(x-2) = 49x^2-112x+64#

Multiplying out, this becomes:

#x^3+18x^2+60x-200 = 49x^2-112x+64#

Subtract the right hand side from the left to get:

#0 = x^3-31x^2+172x-264#

#color(white)(0) = (x-3)(x^2-28x+88)#

#color(white)(0) = (x-3)(x^2-28x+196-108)#

#color(white)(0) = (x-3)((x-14)^2-(6sqrt(3))^2)#

#color(white)(0) = (x-3)((x-14)-6sqrt(3))((x-14)+6sqrt(3))#

#color(white)(0) = (x-3)(x-14-6sqrt(3))(x-14+6sqrt(3))#

So:

#x = 3#

or:

#x = 14+-6sqrt(3)#

Trying these values in the original equation, we find that #x=3# is a valid solution.

How about the other two?

Note that cubing the equation would introduce no extraneous solutions since #f(x) = x^3# is one to one. Squaring the equation introduces extraneous solutions if and only if #(7x-8)/(x+10) < 0#

We find:

#7(color(blue)(14+6sqrt(3)))-8 = 90+42sqrt(3) > 0#

#color(blue)(14+6sqrt(3))+10 = 24+6sqrt(3) > 0#

So #14+6sqrt(3)# is a valid solution.

#7(color(blue)(14-6sqrt(3)))-8 = 90-42sqrt(3) > 0#

#color(blue)(14-6sqrt(3))+10 = 24-6sqrt(3) > 0#

So #14-6sqrt(3)# is a valid solution too.

graph{(y-sqrt(x-2)-root(3)(4-x))(y-2) = 0 [-1, 33.74, -1, 2.5]}