Asked by AD

The missing exponent in the equation is 235.

To simplify the expression 12^87 divided by 12^25, subtract the exponents:

12^(87 – 25) = 12^62

The value of 6.0 - 2^0 is 5.0. None of the answer choices provided is correct.

The value of 6.9 - 2^0 is 5.9. Therefore, the correct answer is 5.9.

Applying the zero power rule, any non-zero number raised to the power of 0 is equal to 1. Therefore, we have:

9 x (-33)^0 + 3/2 ( 8 - 27^0 ) = 9 x 1 + 3/2 ( 8 - 1 )

We can simplify this further:

= 9 + 3/2 ( 7 )

= 9 + 21/2

This can be written as:

9 + 10.5

Therefore, the equivalent expression is:

9 + 10.5 + 3/2 ( 8 - 1 )

To solve the expression 15 - 8^0/5 + 4(7^0 - 6), we follow the order of operations (parentheses, exponents, multiplication/division, addition/subtraction):

First, we evaluate the exponent 8^0, which is equal to 1.

Now we can substitute this value back into the original expression:

15 - 1/5 + 4(1 - 6)

Next, we simplify within the parentheses:

15 - 1/5 + 4(-5)

Now, multiply 4 by -5:

15 - 1/5 - 20

We can rewrite 15 as a fraction with a common denominator of 5:

75/5 - 1/5 - 20

Now combine the fractions:

(75 - 1)/5 - 20

Simplify the numerator:

74/5 - 20

To combine these fractions, we need to find a common denominator. Multiplying 20 by 5 gives us 100:

74/5 - 100/5

Now we can combine the fractions:

(74 - 100)/5

Simplify the numerator:

-26/5

Therefore, the solution to the expression 15 - 8^0/5 + 4(7^0 - 6) is -26/5 or -5.2.

To simplify (10^3)^6 using the power rule of exponents, we multiply the exponents:

(10^3)^6 = 10^(3*6) = 10^18

Therefore, (10^3)^6 simplifies to 10^18.

The correct expanded equivalent expression when simplifying 7^15 using the power rule of exponents would be (7 x 7 x 7 x 7 x 7)^10.

Therefore, the correct choice is:

( 7 x 7 x 7 x 7 x 7 )^10

To create a simplified equivalent expression for (19^4)^9 using the power rule of exponents, we multiply the exponents:

(19^4)^9 = 19^(4*9) = 19^36

Therefore, the simplified equivalent expression for (19^4)^9 is 19^36.

Applying the property of negative integer exponents, we know that:

a^(-n) = 1/(a^n)

Therefore, for 7^-3:

7^-3 = 1/(7^3)

Simplifying further:

7^3 = 7 x 7 x 7 = 343

Thus, 7^-3 = 1/343.

Applying the property of negative exponents, we can rewrite 3^-17 as 1/3^17 and 8^-14 as 1/8^14.

Therefore, the expression 3^-17/8^-14 can be rewritten as (1/3^17)/(1/8^14).

To simplify this further, we can multiply the numerator and denominator by the reciprocal of the denominator, which is 8^14/1.

This gives us (1/3^17) * (8^14/1).

Now, we can simplify the expression using positive exponents:

(8^14)/(3^17).

So, an expression equivalent to 3^-17/8^-14 with positive exponents only is (8^14)/(3^17).

Applying the properties of integer exponents, we can simplify the expression (7^-3)^7 x (7^20)/6^-2 with only positive exponents.

First, let's simplify the exponent (7^-3)^7. Using the property (a^m)^n = a^(m*n), we have:

(7^-3)^7 = 7^(-3*7) = 7^-21

Next, we simplify the exponent 6^-2. Using the property a^(-n) = 1/(a^n), we have:

6^-2 = 1/(6^2) = 1/36

Now we can rewrite the expression with positive exponents:

(7^-21) x (7^20)/6^-2 = (1/7^21) x (7^20)/(1/36)

Using the property of division, division of two fractions can be simplified to a multiplication by the reciprocal of the divisor:

(1/7^21) x (7^20) x (36/1)

Now, we use the property a^m x a^n = a^(m+n):

(1/7^21) x (7^20) x (36/1) = (1 x 7^20 x 36) / (7^21 x 1)

Simplifying the numerator and denominator separately:

7^20 x 36 = 7^(20+2) = 7^22

7^21 x 1 = 7^21

Now we have:

(7^22) / (7^21)

Using the property a^m / a^n = a^(m-n):

(7^22) / (7^21) = 7^(22-21) = 7^1

Therefore, the solution to the expression is 7 as an improper fraction: 7/1.

To simplify the expression (4x^3)^2 using properties of integer exponents, we apply the power rule of exponents, which states that (a^m)^n = a^(m*n).

In this case, we have (4x^3)^2, where 4 and x^3 are the base and 2 is the exponent.

Applying the power rule, we have:

(4x^3)^2 = 4^(2*1) * (x^3)^(2*1)

Simplifying:

= 4^2 * x^(3*2)

= 16x^6

Therefore, the simplified expression is 16x^6.

To generate an equivalent algebraic expression for (4x^4y^-4)^3/(x^7y^3)^2 using the properties of integer exponents, we'll apply the power and division rules of exponents.

First, let's simplify the numerator: (4x^4y^-4)^3
Using the power rule of exponents, we raise each term inside the parentheses to the power of 3:
4^3 * (x^4)^3 * (y^-4)^3

Simplifying the exponents:
64 * x^(4*3) * y^(-4*3)
64 * x^12 * y^(-12)

Now, let's simplify the denominator: (x^7y^3)^2
Using the power rule of exponents, we raise each term inside the parentheses to the power of 2:
(x^7)^2 * (y^3)^2
x^(7*2) * y^(3*2)
x^14 * y^6

Therefore, the expression becomes:
(64 * x^12 * y^(-12))/(x^14 * y^6)

Using the division rule of exponents, we subtract the exponents of the common bases:
64 * x^(12 - 14) * y^(-12 - 6)
64 * x^(-2) * y^(-18)

Finally, we can rewrite this in a positive exponential form:
64/(x^2y^18)

Therefore, the equivalent algebraic expression to (4x^4y^-4)^3/(x^7y^3)^2 is 64/(x^2y^18).

The product rule of integer exponents states that when multiplying two numbers with the same base, we add their exponents.

In this case, we have 12^-5 x 12^7, and since both terms have the base 12, we can apply the product rule by adding their exponents.

12^-5 x 12^7 = 12^(-5 + 7)

Now let's simplify the exponent:

-5 + 7 = 2

Therefore, 12^-5 x 12^7 simplifies to 12^2.

To calculate the numerical value, we can evaluate 12^2:

12^2 = 12 x 12 = 144

So, the numerical equivalent of 12^-5 x 12^7 is 144.

You're welcome! If you have any more questions, feel free to ask.