The Rational Zero Theorem tells us that if [latex]\frac{p}{q}[/latex] is a zero of [latex]f\left(x\right)[/latex], then [latex]p[/latex] is a factor of [latex]3[/latex] and [latex]q[/latex] is a factor of [latex]3[/latex].

[latex]\begin{array}{l}\frac{p}{q}=\frac{\text{Factors of the constant term}}{\text{Factor of the leading coefficient}}\hfill \\ \text{}\frac{p}{q}=\frac{\text{Factors of 3}}{\text{Factors of 3}}\hfill \end{array}[/latex]

The factors of [latex]3[/latex] are [latex]\pm 1[/latex] and [latex]\pm 3[/latex]. The possible values for [latex]\frac{p}{q}[/latex], and therefore the possible rational zeros for the function, are [latex]\pm 3, \pm 1, \text{and} \pm \frac{1}{3}[/latex]. We will use synthetic division to evaluate each possible zero until we find one that gives a remainder of [latex]0[/latex]. Let’s begin with [latex]–3[/latex].

Dividing by [latex]\left(x+3\right)[/latex] gives a remainder of [latex]0[/latex], so [latex]–3[/latex] is a zero of the function. The polynomial can be written as [latex]\left(x+3\right)\left(3{x}^{2}+1\right)[/latex].

We can then set the quadratic equal to [latex]0[/latex] and solve to find the other zeros of the function.

[latex]\begin{array}{l}3{x}^{2}+1=0\hfill \\ \text{ }{x}^{2}=-\frac{1}{3}\hfill \\ \text{ }x=\pm \sqrt{-\frac{1}{3}}=\pm \frac{i\sqrt{3}}{3}\hfill \end{array}[/latex]

The zeros of [latex]f\left(x\right)[/latex] are [latex]–3[/latex] and [latex]\pm \frac{i\sqrt{3}}{3}[/latex].

Thus, we can write our function in factored form:

[latex]f(x) = 3(x+3)(x-\frac{i\sqrt{3}}{3})(x+\frac{i\sqrt{3}}{3})[/latex]

Analysis of the Solution

Look at the graph of the function [latex]f[/latex]. Notice that, at [latex]x=-3[/latex], the graph crosses the x-axis, indicating an odd multiplicity ([latex]1[/latex]) for the zero [latex]x=-3[/latex]. Also note the presence of the two turning points. This means that, since there is a 3^rd degree polynomial, we are looking at the maximum number of turning points. So, the end behavior of increasing without bound to the right and decreasing without bound to the left will continue. Thus, all the [latex]x[/latex]-intercepts for the function are shown. So either the multiplicity of [latex]x=-3[/latex] is [latex]1[/latex] and there are two complex solutions, which is what we found, or the multiplicity at [latex]x=-3[/latex] is three. Either way, our result is correct.

The Rational Zero Theorem states that any rational zero, [latex]\frac{p}{q}[/latex], must have [latex]p[/latex] as a factor of the constant term [latex]4[/latex] and [latex]q[/latex] as a factor of the leading coefficient [latex]2[/latex].

• Factors of [latex]4[/latex]: [latex]\pm 1, \pm 2, \pm 4[/latex]
• Factors of [latex]2[/latex]: [latex]\pm 1, \pm 2[/latex]
• All possible rational root: [latex]\pm 1, \pm 2, \pm 4, \pm \frac{1}{2}[/latex]

Test the possible zeros! Let’s start with [latex]x = 1[/latex]:

The reminder is [latex]0[/latex], so [latex]x=1[/latex] is a zero.

Let’s rewrite [latex]f(x)[/latex] and factor it completely:

[latex]\begin{align*} f(x) &= 2x^3 + 5x^2 - 11x + 4 \\ &= (x - 1)(2x^2 + 7x - 4) \\ &= (x - 1)(2x^2 + 8x - x - 4) \\ &= (x - 1)\left[ (2x^2 + 8x) + (-x - 4) \right] \\ &= (x - 1)\left[ 2x(x + 4) - 1(x + 4) \right] \\ &= (x - 1)(2x - 1)(x + 4) \end{align*}[/latex]

Thus, the zeros are [latex]\text{-4, }\frac{1}{2},\text{ and 1}\text{.}[/latex]