90090 The product of the zeros of x\(^{1}\) + 4x\(^{1}\) + x - 6 is:

90091 If one of the zeros of the cubic polynomial x\(^{1}\)\(^{1}\)+ ax\(^{1}\) + bx + c is -1, then the product of the other two zeros is:

90092 if the sum of the zeroes of the cubic polynomial 4x\(^{1}\) - kx\(^{1}\) - 8x - 12 is \(\frac{-3}{4}\) then the value of 'k' is:

90093 Directions: In the following questions, the Assertions (A) and Reason(s) (R) have been put forward. Read both the statements carefully and choose the correct alternative from the following: Assertion: \((2-\sqrt{3}) \) is one zero of the quadratic polynomial then other zero will be \((2+\sqrt{3}).\) Reason: Irrational zeros (roots) always occurs in pairs.

90094 If 2, -7 and -14 are the sum, sum of the product of its zeroes taken two at a time and the product of its zeroes of a cubic polynomial, then the cubic polynomial is:

90090 The product of the zeros of x\(^{1}\) + 4x\(^{1}\) + x - 6 is:

90091 If one of the zeros of the cubic polynomial x\(^{1}\)\(^{1}\)+ ax\(^{1}\) + bx + c is -1, then the product of the other two zeros is:

90092 if the sum of the zeroes of the cubic polynomial 4x\(^{1}\) - kx\(^{1}\) - 8x - 12 is \(\frac{-3}{4}\) then the value of 'k' is:

90093 Directions: In the following questions, the Assertions (A) and Reason(s) (R) have been put forward. Read both the statements carefully and choose the correct alternative from the following: Assertion: \((2-\sqrt{3}) \) is one zero of the quadratic polynomial then other zero will be \((2+\sqrt{3}).\) Reason: Irrational zeros (roots) always occurs in pairs.

90094 If 2, -7 and -14 are the sum, sum of the product of its zeroes taken two at a time and the product of its zeroes of a cubic polynomial, then the cubic polynomial is:

90090 The product of the zeros of x\(^{1}\) + 4x\(^{1}\) + x - 6 is:

90091 If one of the zeros of the cubic polynomial x\(^{1}\)\(^{1}\)+ ax\(^{1}\) + bx + c is -1, then the product of the other two zeros is:

90092 if the sum of the zeroes of the cubic polynomial 4x\(^{1}\) - kx\(^{1}\) - 8x - 12 is \(\frac{-3}{4}\) then the value of 'k' is:

90093 Directions: In the following questions, the Assertions (A) and Reason(s) (R) have been put forward. Read both the statements carefully and choose the correct alternative from the following: Assertion: \((2-\sqrt{3}) \) is one zero of the quadratic polynomial then other zero will be \((2+\sqrt{3}).\) Reason: Irrational zeros (roots) always occurs in pairs.

90094 If 2, -7 and -14 are the sum, sum of the product of its zeroes taken two at a time and the product of its zeroes of a cubic polynomial, then the cubic polynomial is:

90090 The product of the zeros of x\(^{1}\) + 4x\(^{1}\) + x - 6 is:

90091 If one of the zeros of the cubic polynomial x\(^{1}\)\(^{1}\)+ ax\(^{1}\) + bx + c is -1, then the product of the other two zeros is:

90092 if the sum of the zeroes of the cubic polynomial 4x\(^{1}\) - kx\(^{1}\) - 8x - 12 is \(\frac{-3}{4}\) then the value of 'k' is:

90093 Directions: In the following questions, the Assertions (A) and Reason(s) (R) have been put forward. Read both the statements carefully and choose the correct alternative from the following: Assertion: \((2-\sqrt{3}) \) is one zero of the quadratic polynomial then other zero will be \((2+\sqrt{3}).\) Reason: Irrational zeros (roots) always occurs in pairs.

90094 If 2, -7 and -14 are the sum, sum of the product of its zeroes taken two at a time and the product of its zeroes of a cubic polynomial, then the cubic polynomial is:

90090 The product of the zeros of x\(^{1}\) + 4x\(^{1}\) + x - 6 is:

90091 If one of the zeros of the cubic polynomial x\(^{1}\)\(^{1}\)+ ax\(^{1}\) + bx + c is -1, then the product of the other two zeros is:

90092 if the sum of the zeroes of the cubic polynomial 4x\(^{1}\) - kx\(^{1}\) - 8x - 12 is \(\frac{-3}{4}\) then the value of 'k' is:

90093 Directions: In the following questions, the Assertions (A) and Reason(s) (R) have been put forward. Read both the statements carefully and choose the correct alternative from the following: Assertion: \((2-\sqrt{3}) \) is one zero of the quadratic polynomial then other zero will be \((2+\sqrt{3}).\) Reason: Irrational zeros (roots) always occurs in pairs.

90094 If 2, -7 and -14 are the sum, sum of the product of its zeroes taken two at a time and the product of its zeroes of a cubic polynomial, then the cubic polynomial is: