Can you find a seven-digit number containing seven different digits, whose prime factors are four two-digit primes containing between them eight different digits?

This is quite similar to PotW #320 but differs in a couple of respects. Firstly, the rectangle is a slightly different height. Secondly, the point F no longer needs to lie on CD, but is free to be anywhere, subject to the other conditions (that ABCD is a rectangle, AEF is a right angle, and E lies on BC.

What is the minimum that DF could be?

I have a number, let’s call it n. n doesn’t have any repeated prime factors. For every prime number p, p divides into n IF AND ONLY IF p-1 also divides into n.

For instance, if 23 divides into n, then 22 does also, and if 59 doesn’t divide into n, then neither does 58.

What is the value of n?

What are the missing digits in this product of fractions?

A rectangle ABCD has width 64 and height 80. A right-angled triangle AEF is drawn as shown. What is the minimum that DF could be?

w + x + y + z = 2

w^2 + x^2 + y^2 + z^2 = 2

w^3 + x^3 + y^3 + z^3 = -4

w^4 + x^4 + y^4 + z^4 = -6

What is the value of: w^7 + x^7 + y^7 + z^7 ?

What is the lowest number n such that if a is the highest prime factor of n, then b (not equal to a) is the highest prime factor of (n-a), and c (not equal to a or b) is the highest prime factor of (n-a-b)?

For instance, a higher example is 700. The highest prime factor of 700 is 7, the highest prime factor of 693 is 11, and the highest prime factor of 682 is 31.

There are two ships, a fast one and a slower one, each travel consistently at their own fixed speed.

If the fast ship travels in a straight line from Duxmouth to Boxcote and the slow ship travels from Axton to Caxcombe, and they each set off at the same time, they will collide where the routes cross.

Similarly, if the fast ship travels in a straight line from Caxcombe to Axton and the slow ship travels from Boxcote to Duxmouth, and they each set off at the same time, they will again collide where the routes cross.

If the fast ship travels from Caxcombe to Duxmouth and the slow ship from Axton to Boxcote, and they set off at the same time, clearly they won’t clash, as the routes don’t cross, but which ship will reach its destination first?

It's been a while since I invented a new puzzle type, although this one is a combination of a couple of ideas already around in puzzle world.

Your task is to subdivide the grid into regions, such that every region has 180-degree rotation symmetry. (They might also have 90-degree symmetry and/or reflective symmetry, but this is not necessary).

Every square that in the solved grid is bordered by 2 or fewer lines, is denoted by the number of lines bordering it. Any square that will have 3 or 4 lines bordering it, is left blank.

The only other rule is that you can't have two single square regions next to each other, hence why the top right corner of the example must be a pair.

The longest streak of consecutive numbers, NONE of whose digit sums is a multiple of 7, is 12 in a row. For instance:

994, digit sum = 9+9+4 = 22, remainder after division by 7 = 1

995, digit sum = 9+9+5 = 23, remainder after division by 7 = 2

996, digit sum = 24, remainder after division by 7 = 3

997, digit sum = 25, remainder after division by 7 = 4

998, digit sum = 26, remainder after division by 7 = 5

999, digit sum = 27, remainder after division by 7 = 6

1000, digit sum = 1, remainder after division by 7 = 1

1001, digit sum = 2, remainder after division by 7 = 2

1002, digit sum = 3, remainder after division by 7 = 3

1003, digit sum = 4, remainder after division by 7 = 4

1004, digit sum = 5, remainder after division by 7 = 5

1005, digit sum = 6, remainder after division by 7 = 6

By the same notion, the length of the longest streak of consecutive numbers, NONE of whose digital sums is a multiple of 13, happens to be an exact multiple of 13 itself.

How long is the streak, and can you find an example?

Imagine a number system where the only numbers are those that are 1 greater than a multiple of 20, for instance, 21, 81, 1741. You cannot add or subtract using this number system without the result being a number outside the number system, however it is possible to multiply, as multiplying together two numbers that are each 1 greater than a multiple of 20 will result in a third number that is also 1 greater than a multiple of 20. For example, 21 x 61 = 1281.

‘Prime’ numbers exist in this system, defined as numbers that cannot be formed by multiplying together two smaller numbers in the number system. All actual primes, such as 41, are obviously still prime in this system, but other numbers, such as 21 or 81, are not prime usually, but are in this system.

