algebra 2 quiz review name:
1 simplify the expression
$\sqrt6{q^{12}z^4}$
2 find the reduced radical form of
$\sqrt3{250y^3z^4}$
3 find the reduced radical form of
$\frac{7}{1 - \sqrt{6}}$
4 find the reduced radical form of
$\frac{3}{1 - \sqrt{5}}$
5 $f(x) = \sqrt{x - 2} - 3$
8 $f(x) = \sqrt{x + 3} - 1$

Question

Accepted Answer

### Problem 1: Simplify $\boldsymbol{\sqrt[4]{q^{12}z^4}}$ # Explanation: ## Step 1: Apply the nth root property For a radical $\sqrt[n]{a^m}$, we can simplify it as $a^{\frac{m}{n}}$ (when $a\geq0$ for even roots). So we apply this to $q^{12}$ and $z^4$ separately. For $q^{12}$: $\sqrt[4]{q^{12}} = q^{\frac{12}{4}} = q^3$ For $z^4$: $\sqrt[4]{z^4} = z^{\frac{4}{4}} = z$ (assuming $z\geq0$ to take the real root) ## Step 2: Combine the results Multiply the simplified parts together: $q^3 \cdot z = q^3z$ # Answer: $q^3z$ ### Problem 2: Simplify $\boldsymbol{\sqrt[3]{250y^3z^4}}$ # Explanation: ## Step 1: Factor the radicand Factor 250: $250 = 125 imes 2 = 5^3 imes 2$ Factor $y^3$: $y^3 = y^3$ Factor $z^4$: $z^4 = z^3 imes z$ So the radicand becomes $5^3 imes 2 imes y^3 imes z^3 imes z$ ## Step 2: Apply the cube root property $\sqrt[3]{a^3b} = a\sqrt[3]{b}$. So we take the cube root of the perfect cube factors: $\sqrt[3]{5^3y^3z^3} = 5yz$ The remaining factor is $2z$, so we have: $\sqrt[3]{250y^3z^4} = 5yz\sqrt[3]{2z}$ # Answer: $5yz\sqrt[3]{2z}$ ### Problem 3: Simplify $\boldsymbol{\frac{7}{1 - \sqrt{6}}}$ # Explanation: ## Step 1: Rationalize the denominator Multiply the numerator and denominator by the conjugate of the denominator, which is $1 + \sqrt{6}$. $\frac{7(1 + \sqrt{6})}{(1 - \sqrt{6})(1 + \sqrt{6})}$ ## Step 2: Simplify the denominator The denominator is a difference of squares: $(a - b)(a + b) = a^2 - b^2$. So: $(1)^2 - (\sqrt{6})^2 = 1 - 6 = -5$ ## Step 3: Simplify the numerator Multiply out the numerator: $7(1 + \sqrt{6}) = 7 + 7\sqrt{6}$ ## Step 4: Combine and simplify Now we have $\frac{7 + 7\sqrt{6}}{-5} = -\frac{7 + 7\sqrt{6}}{5}$ or we can factor out 7: $-\frac{7(1 + \sqrt{6})}{5}$ # Answer: $-\frac{7(1 + \sqrt{6})}{5}$ (or $-\frac{7 + 7\sqrt{6}}{5}$) ### Problem 4: Simplify $\boldsymbol{\frac{3}{1 - \sqrt{5}}}$ # Explanation: ## Step 1: Rationalize the denominator Multiply the numerator and denominator by the conjugate of the denominator, which is $1 + \sqrt{5}$. $\frac{3(1 + \sqrt{5})}{(1 - \sqrt{5})(1 + \sqrt{5})}$ ## Step 2: Simplify the denominator Using the difference of squares: $(1)^2 - (\sqrt{5})^2 = 1 - 5 = -4$ ## Step 3: Simplify the numerator Multiply out the numerator: $3(1 + \sqrt{5}) = 3 + 3\sqrt{5}$ ## Step 4: Combine and simplify Now we have $\frac{3 + 3\sqrt{5}}{-4} = -\frac{3 + 3\sqrt{5}}{4}$ or factor out 3: $-\frac{3(1 + \sqrt{5})}{4}$ # Answer: $-\frac{3(1 + \sqrt{5})}{4}$ (or $-\frac{3 + 3\sqrt{5}}{4}$) ### Problem 5: Graph $\boldsymbol{f(x) = \sqrt{x - 2} - 3}$ (Note: Since graphing is visual, we'll describe the transformations from the parent function $y = \sqrt{x}$) # Explanation: ## Step 1: Identify the parent function and transformations The parent function is $y = \sqrt{x}$, which has a domain $x\geq0$ and starts at $(0, 0)$, increasing. - The $x - 2$ inside the square root shifts the graph **2 units to the right** (horizontal shift: $y = \sqrt{x - h}$ shifts $h$ units right when $h>0$). - The $- 3$ outside the square root shifts the graph **3 units down** (vertical shift: $y = \sqrt{x} + k$ shifts $k$ units down when $k<0$). ## Step 2: Find the vertex (starting point) For $y = \sqrt{x - 2} - 3$, the starting point (where the square root is zero) is when $x - 2 = 0 \implies x = 2$, and $y = 0 - 3 = -3$. So the vertex is at $(2, -3)$. ## Step 3: Plot points and draw the graph - When $x = 3$: $f(3) = \sqrt{3 - 2} - 3 = 1 - 3 = -2$ (point: $(3, -2)$) - When $x = 6$: $f(6) = \sqrt{6 - 2} - 3 = 2 - 3 = -1$ (point: $(6, -1)$) - When $x = 11$: $f(11) = \sqrt{11 - 2} - 3 = 3 - 3 = 0$ (point: $(11, 0)$) Draw a smooth curve starting at $(2, -3)$ and passing through these points, increasing as $x$ increases. # Answer: The graph is a square root curve shifted 2 units right and 3 units down, with vertex at $(2, -3)$ and passing through points like $(3, -2)$, $(6, -1)$, $(11, 0)$ (graph description). ### Problem 8: Graph $\boldsymbol{f(x) = \sqrt{x + 3} - 1}$ (Note: Similar to problem 5, we describe the transformations from $y = \sqrt{x}$) # Explanation: ## Step 1: Identify transformations Parent function: $y = \sqrt{x}$ (domain $x\geq0$, starts at $(0, 0)$). - The $x + 3$ inside the square root shifts the graph **3 units to the left** (horizontal shift: $y = \sqrt{x + h}$ shifts $h$ units left when $h>0$). - The $- 1$ outside the square root shifts the graph **1 unit down** (vertical shift: $y = \sqrt{x} + k$ shifts $k$ units down when $k<0$). ## Step 2: Find the vertex (starting point) Set $x + 3 = 0 \implies x = -3$, then $y = 0 - 1 = -1$. So the vertex is at $(-3, -1)$. ## Step 3: Plot points and draw the graph - When $x = -2$: $f(-2) = \sqrt{-2 + 3} - 1 = 1 - 1 = 0$ (point: $(-2, 0)$) - When $x = 1$: $f(1) = \sqrt{1 + 3} - 1 = 2 - 1 = 1$ (point: $(1, 1)$) - When $x = 6$: $f(6) = \sqrt{6 + 3} - 1 = 3 - 1 = 2$ (point: $(6, 2)$) Draw a smooth curve starting at $(-3, -1)$ and passing through these points, increasing as $x$ increases. # Answer: The graph is a square root curve shifted 3 units left and 1 unit down, with vertex at $(-3, -1)$ and passing through points like $(-2, 0)$, $(1, 1)$, $(6, 2)$ (graph description).

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QUESTION IMAGE

Question

Explanation:

Problem 1: Simplify $\boldsymbol{\sqrt[4]{q^{12}z^4}}$

Step 1: Apply the nth root property

Step 2: Combine the results

Step 1: Factor the radicand

Step 2: Apply the cube root property

Step 1: Rationalize the denominator

Step 2: Simplify the denominator

Step 3: Simplify the numerator

Step 4: Combine and simplify

Answer:

Problem 2: Simplify $\boldsymbol{\sqrt[3]{250y^3z^4}}$