a+b=2 ab=3\left(-21\right)=-63

To solve the equation, factor the left hand side by grouping. First, left hand side needs to be rewritten as 3n^{2}+an+bn-21. To find a and b, set up a system to be solved.

-1,63 -3,21 -7,9

Since ab is negative, a and b have the opposite signs. Since a+b is positive, the positive number has greater absolute value than the negative. List all such integer pairs that give product -63.

-1+63=62 -3+21=18 -7+9=2

Calculate the sum for each pair.

a=-7 b=9

The solution is the pair that gives sum 2.

\left(3n^{2}-7n\right)+\left(9n-21\right)

Rewrite 3n^{2}+2n-21 as \left(3n^{2}-7n\right)+\left(9n-21\right).

n\left(3n-7\right)+3\left(3n-7\right)

Factor out n in the first and 3 in the second group.

\left(3n-7\right)\left(n+3\right)

Factor out common term 3n-7 by using distributive property.

n=\frac{7}{3} n=-3

To find equation solutions, solve 3n-7=0 and n+3=0.

3n^{2}+2n-21=0

All equations of the form ax^{2}+bx+c=0 can be solved using the quadratic formula: \frac{-b±\sqrt{b^{2}-4ac}}{2a}. The quadratic formula gives two solutions, one when ± is addition and one when it is subtraction.

n=\frac{-2±\sqrt{2^{2}-4\times 3\left(-21\right)}}{2\times 3}

This equation is in standard form: ax^{2}+bx+c=0. Substitute 3 for a, 2 for b, and -21 for c in the quadratic formula, \frac{-b±\sqrt{b^{2}-4ac}}{2a}.

n=\frac{-2±\sqrt{4-4\times 3\left(-21\right)}}{2\times 3}

Square 2.

n=\frac{-2±\sqrt{4-12\left(-21\right)}}{2\times 3}

Multiply -4 times 3.

n=\frac{-2±\sqrt{4+252}}{2\times 3}

Multiply -12 times -21.

n=\frac{-2±\sqrt{256}}{2\times 3}

Add 4 to 252.

n=\frac{-2±16}{2\times 3}

Take the square root of 256.

n=\frac{-2±16}{6}

Multiply 2 times 3.

n=\frac{14}{6}

Now solve the equation n=\frac{-2±16}{6} when ± is plus. Add -2 to 16.

n=\frac{7}{3}

Reduce the fraction \frac{14}{6} to lowest terms by extracting and canceling out 2.

n=-\frac{18}{6}

Now solve the equation n=\frac{-2±16}{6} when ± is minus. Subtract 16 from -2.

n=-3

Divide -18 by 6.

n=\frac{7}{3} n=-3

The equation is now solved.

3n^{2}+2n-21=0

Quadratic equations such as this one can be solved by completing the square. In order to complete the square, the equation must first be in the form x^{2}+bx=c.

3n^{2}+2n-21-\left(-21\right)=-\left(-21\right)

Add 21 to both sides of the equation.

3n^{2}+2n=-\left(-21\right)

Subtracting -21 from itself leaves 0.

3n^{2}+2n=21

Subtract -21 from 0.

\frac{3n^{2}+2n}{3}=\frac{21}{3}

Divide both sides by 3.

n^{2}+\frac{2}{3}n=\frac{21}{3}

Dividing by 3 undoes the multiplication by 3.

n^{2}+\frac{2}{3}n=7

Divide 21 by 3.

n^{2}+\frac{2}{3}n+\left(\frac{1}{3}\right)^{2}=7+\left(\frac{1}{3}\right)^{2}

Divide \frac{2}{3}, the coefficient of the x term, by 2 to get \frac{1}{3}. Then add the square of \frac{1}{3} to both sides of the equation. This step makes the left hand side of the equation a perfect square.

n^{2}+\frac{2}{3}n+\frac{1}{9}=7+\frac{1}{9}

Square \frac{1}{3} by squaring both the numerator and the denominator of the fraction.

n^{2}+\frac{2}{3}n+\frac{1}{9}=\frac{64}{9}

Add 7 to \frac{1}{9}.

\left(n+\frac{1}{3}\right)^{2}=\frac{64}{9}

Factor n^{2}+\frac{2}{3}n+\frac{1}{9}. In general, when x^{2}+bx+c is a perfect square, it can always be factored as \left(x+\frac{b}{2}\right)^{2}.

\sqrt{\left(n+\frac{1}{3}\right)^{2}}=\sqrt{\frac{64}{9}}

Take the square root of both sides of the equation.

n+\frac{1}{3}=\frac{8}{3} n+\frac{1}{3}=-\frac{8}{3}

Simplify.

n=\frac{7}{3} n=-3

Subtract \frac{1}{3} from both sides of the equation.

x ^ 2 +\frac{2}{3}x -7 = 0

Quadratic equations such as this one can be solved by a new direct factoring method that does not require guess work. To use the direct factoring method, the equation must be in the form x^2+Bx+C=0.This is achieved by dividing both sides of the equation by 3

r + s = -\frac{2}{3} rs = -7

Let r and s be the factors for the quadratic equation such that x^2+Bx+C=(x−r)(x−s) where sum of factors (r+s)=−B and the product of factors rs = C

r = -\frac{1}{3} - u s = -\frac{1}{3} + u

Two numbers r and s sum up to -\frac{2}{3} exactly when the average of the two numbers is \frac{1}{2}*-\frac{2}{3} = -\frac{1}{3}. You can also see that the midpoint of r and s corresponds to the axis of symmetry of the parabola represented by the quadratic equation y=x^2+Bx+C. The values of r and s are equidistant from the center by an unknown quantity u. Express r and s with respect to variable u. <div style='padding: 8px'><img src='https://opalmath.azureedge.net/customsolver/quadraticgraph.png' style='width: 100%;max-width: 700px' /></div>

(-\frac{1}{3} - u) (-\frac{1}{3} + u) = -7

To solve for unknown quantity u, substitute these in the product equation rs = -7

\frac{1}{9} - u^2 = -7

Simplify by expanding (a -b) (a + b) = a^2 – b^2

-u^2 = -7-\frac{1}{9} = -\frac{64}{9}

Simplify the expression by subtracting \frac{1}{9} on both sides

u^2 = \frac{64}{9} u = \pm\sqrt{\frac{64}{9}} = \pm \frac{8}{3}

Simplify the expression by multiplying -1 on both sides and take the square root to obtain the value of unknown variable u

r =-\frac{1}{3} - \frac{8}{3} = -3 s = -\frac{1}{3} + \frac{8}{3} = 2.333

The factors r and s are the solutions to the quadratic equation. Substitute the value of u to compute the r and s.