One well known fact about ordinary numbers is that they are the product of prime numbers in exactly one way, for example 72 = 2x2x2x3x3. However, it is possible for numbers in this special number system to be the product of ‘prime’ (within the system) numbers in more than one way.

What is the smallest number in this number system that is the product of ‘primes’ in two distinct ways?

A Wolf Tooth cube is a strange and interesting puzzle. It is almost like solving two puzzles at once. In essence it is a cube and an octahedron intersected. Each of the six cube faces has one of the octahedron vertices in the centre, a square based pyramid with four different colours on it. Each of the eight octahedron faces has one of the cube vertices in the centre, a triangular based pyramid with three different colours on it.

The arrangement of colours on the cube part are as follows:

Red is opposite Orange

White is opposite Yellow

Blue is opposite Green

Red White and Blue appear clockwise on their shared vertex

The arrangement of colours on the octahedron part are as follows:

Red is opposite White

Yellow is opposite Silver

Purple is opposite Blue

Orange is opposite Green

Red Yellow Purple and Orange appear clockwise around their shared vertex

It is possible to orient the octahedron through the cube such that none of the same colours on the cube and octahedron are in contact?

If so what four colours appear on the octahedron vertex in the middle of the green cube face?

To illustrate the objective of the puzzle, in the cube above the white cube face and the white octahedron face are not in contact, whereas the green cube face and the green octahedron face are in contact, which is not permitted within this puzzle.

(For the purposes of this puzzle I have changed the order of the colours on the octahedron part from the colouring on an actual Wolf Tooth cube, shown here.)

ABCD is a square with side length of 2, rotated through 45 degrees so that the diagonal BD becomes horizontal. A circle of unknown radius is drawn through B and D as shown. Within the large circle two further circles are drawn, respectively above and below BD, and the maximum size they can be whilst staying within the large circle.

The region that lies within the large circle but outside of the two smaller circles is shaded.

What is the area of the shaded region?

I happened to notice that if I took a number that was the sum of two different squares (eg, 4+1 = 5) and multiplied it by a different number that was also the sum of two different squares (eg, 9+1 = 10), the result (50) would also be the sum of two different squares: (49+1).

But is this always true?

I have three straight lengths of fencing, measuring 25m, 33m and 39m, and a long straight brick wall. Using the wall and the three fences, what is the greatest area I can enclose?

Here is a puzzle you might not have met before, as it’s one of my own invention. A cross between a Fill-In and a Skeleton which I call ‘Shadowbox’.

Place all the listed words into the grid, crossword style, such that every white square contains a consonant, and every grey square either contains a vowel (A, E, I, O, U), or becomes a black square. The pattern of black squares in the grid is fully symmetrical.

If you enjoy this, I wrote an entire book of them, available online:

https://www.amazon.co.uk/Shadowbox-Logical-Crossword-Puzzles-Elliott/dp/1447861965

This puzzle is based on a similar algorithm to last week’s puzzle, but this time the sequence descends from any composite number, and stops when it reaches a number that is not composite (so, either a prime number or the number 1).

At each stage find the largest prime factor of your number and SUBTRACT this plus one from your number to get the next number, for instance: 24 -> 20 -> 14 -> 6 -> 2

There are many, possibly infinitely many, starting numbers that terminate at either 1 or 2, whereas there are no starting numbers that reach 3 or 7. 5 however is a more interesting case, there is a relatively small set of numbers that lead to 5. Can you find them all?

A while ago I ‘invented’ an interesting mathematical algorithm as follows.

 Start with any whole number ‘n’.

If ‘n’ is prime, stop.

If ‘n’ is composite, list its prime factors and find the largest, let’s call it ‘m’

Let your new ‘n’ be equal to n+m+1, and repeat the whole sequence.

 For instance if we start with 15:

 15

Not prime, highest prime factor is 5, so add 6

21

Not prime, highest prime factor is 7, so add 8

29

Prime, stop

If you start with the number 38, which prime number do you eventually end up at? 

What are the last five digits of the following number?

To be clear, in the absence of brackets, a power tower in calculated from the top, so that 3^3^3 = 3^27, not 27^3.