No. The numbers total 78, so in a successful magic square each row and column would total a third of that, or 26. But only one of the primes is even, which means that in two rows and two columns we’d have to produce an even number by adding three odd numbers, which is impossible.

If the rook weren’t on f2 then White could immediately give mate with the knight. Unfortunately, moving the rook out of the way gives Black time to play 1. … Bd4, and now White’s plan doesn’t work — if the knight checks the king then the bishop can simply capture it.

The answer is 1. Rf6! This stops the bishop from reaching d4, and Black has no way to stop 2. Nf2#.

1. Kf1! Kxh3 2. Bf5#

From La Régence, 1849.

1. Bh1! Kxh1 2. Rc1#

Fold the slip and feed the strip through both holes as shown. Now you can draw one cherry through loop H.

His cross was blue. He thought, “If my cross were white, then B would see one blue and one white cross. In that event B would immediately know that his own cross could not be white, because if it were then C would see two white crosses and immediately leave the room. Similarly, if my cross were white then C would know that his own cross must be blue, since otherwise B would have gone out. Since neither B nor C has moved, my cross must be blue.”

1. Qg3! Ke7 2. Qd6#

From Jeugdproblem, 1914.

199 × the quotient equals the number we’re seeking (7777 …).

Hence (200 × the quotient) minus the quotient will give us the same number.

So let a, b, c, and d be the last four digits of the quotient. Now the quotient multiplied by 200 ends in r, s, 0, 0, where r, s are the digits that result from multiplying c, d by 2.

Here’s the subtraction:

So d must be 3, and c must be 2.

Therefore s, which we know is twice d, is 6, and r, which is twice c, is 4. And that tells us that b is 8 and a is 6.

So the last four digits of the quotient are 6823.