Question

in exercises 35-42, simplify the expression. (see example 5.)35. $sqrt4{81y^8}$36. $sqrt3{8w^9}$37. $sqrt3{64r^3t^6}$38. $sqrt4{16a^8b^{12}}$39. $\frac{sqrt5{m^{10}}}{m^3}$40. $sqrt6{\frac{k^{18}}{16z^4}}$▶41. $sqrt{\frac{g^6h}{h^7}}$42. $sqrt8{\frac{n^2p^{-1}}{n^{18}p^7}}$in exercises 43-48, perform the indicated operation and write the answer in simplest form. assume all variables are positive. (see example 6.)▶43. $12sqrt3{y}+9sqrt3{y}$44. $11sqrt{2z}-5sqrt{2z}$45. $3x^{7/2}-5x^{7/2}$46. $7m^{7/3}+3m^{7/3}$47. $(16w^{10})^{1/4}+2w(w^6)^{1/4}$48. $sqrt3{32p^{10}}-9p^2sqrt3{4p^4}$4 error analysis in exercises 49 and 50, describe and correct the error in simplifying the expression.49.$sqrt6{\frac{64}{w^6}}=\frac{sqrt6{64}}{sqrt6{w^6}}LXB0=\frac{2}{w}$50.$3sqrt3{12y}+5sqrt3{12y}=(3+5)sqrt3{24y}LXB1=8sqrt3{8cdot3y}LXB2=16sqrt3{3y}$51. open-ended write two variable expressions involving radicals, one that needs absolute value when simplifying and one that does not need absolute value. justify your answers.52. college prep when each expression is simplified, which expressions are like radicals? select all that apply.a $sqrt3{125x}$b $sqrt4{80x}$c $sqrt3{625x}$d $sqrt3{40x}$e $sqrt4{16x}$f $sqrt3{135x}$

Explanation:

First, solving Exercises 35-42 (simplify radicals):

Step1: Rewrite radicand as perfect 4th power

$\sqrt[4]{81y^8} = \sqrt[4]{3^4 \cdot (y^2)^4}$

Step2: Extract perfect 4th power terms

$\sqrt[4]{3^4 \cdot (y^2)^4} = 3y^2$

---

Step1: Rewrite radicand as perfect 3rd power

$\sqrt[3]{8w^9} = \sqrt[3]{2^3 \cdot (w^3)^3}$

Step2: Extract perfect 3rd power terms

$\sqrt[3]{2^3 \cdot (w^3)^3} = 2w^3$

---

Step1: Rewrite radicand as perfect 3rd power

$\sqrt[3]{64r^9t^6} = \sqrt[3]{4^3 \cdot (r^3)^3 \cdot (t^2)^3}$

Step2: Extract perfect 3rd power terms

$\sqrt[3]{4^3 \cdot (r^3)^3 \cdot (t^2)^3} = 4r^3t^2$

---

Step1: Rewrite radicand as perfect 4th power

$\sqrt[4]{16a^8b^{12}} = \sqrt[4]{2^4 \cdot (a^2)^4 \cdot (b^3)^4}$

Step2: Extract perfect 4th power terms

$\sqrt[4]{2^4 \cdot (a^2)^4 \cdot (b^3)^4} = 2a^2b^3$

---

Step1: Combine radicals into single fraction

$\frac{\sqrt[5]{m^{10}}}{\sqrt[5]{m^5}} = \sqrt[5]{\frac{m^{10}}{m^5}}$

Step2: Simplify exponent inside radical

$\sqrt[5]{m^{10-5}} = \sqrt[5]{m^5}$

Step3: Extract perfect 5th power term

$\sqrt[5]{m^5} = m$

---

Step1: Split radical into fraction of radicals

$\sqrt[6]{\frac{k^{18}}{16z^4}} = \frac{\sqrt[6]{k^{18}}}{\sqrt[6]{16z^4}}$

Step2: Simplify numerator and rewrite denominator

$\frac{k^{3}}{(2^4z^4)^{1/6}} = \frac{k^3}{2^{2/3}z^{2/3}} = \frac{k^3}{\sqrt[3]{4z^2}}$

