Find the domain of the function and write your answer in set notation. $$ \begin{array}{lll} ext { i } f(t)=\frac{1}{t^{2}-81} & ext { ii } f(a)=\sqrt[4]{a^{2}-a-6} & ext { iii } f(b)=\sqrt[3]{b^{2}-b-6} \ ext { iv } f(x)=\ln \left(x^{3}+x^{2}-2 x ight) & ext { v } f(z)=\sqrt{z}+\sqrt{10-z} & ext { vi } f(x)=\ln \left(4-x^{2} ight)\end{array} $$

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Find the domain of the function and write your answer in set notation. $$ \begin{array}{lll}	ext { i } f(t)=\frac{1}{t^{2}-81} & 	ext { ii } f(a)=\sqrt[4]{a^{2}-a-6} & 	ext { iii } f(b)=\sqrt[3]{b^{2}-b-6} \ 	ext { iv } f(x)=\ln \left(x^{3}+x^{2}-2 xight) & 	ext { v } f(z)=\sqrt{z}+\sqrt{10-z} & 	ext { vi } f(x)=\ln \left(4-x^{2}ight)\end{array} $$

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We will find the domain of each function by determining the restrictions on the variable. 1. f(t) = 1/(t² – 81) The function is undefined when the denominator is zero. Solve: t² – 81 = 0 (t – 9)(t + 9) = 0 t = 9 or t = –9 In set notation, the domain is: { t ∈ ℝ : t ≠ 9 and t ≠ –9 } 2. f(a) = √[4](a² – a – 6) Since we have an even indexed root, the radicand must be nonnegative. Set: a² – a – 6 ≥ 0 Factor the quadratic: (a – 3)(a + 2) ≥ 0 Find the critical points: a = –2 and a = 3. Use a sign chart: - For a < –2, both factors are negative so their product is positive. - For –2 < a < 3, one factor is negative and the other is positive so the product is negative. - For a > 3, both factors are positive so the product is positive. Include the points where the expression equals 0. The domain is: { a ∈ ℝ : a ≤ –2 or a ≥ 3 } In interval notation: (–∞, –2] ∪ [3, ∞) 3. f(b) = ∛(b² – b – 6) The cube root function is defined for all real numbers, so there are no restrictions. Domain: ℝ 4. f(x) = ln(x³ + x² – 2x) The natural logarithm requires its argument to be positive, so: x³ + x² – 2x > 0 Factor the expression: x(x² + x – 2) > 0 x(x + 2)(x – 1) > 0 The critical points are x = –2, 0, and 1. Test intervals: - For x < –2, choose x = –3: (–3)(–3+2=–1)(–3–1=–4) → negative × negative × negative = negative. - For –2 < x < 0, choose x = –1: (–1)(1)(–2) → negative × positive × negative = positive. - For 0 < x < 1, choose x = 0.5: (0.5)(2.5)(–0.5) → positive × positive × negative = negative. - For x > 1, choose x = 2: (2)(4)(1) → all positive = positive. Also, the expression is zero at x = –2, 0, and 1; these cannot be included since ln(0) is undefined. Therefore, the domain is: { x ∈ ℝ : –2 < x < 0 or x > 1 } In interval notation: (–2, 0) ∪ (1, ∞) 5. f(z) = √z + √(10 – z) Both square roots require their radicands to be nonnegative: - For √z: z ≥ 0 - For √(10 – z): 10 – z ≥ 0 → z ≤ 10 Hence, the domain is: { z ∈ ℝ : 0 ≤ z ≤ 10 } In interval notation: [0, 10] 6. f(x) = ln(4 – x²) The natural logarithm requires: 4 – x² > 0 x² < 4 Solving, we get: –2 < x < 2 Thus, the domain in set notation is: { x ∈ ℝ : –2 < x < 2 } Summary of Answers: i. { t ∈ ℝ : t ≠ 9 and t ≠ –9 } ii. { a ∈ ℝ : a ≤ –2 or a ≥ 3 } iii. ℝ iv. { x ∈ ℝ : –2 < x < 0 or x > 1 } v. [0, 10] vi. { x ∈ ℝ : –2 < x < 2 } The domains of the functions are as follows: 1. $$ f(t) = \frac{1}{t^2 - 81} $$: $$ t eq 9 $$ and $$ t eq -9 $$ 2. $$ f(a) = \sqrt[4]{a^2 - a - 6} $$: $$ a \leq -2 $$ or $$ a \geq 3 $$ 3. $$ f(b) = \sqrt[3]{b^2 - b - 6} $$: All real numbers ($$ \mathbb{R} $$) 4. $$ f(x) = \ln(x^3 + x^2 - 2x) $$: $$ -2 < x < 0 $$ or $$ x > 1 $$ 5. $$ f(z) = \sqrt{z} + \sqrt{10 - z} $$: $$ 0 \leq z \leq 10 $$ 6. $$ f(x) = \ln(4 - x^2) $$: $$ -2 < x < 2 $$ In set notation: 1. $$ \{ t \in \mathbb{R} : t eq 9 ext{ and } t eq -9 \} $$ 2. $$ \{ a \in \mathbb{R} : a \leq -2 ext{ or } a \geq 3 \} $$ 3. $$ \mathbb{R} $$ 4. $$ \{ x \in \mathbb{R} : -2 < x < 0 ext{ or } x > 1 \} $$ 5. $$ [0, 10] $$ 6. $$ \{ x \in \mathbb{R} : -2 < x < 2 \} $$

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