We have as on RHS (a+b) we can add 4abc to the 3rd term to get (a+b) as a factor and add 2abc to 1st and 2nd term that is distributing 8abc to get
$a(b-c)^2 +b(c-a)^2+c(a-b)^2+8abc$
$=a((b-c)^2 +2bc)+b((c-a)^2+2ac)+c((a-b)^2+4ab)$
$=a((b^2+c^2)+b((c^2+a^2))+c(a+b)^2$
$=ab^2+ac^2+bc^2+ba^2+c(a+b)^2$
$=ab^2+ba^2+ac^2+bc^2+c(a+b)^2$
$=ab(a+b) + c^2(a+b) + c(a+b)^2$
$=(a+b)(ab+c^2 + c(a+b)$
$=(a+b) (c^2 + ca + bc + ab)$
$= (a+b)(b+c)(c+a)$
First let us find the number such that $\frac{n}{2}$ , $\frac{n}{3}$ ,$\frac{2n+1}{5}$ are integers
as $\frac{n}{2}$ , $\frac{n}{3}$ are integers so $\frac{n}{6}$ is integer say k
so n= 6k
As in denominator we have 2 3 and 5 so we should have mod 30
take k from 0 to 5 we get n = 12 satisfies $\frac{2n+1}{5}$ integer
so we get values n =12 , 42, 72, 102,132,162,192 .
as n is multiple of 6 $\frac{n}{2}$ , $\frac{n}{3}$ are composite we need to check $\frac{2n+1}{5}$ composite . let us compute $\frac{2n+1}{5}$
n = 12 gives 5 so no
n = 42 gives 17 so no
n = 72 gives 29 no
n = 102 gives 41 no
n = 132 gives 53 no
n = 162 gives 65 yes
n = 192 gives 77 yes
so there are 2 values
we have
$3^{(2n + 1)}+ 2^{(n + 2)}$
$=3 *3^{2n}+ 4 *2^{n}$
$=3 *3^{2n}+ 4 *2^{n}$
$=3 *9^{n}+ 4 *2^{n}$
$=3 *2^{n}+ 4 *2^{n}$ as $9 \equiv 2 \pmod 7$
$=(3 + 4) *2^{n}$
$= 7 *2^{n}$ divisible by 7
It is risky to square both sides as it shall give erroneous root.
Let us first find the range of x
as we can take the square root of a non -ve number only so we
$x \ge -2$
for $x \in [-2,0] LHS is positve and RHS is -ve or zero. so this is range in -ve
To find the range is positive we square both sides to get
$(x+2) > x^2$
or $x^2-x-2 <0$
or $(x-2)(x+1) <0$ or $x \in [-1,2)$
as x is positive so $x \in [0,2)$
so combining we get $x \in [-2,2)$
Both a and $a^5$ are even or odd so $a^5-a$
Now if a is multiple of 5 $a^5$ is multiple of 5. so $a^5-a$ is divisible by 5
If a is not multiple of 5 then as per FLT $a^5 \equiv a \pmod 5$ so $a^5-a$ is divisible by 5
In both cases $a^5−a$ is divisible by 10
we can solve by fining GCD of 2 and 3 but here I shall solve it by a different approach
We can rewrite this as
$3y = 2x -8$
RHS is even so LHS should be even or y should be even
So let $y =2k$
We get $6k = 2x -8$
Or x = $3k + 4$
So $x = 3k + 4$ and $y = 2k$ are parametric form of solution
by choosing any integer for k we can get particular solution
k = 1 gives (7,2)
k =2 gives (10,4)
We can solve the 2 equations and get $a=5$ and $b=2$ and hence $a^3-b^3=5^3-2^3=117$
but the above approach is longer as compared to the approach below
We have
$(a-b)^3 = a^3-3a^2b + 3ab^3 - b^3 = a^3-b^3-3ab(a-b)$
or $a^3-b^3= (a-b)^3 + 3ab(a-b)$
Putting the values we get $a^3-b^3=3^3 + 3 * 10 * 3 = 117$
In this process we have avoided solving of equations
