1. Bb5 (there’s a metaphor in here somewhere) and the queen will mate.

From the Central New Jersey Herald, via Charles F. Wadworth, Unique Chess Problems, 1890.

Keep the goat in the boat with you for the first two trips, taking first the dog and then the cabbage across and leaving them on the opposite bank. Take the goat back with you and leave it on the riverbank by itself as you take the two wolves across. Leave them with the cabbage and return with the dog. Collect the goat and bring it and the dog to the farther shore.

(By E. Chernyshov, via Quantum, May 1990.)

If we work backward, we can see that at each step there’s only one way in which the money can have been distributed:

After three rounds, they have $24, $24, and $24.

So after two rounds the amounts must have been $12, $12, and $48.

Hence after one round the amounts must have been $6, $42, and $24.

And thus originally the amounts were $39, $21, and $12.

Under the rules as described, with each man losing once, these must be the amounts that they started with. Note that the total amount held by the group is always $72.

From Edward Barbeau, Murray Klamkin, and William Moser, Five Hundred Mathematical Challenges, 1995.

Solution:

1. Rc2 b5 2. Kc7 (any) 3. Ra2#

1. Rc2 Ka8 2. Kc7 (any) 3. Ra2#

1. Rc2 Kb8 2. Kxb6 Ka8 3. Rc8#

“The trick was to first reverse the tube so that the three depressions, D, E, and F, were at the bottom. It was quite easy to get the shots into these hollows, and when you had them in position you had merely to twist the tube with a quick turn of the fingers, holding it at the ends, when the pellets would fall into the required positions. You could hardly fail once in a hundred attempts, yet I have seen people try the puzzle for hours without success, while this simple trick never occurred to them.”

(Henry E. Dudeney, “The World’s Best Puzzles,” Strand 36:216 [January 1909], 692-700.)

3816547290.

(By Nob Yoshigahara.)

09/14/2021 UPDATE: I came across this puzzle in Yoshigahara’s 2004 book Puzzles 101: A Puzzlemaster’s Challenge. In an article in Quanta last year, Pradeep Mutalik credits it to John Horton Conway. I don’t know who came up with it first; possible the two devised it independently. (Thanks, Dharmesh.)

09/17/2021 UPDATE: Reader Ben Hamula has worked out programmatically that this solution is unique.

09/17/2021 UPDATE: This is getting interesting. Reader Hans Havermann finds that neither Yoshigahara nor Conway originated the problem. The earliest known mention is in the December 1984 issue of the New Zealand Mathematical Society newsletter (Problem 15 on page 17). David B. Gauld, mentioned in that problem, is sometimes cited as its author; Gauld contributed OEIS sequence A181736 in 2010. Immediately after the problem appeared in the New Zealand newsletter, Kishor N. Gordhandas posed it in the January 1985 issue of Games (page 2) and it generally escaped into the wild.

Hans contacted Gauld, who recalls that he encountered 3816547290 in François Le Lionnais and Jean Brette’s 1983 book Les nombres remarquables and passed it on to Teddy Zulauf, sub-editor of the NZMS newsletter. Many thanks to Hans for all this yeoman sleuthing; I’ll post a further update if Le Lionnais turns out to cite a source.

09/30/2021 UPDATE: Le Lionnais cites no source but calls the fact “Trés remarquable.” See Hans’ blog for more on the search.

10/04/2021 UPDATE: It appears Hans has identified the originator of the puzzle: Lea Gorodisky, in the Spanish puzzle magazine The Snark. See the link immediately above. (Thanks again, Hans.)

“Play the three queens as follows. There is no necessity to give the moves of the Black king, as they are all forced.”

1. Qe1 (“just a waste move”) 2. Qh1 3. Qhg1 4. Qgf1 5. Qce1 6. Qa1+ 7. Qeb1#

Call the number of exams n. Then the total number of points distributed is n(A + B + C) = 20 + 10 + 9 = 39. Since A, B, and C are distinct, their sum must be at least 1 + 2 + 3 = 6, and the only combination of factors that can give us 39 is n = 3 and A + B + C = 13.

Assume without loss of generality that A > B > C. We’re told that Betty placed first in arithmetic, so she received A points on that exam. But we also know that she received 10 points overall, which is fewer than A + B + C = 13, so she must have received C points in both remaining exams (one of which is spelling).

Carol received 9 points overall, which is also less than A + B + C = 13. But she must have received at least B points on two of the exams (since Betty accounts for two Cs), one of which is spelling. If she’d received A points in the spelling exam, though, she’d have a total of at least A + B + C = 13. That’s a contradiction. So Carol must have scored B points in spelling, placing second.

(It can be worked out that Alice, Betty, and Carol scored B + A + A, A + C + C, and C + B + B, respectively, and that A = 8, B = 4, and C = 1.)

(From Dušan Djukic et al., The IMO Compendium: A Collection of Problems Suggested for the International Mathematical Olympiads: 1959-2004, 2006.)

He should collect the bicycle. By symmetry he can reach point P two miles north of Q in the same time as it takes to reach the village. He can cycle from the village to the town quicker than he can walk there from P.

(From the October 1949 issue of the society’s journal, Eureka. The Eureka archive is published under a Creative Commons license.)