Solution by Robert C. Gebhardt (from the Fall 1972 issue, page 349):

If no carrying were involved, we could get the answer by just adding the two digit sums together, 43 + 68 = 111. But each carry increases the final digit sum by only 1 rather than the 10 that would otherwise result. So each carry reduces our expected final digit sum by 9. In this case there are five carries, so the digit sum of the total is 43 + 68 – (5 × 9) = 66.

1. Qa6! and Black can choose among four different mates:

If he moves his knight, then 2. Qe6#.

If he takes the rook, then 2. Qc4#.

If he advances his pawn one square, then 2. Qd3#.

If he advances his pawn two squares, then 2. Nf6#.

From Benjamin Glover Laws, The Two-Move Chess Problem, 1890.

If the native’s name isn’t Saul, it’s unlikely that he’d happen to choose that name for a lie. So he’s probably telling the truth, and is likely a knight (named Saul).

Obligatory John Finnemore sketch:

Imagine that Peter and Paula simply take turns drawing balls, without bothering to inspect their color, until the urn is exhausted. Then afterward they look to see who has the red ball. The winner in this procedure will always be the same as in the original, so each player’s chance of winning will be the same as in the original game.

If k is odd, then the total number of balls is even, and when the urn is empty each player will have the same number of balls, so each of them has a 1/2 chance of winning. But when k is even, then the total number of balls is odd, and the player who draws first will have an extra ball when the drawing is done. So, generally, Paula should accept Peter’s offer to draw first — it may help her, and at worst it leaves her chances unchanged.

(From Wolfgang Schwarz, 40 Puzzles and Problems in Probability and Mathematical Statistics, 2008.)

Draw a hexagon whose sides are 100 meters long. Now draw a circle, with the same center, whose radius r is the desired length of the tether:

The difference in area between the hexagon and the circle is 6 times half the area of the meadow.

The area of the circle is πr².

The area of an equilateral triangle with side length a is .

The area of a hexagon with side length a is .

For a = 100 the area of the hexagon is . If we want a circle half that size, then and

(From Ian Stewart’s Cabinet of Mathematical Curiosities, 2009.)

If White withdraws his light-squared bishop along the b1-h7 diagonal, then Black is facing two mate threats: White can move his king off the a-file, discovering mate by the a8 rook, or he can move his dark-squared bishop off the first rank, discovering mate by the h1 queen. A few sample lines:

1. Bf5 Rxa8+ 2. Ba7#
1. Bf5 Rxh1 2. Kb3#
1. Bf5 Rh4 [ready to block a rook check or take the queen] 2. Bh2#
1. Bf5 Rd8 [ready to block a queen check or take the rook] Bd4#
(If 1. Bf5 c2 then 1. Bd4#!)

At first it looks as though Black is doomed, but he does have one resource. If after e.g. 1. Bf5 he plays 1. … Rg8 then White has no way to mate on the next move: If the white king discovers check, Black can simply take the rook, and if the g1 bishop discovers check by the queen, the rook can interpose.

The answer is 1. Bg6!, the only initial bishop move that blocks the rook’s route to g1 and keeps both mate threats alive.