# Euler problems/131 to 140

### From HaskellWiki

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== [http://projecteuler.net/index.php?section=view&id=131 Problem 131] == | == [http://projecteuler.net/index.php?section=view&id=131 Problem 131] == | ||

Determining primes, p, for which n3 + n2p is a perfect cube. | Determining primes, p, for which n3 + n2p is a perfect cube. | ||

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problem_140 = undefined | problem_140 = undefined | ||

</haskell> | </haskell> | ||

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## Revision as of 12:14, 30 September 2007

## Contents |

## 1 Problem 131

Determining primes, p, for which n3 + n2p is a perfect cube.

Solution:

problem_131 = undefined

## 2 Problem 132

Determining the first forty prime factors of a very large repunit.

Solution:

problem_132 = undefined

## 3 Problem 133

Investigating which primes will never divide a repunit containing 10n digits.

Solution:

problem_133 = undefined

## 4 Problem 134

Finding the smallest positive integer related to any pair of consecutive primes.

Solution:

problem_134 = undefined

## 5 Problem 135

Determining the number of solutions of the equation x2 − y2 − z2 = n.

Solution:

problem_135 = undefined

## 6 Problem 136

Discover when the equation x2 − y2 − z2 = n has a unique solution.

Solution:

problem_136 = undefined

## 7 Problem 137

Determining the value of infinite polynomial series for which the coefficients are Fibonacci numbers.

Solution:

problem_137 = undefined

## 8 Problem 138

Investigating isosceles triangle for which the height and base length differ by one.

Solution:

problem_138 = undefined

## 9 Problem 139

Finding Pythagorean triangles which allow the square on the hypotenuse square to be tiled.

Solution:

problem_139 = undefined

## 10 Problem 140

Investigating the value of infinite polynomial series for which the coefficients are a linear second order recurrence relation.

Solution:

problem_140 = undefined