Futility Closet An idler's miscellany of compendious amusements

Typically for Loyd, the answer is the least likely move on the board:

1. Nd2! (threatening 2. Rxe2#)

If 1…Kxf2 then 2.Qg3#
If 1…Kxd2 then 2.Qc3#
If 1…Rxe3 then 2.Qxe3#

Suppose it’s rational. Then log₁₀ 5 = a/b, where a and b are positive integers. Then 10^a/b = 5 and 10^a = 5^b. But these two values can never be equal — any positive integral power of 10 will end in 0, and any such power of 5 will end in 5. So log₁₀ 5 cannot be rational.

1. Qh2! threatens 2. Nf5#. If 1. … Kf4 then 2. Ne4#, and if 1. … Kd4 then the queen mates from h8.

From The Chess Players’ Chronicle, 1874.

Yes. Imagine that the king is on the lower left square and that on each move he takes a step along the main diagonal toward the upper right. After his first move and Black’s response, there must be no rooks on the lowest three ranks or the leftmost three files, or the king could immediately reach a threatened square. After his 998th move, the king arrives at a similar situation in the upper right: At this point there must be no rooks on the uppermost three ranks or the rightmost three files, for the same reason. This means that when the king begins his journey, all the rooks must be northeast of him, and when he finishes, all must be southwest. During the trip, then, each of Black’s 499 rooks must change both its rank and its file, in order to keep out of his way. This requires 499 x 2 = 998 moves. So, at the latest, Black will run out of time just a half-move too soon: White will squeeze Black’s maneuvering room down to zero on his own 998th move, just before Black evacuates the last rook.

From Miodrag Petkovic, Mathematics and Chess, 1997.

1. Qc7! cxd2 2. Qc3#

From American Chess-Nuts, 1868.

If White could pass his turn, Black would have to promote the pawn or play 1. … Kd1, inviting mate in every variation:

2. Kd1 Qxd2#
2. d1=Q(or R) Bh4#
2. d1=B (or N) Bd2#

To reach these lines, White needs to play a waiting move now. But this is tricky to find: If he marks time by moving the bishop, then Black can mark time by advancing the g-pawn. And if White moves the king to b3, b2, b1, or a1, then Black can promote the pawn with check. The only safe move is 1. Ka3!, and now Black must submit to one of the lines above.

From the St. John Globe, 1905.

With 1. Qf3 White threatens 2. Qh5#. If Black captures the queen then 2. d4 is mate. His only other defenses require moving the bishop (Bxb3/Be6/Bf7), which permits an immediate 2. Qxe4#.

From The Chess Players’ Chronicle, 1872.

After 1. Kg1 Black has no safe move:

• If he moves the king to e4 or f3, then the queen zooms westward to infinity and mates, attacking simultaneously from left and right on every rank.
• If he moves the king onto the g-file then the queen zooms southwestward to infinity, attacking simultaneously along all the southwest-northeast diagonals from both directions.
• If he moves the d-pawn then again the queen can mate from the southwest/northeast.
• If he moves the b6 knight (anywhere), then the queen zooms northwest and attacks along the northwest-southeast diagonals.
• If he moves the c7 knight then the queen zooms north and attacks along the files.

Given all this firepower, White’s main task is really to find a square where his king is safely out of the way. But that’s tricky. After 1. Kh1?, for example, Black has 1. … Nbd5! and there’s no mate.

Yes. The father sets out with his first son, leaving the second boy to walk alone. Father and son drive 24 kilometers, which takes 6/5 hours. Then the father puts down the first son and rides back to meet the second son 9 kilometers from home, which takes 3/5 hours. Finally he and the second son ride 6/5 hours more and reach grandmother’s house just as the first son is arriving there on foot. Each son spends 6/5 hours riding 24 kilometers and 9/5 hours walking 9 kilometers, so the three of them reach grandmother’s in exactly 3 hours.

The surprising 1. Qh3! leaves Black with no options. If he moves his knight then White can take the rook with mate, and if he moves the rook then White’s knight will mate.

From Teplitz-Schönauer Anzeiger, 1921.

“The two children were so befogged over the calendar that they had started on their way to school on Sunday morning!”

In presenting this problem in Ingenuity in Mathematics, Ross Honsberger gave a complex analysis, but his friend Scott Vanstone showed a simple way to visualize it, building on an observation by John Annulis:

Each boy is represented by a point, and each pair of boys named in an accusation are joined by a line. Now we know that each line has a thief at one end and an innocent at the other, except for one line, which has an innocent at both ends (due to the outright liar). Since four boys named one guilty boy correctly, the two points that represent the thieves are attached to a total of four lines. And because no boy made two accurate accusations, the thieves themselves are not joined by a line. The only two points that satisfy all these requirements indicate Charlie and James.

Yes. First three cannibals cross; then the two rowers return, bearing an extra missionary; then the rowing missionary crosses with a cannibal and returns with two missionaries; and finally the rowing cannibal crosses:

Mmmm Cccc
MmmmCcc c
mmcc MmCc
Mmmccc mC
ccc MmmmC
Cccc Mmmm

1. Qf8! and the queen will mate.

From the Chicago Times, 1879.

80 cents. It’s tempting to say that the answer is 81 cents, since paying for nine 90-cent packets will give us 10 packets total, meaning we’ve paid ($0.90 × 9) / 10 = $0.81 for each packet. But the free packet itself includes a voucher, which is worth something.

Maslanka suggests this thought experiment: Borrow a packet from a friend, then buy eight additional packets for $0.90 × 8 = $7.20. Consume the nine packets, redeem the nine vouchers for a free packet, and use this to repay your friend. You’ve consumed nine packets of sugar for $7.20, so each packet is worth 80 cents.

From Maslanka’s “A Bouquet of Brainteasers,” in Tribute to a Mathemagician, 2005.

Take 1 pill from the first bottle, 2 from the second, 4 from the third, 8 from the fourth, 16 from the fifth, and 32 from the sixth. This gives us 63 pills that ought to weigh 315 grams. As before, the bad pills will add some excess weight, but now that weight can tell us which combination of bottles is bad. Suppose the 63 pills weigh 336 grams, or 21 grams too much. That extra 21 grams can only have come from the fifth bottle (16 grams), the third (4 grams), and the first (1 gram). The same is true for any overage: Because any integer is uniquely expressible as the sum of powers of 2, the excess weight will always identify uniquely any combination of bad bottles.

He numbers the bottles from 1 to 10, then takes one pill from bottle one, two pills from bottle two, and so on. This gives him a pile of 55 pills that ought to weigh 275 grams. Its difference from this weight can tell him which bottle is bad: If the pile is 1 gram overweight then the bad pills are in bottle one, if 2 grams then they’re in bottle two, and so forth.

1. Ra5! The rook tours the fifth rank and returns to its original square, forcing 1. … Kc1 2. Ra1#. The normal-seeming 1. Rxa6, which would ordinarily lead to the same mate, here fails because Black can take the rook.

By Kuznecov and Plaskin, from Miodrag Petković, Mathematics and Chess, 1997.

Eighty-four.

1. He says, “I want to buy a saw.”
2. Drive backward.
3. Its name.
4. An hour and a quarter is 75 minutes.
5. Yes.
6. One.