Step3: Rationalize the denominator

$\frac{k^3\sqrt[3]{2z}}{\sqrt[3]{4z^2} \cdot \sqrt[3]{2z}} = \frac{k^3\sqrt[3]{2z}}{2z}$

---

Step1: Split radical into fraction of radicals

$\sqrt{\frac{g^6h}{h^7}} = \frac{\sqrt{g^6h}}{\sqrt{h^7}}$

Step2: Simplify exponents of radicals

$\frac{g^3\sqrt{h}}{h^{3}\sqrt{h}}$

Step3: Cancel common radical terms

$\frac{g^3}{h^3}$

---

Step1: Split radical into fraction of radicals

$\sqrt[8]{\frac{n^2p^{-1}}{n^{18}p^7}} = \sqrt[8]{n^{2-18}p^{-1-7}}$

Step2: Simplify exponents inside radical

$\sqrt[8]{n^{-16}p^{-8}}$

Step3: Rewrite with positive exponents

$\sqrt[8]{\frac{1}{n^{16}p^8}} = \frac{1}{n^2p}$

Step1: Combine like radical terms

$12\sqrt[3]{y} + 9\sqrt[3]{y} = (12+9)\sqrt[3]{y}$

Step2: Simplify the coefficient

$21\sqrt[3]{y}$

---

Step1: Combine like radical terms

$11\sqrt{2z} - 5\sqrt{2z} = (11-5)\sqrt{2z}$

Step2: Simplify the coefficient

$6\sqrt{2z}$

---

Step1: Combine like exponential terms

$3x^{7/2} - 5x^{7/2} = (3-5)x^{7/2}$

Step2: Simplify the coefficient

$-2x^{7/2}$

---

Step1: Combine like exponential terms

$7m^{7/3} + 3m^{7/3} = (7+3)m^{7/3}$

Step2: Simplify the coefficient

$10m^{7/3}$

---

Step1: Simplify each exponential term

$(16w^{10})^{1/4} = 16^{1/4}w^{10/4} = 2w^{5/2}$; $2w(w^6)^{1/4} = 2w \cdot w^{6/4} = 2w^{5/2}$

Step2: Combine like terms

$2w^{5/2} + 2w^{5/2} = 4w^{5/2}$

---

Step1: Simplify each radical term

$\sqrt[3]{32p^{10}} = \sqrt[3]{16 \cdot 2 \cdot p^9 \cdot p} = 2p^3\sqrt[3]{4p}$; $9p^2\sqrt[3]{4p^4} = 9p^2 \cdot p\sqrt[3]{4p} = 9p^3\sqrt[3]{4p}$

Step2: Combine like radical terms

$2p^3\sqrt[3]{4p} - 9p^3\sqrt[3]{4p} = (2-9)p^3\sqrt[3]{4p}$

Step3: Simplify the coefficient

$-7p^3\sqrt[3]{4p}$

Exercise 49:

The error is that $\sqrt[6]{64} = 2$, but since the root index (6) is even, the result of $\sqrt[6]{w^6}$ must include an absolute value to ensure non-negativity (even roots yield non-negative results, and $w$ could be negative).

Exercise 50:

The error is incorrectly combining the radicands when adding like radicals. Like radicals have identical radicands and root indices, so we only add the coefficients, not combine the radicands.

Answer:

1. $3y^2$
2. $2w^3$
3. $4r^3t^2$
4. $2a^2b^3$
5. $m$
6. $\frac{k^3\sqrt[3]{2z}}{2z}$
7. $\frac{g^3}{h^3}$
8. $\frac{1}{n^2p}$

---

Next, solving Exercises 43-48 (combine like radicals/terms):