Eureka Math Grade 8 Module 1 Lesson 3 Answer Key

Engage NY Eureka Math 8th Grade Module 1 Lesson 3 Answer Key

Eureka Math Grade 8 Module 1 Lesson 3 Example Answer Key

Examples 1–2
Work through Examples 1 and 2 in the same manner. (Supplement with additional examples if needed.) Have students calculate the resulting exponent; however, emphasis should be placed on the step leading to the resulting exponent, which is the product of the exponents.
Example 1.
(72 )6=
Answer:
Eureka Math Grade 8 Module 1 Lesson 3 Example Answer Key 1

Example 2.
(1.3)3 )10=
Answer:
(1.3×1.3×1.3)10
Eureka Math Grade 8 Module 1 Lesson 3 Example Answer Key 2

Eureka Math Grade 8 Module 1 Lesson 3 Exercise Answer Key

Exercise 1.
(153)9=
Answer:
(15)9×3

Exercise 2.
((-2)5 )8=
Answer:
(-2)8×5

Exercise 3.
(3.417)4=
Answer:
3.44×17

Exercise 4.
Let s be a number.
Answer:
(s17 )4=
Answer:
s4×17

Exercise 5.
Sarah wrote (35 )7=312. Correct her mistake. Write an exponential expression using a base of 3 and exponents of 5, 7, and 12 that would make her answer correct.
Answer:
Correct way: (35 )7=335; Rewritten Problem: 35×37=35+7=312.

Exercise 6.
A number y satisfies y24-256=0. What equation does the number x=y4 satisfy?
Answer:
Since x=y4, then (x)6=(y4 )6. Therefore, x=y4 would satisfy the equation x6-256=0.

Exercises 7–13 (10 minutes)
Have students complete Exercises 17–12 independently and then check their answers.

Exercise 7.
(11×4)9=
Answer:
119×1×49×1

Exercise 8.
(32×74 )5=
Ans:
35×2×75×4

Exercise 9.
Let a, b, and c be numbers.
(32 a4 )5=
Answer:
35×2 a5×4

Exercise 10.
Let x be a number.
(5x)7=
Ans:
57×1 ∙x7×1

Exercise 11.
Let x and y be numbers.
(5xy2 )7=
Ans:
57×1 ∙x7×1∙y7×2

Exercise 12.
Let a, b, and c be numbers.
(a2 bc3 )4=
Ans:
a4×2 ∙b4×1∙c4×3

Exercise 13.
Let x and y be numbers, y≠0, and let n be a positive integer. How is (\(\frac{x}{y}\))n related to xn and yn?
Answer:
(\(\frac{x}{y}\))n=\(\frac{x^{n}}{y^{n}}\)
Because
Eureka Math Grade 8 Module 1 Lesson3 Exercise Answer Key 20

Eureka Math Grade 8 Module 1 Lesson 3 Problem Set Answer Key

Question 1.
Show (prove) in detail why (2∙3∙7)4=24 34 74.
Answer:
(2∙3∙7)4=(2∙3∙7)(2∙3∙7)(2∙3∙7)(2∙3∙7)
=(2∙2∙2∙2)(3∙3∙3∙3)(7∙7∙7∙7)
By repeated use of the commutative and associative properties
=24 34 74 By definition

Question 2.
Show (prove) in detail why (xyz)4=x4 y4 z4 for any numbers x,y,z.
Answer:
The left side of the equation (xyz)4 means (xyz) (xyz) (xyz) (xyz). Using the commutative and associative properties of multiplication, we can write (xyz) (xyz) (xyz) (xyz) as (xxxx)(yyyy) (zzzz), which in turn can be written as x4 y4 z4, which is what the right side of the equation states.

Question 3.
Show (prove) in detail why (xyz)n=xn yn zn for any numbers x, y, and z and for any positive integer n.
Ans:
Beginning with the left side of the equation, (xyz)n means Eureka Math Grade 8 Module 1 Lesson 3 Problem Set Answer Key 15. Using the commutative and associative properties of multiplication, Eureka Math Grade 8 Module 1 Lesson 3 Problem Set Answer Key 16 can be rewritten as Eureka Math Grade 8 Module 1 Lesson 3 Problem Set Answer Key 17 and, finally, xn yn zn, which is what the right side of the equation states. We can also prove this equality by a different method, as follows. Beginning with the right side xn yn zn means Eureka Math Grade 8 Module 1 Lesson 3 Problem Set Answer Key 19 which by the commutative property of multiplication can be rewritten as Eureka Math Grade 8 Module 1 Lesson 3 Problem Set Answer Key 21. Using exponential notation, Eureka Math Grade 8 Module 1 Lesson 3 Problem Set Answer Key 22 can be rewritten as (xyz)n, which is what the left side of the equation states.

Eureka Math Grade 8 Module 1 Lesson 3 Exit Ticket Answer Key

Write each expression as a base raised to a power or as the product of bases raised to powers that is equivalent to the given expression.

Question 1.
(93 )6=
Ans:
(93 )6=96×3=918

Question 2.
(1132×37×514 )3=
Ans:
(1132×37×514 )3=((1132×37)×514 )3 By associative law
= (1132×37)3×(514 )3 Because (xy)n=xn yn for all numbers x, y
= (1132)3×373×(514)3 Because (xy)n=xn yn for all numbers x, y
= 1136×373×5112 Because (xm)n=xmn for all numbers x

Question 3.
Let x,y,z be numbers. (x2 yz4 )3=
Answer:
(x2yz4 )3=((x2×y)×z4 )3 By associative law
= (x2×y)3×(z4 )3 Because (xy)n=xn yn for all numbers x, y
=(x2 )3×y3×(z4 )3 Because (xy)n=xn yn for all numbers x, y
=x6×y3×z12 Because (xm)n=xmn for all numbers x
= x6 y3 z12

Question 4.
Let x,y,z be numbers and let m,n,p,q be positive integers. (xm yn zp)q=
Ans:
(xm yn zp )q=((xm×yn )×zp)q By associative law
=(xm×yn )q×(zp )q Because (xy)n=xn yn for all numbers x, y
=(xm )q×(yn )q×(zp)q Because (xy)n=xn yn for all numbers x, y
= xmp×ynq×zpq Because (xm )n=xmn for all numbers x
=xmqynqzpq

Question 5.
\(\frac{4^{8}}{5^{8}}\) =
Answer:
\(\frac{4^{8}}{5^{8}}\) = \(\left(\frac{4}{5}\right)^{8}\)

Leave a Comment

Scroll to Top
Scroll to Top