The four-color conjecture was put forward in Britain. 1852, when Francis guthrie, a graduate of London University, came to a scientific research unit to do map coloring, he found an interesting phenomenon: "It seems that every map can be colored in four colors, which makes countries with the same border have different colors." Can this conclusion be strictly proved by mathematical methods? He and his younger brother Grace, who is studying in university, decided to give it a try. The manuscripts and papers used by the two brothers to prove this problem have been piled up, but the research work has not progressed.

1852, 10 year123 October, his younger brother asked his teacher, the famous mathematician de Morgan, to prove this problem. Morgan couldn't find a solution to this problem either, so he wrote to his good friend, Sir Hamilton, a famous mathematician, for advice. Hamilton demonstrated the four-color problem after receiving Morgan's letter. But until 1866.

1872, Kelly, the most famous mathematician in Britain at that time, formally put forward this question to the London Mathematical Society, so the four-color conjecture became a concern of the world mathematical community. Many first-class mathematicians in the world have participated in the great battle of four-color conjecture one after another. During the two years from 1878 to 1880, Kemp and Taylor, two famous lawyers and mathematicians, submitted papers to prove the four-color conjecture respectively, and announced that,

1 1 years later, that is, 1890, the mathematician Herwood pointed out that Kemp's proof and his accurate calculation were wrong. Soon, Taylor's proof was also denied. Later, more and more mathematicians racked their brains for this, but found nothing. So people began to realize that this seemingly simple topic was actually a guess with Fermat.

Since the beginning of the 20th century, scientists have basically proved the four-color conjecture according to Kemp's idea. In 2003, boekhoff introduced some new techniques on the basis of Kemp, and American mathematician Franklin proved in 1939 that maps below 22 countries can be colored in four colors. In 2005, some people rose from 22 countries to 30 countries. 1000000000606, it was promoted to 50 countries. It seems that this progress is still very slow. After the appearance of electronic computer, the proof process of four-color conjecture has been greatly accelerated due to the rapid improvement of calculation speed and the appearance of man-machine dialogue. 1976, American mathematicians Appel and Harken spent 1200 hours on two different computers at the University of Illinois. Finally, the four-color theorem is proved. The computer proof of the four-color conjecture has caused a sensation in the world. It not only solved a problem that lasted for more than 100 years, but also may become the starting point of a series of new ideas in the history of mathematics. However, many mathematicians are not satisfied with the achievements made by computers, and they are still looking for a simple and clear written proof method.

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Fermat's last theorem is one of the three major mathematical problems in the modern world.

The New York Times, a recognized world newspaper, published a headline on June 24th, 1993.

About the news that the math problem has been solved, the news headline is "In the ancient math dilemma, someone finally called"

I found it. " The opening article of the first edition of The Times also attached a picture of long hair and wearing a medieval European robe.

Pictures of men. This ancient man was the French mathematician Pierre de Fermat.

Fermat is one of the most outstanding mathematicians in17th century, and he has made great achievements in many fields of mathematics.

Great contribution, because he is a professional lawyer, in order to commend his mathematical attainments, the world called him "amateur prince"

"Reputation, one day more than 360 years ago, Fermat was reading a book by the ancient Greek mathematician Diofendus.

When I was writing a math book, I suddenly wrote a seemingly simple theorem in the margin of the page.

Capacity is a problem about the positive integer solution of equation x2+y2 =z2. When n=2, it is called Pythagorean rule.

Li (also called Pythagorean Theorem in ancient China): x2+y2 =z2, where z represents the hypotenuse of a right angle, and X and Y are it.

The square of the hypotenuse of two strands, that is, a right triangle, is equal to the sum of the squares of its two strands. Of course, this equation has

Integer solutions (in fact, there are many), such as: x=3, y=4, z = 5；; x=6、y=8、z = 10； x=5、y= 12、z= 13…

Wait a minute.

Fermat claims that when n>2, there is no integer solution satisfying xn +yn = zn, such as the equation x3 +y3=z3.

Find an integer solution.

Fermat didn't explain the reason at that time, he just left this narrative, saying that he found the proof of this theorem wonderful.

Method, but there is not enough space on the page to write it down. Fermat, the initiator, also left an eternal problem, 300

Over the years, countless mathematicians have tried to solve this problem, but in vain. This Fermat, known as the century problem, is the most difficult.

The post-theorem has become a big worry in the field of mathematics, and it is eager to solve it quickly.

In the19th century, the Francis Institute of Mathematics in France provided a gold medal and two prizes in 18 15 and 1860.

Whoever solves this difficult problem will be given 300 francs, but unfortunately no one will get a reward. German mathematician Wolff

Skell (p？ Wolfskehl) provides100000 mark in 1908 to those who can prove the correctness of Fermat's last theorem.

The validity period is 100 year. During this period, due to the Great Depression, the bonus amount has depreciated to 7500 marks, although

This still attracts many "math idiots"

After the development of computers in the 20th century, many mathematicians can prove that this theorem holds when n is large.

1983, the computer expert Sloansky ran the computer for 5782 seconds, which proved that Fermat's last theorem was correct when n was 286243- 1.

(Note 286243- 1 is astronomical, with about 25960 digits).

Nevertheless, mathematicians have not found a universal proof, but this unsolved mathematical problem for more than 300 years has finally been solved.

Yes, this math problem was solved by British mathematician andrew wiles. Actually, Willis is.

The results of the development of abstract mathematics in the past 30 years of the twentieth century have proved this point.

In 1950s, Yutaka Taniyama, a Japanese mathematician, first put forward a conjecture about elliptic curvature, which was later recorded by another mathematician.

Muragoro carried it forward. At that time, no one thought that this conjecture had anything to do with Fermat's last theorem. In the 1980s, Germany

Frey, a mathematician in China, linked Yutaka Taniyama conjecture with Fermat's Last Theorem, and what Willis did was based on this connection.

Prove that one form of Yutaka Taniyama's conjecture is correct, so is Fermat's last theorem. This conclusion.

It was officially published by Willis at the seminar of Newton Institute of Mathematics, Cambridge University on June 1993, 2 1.

It immediately shocked the whole mathematics field, and even the public outside the mathematics door wall paid infinite attention to it. However, Willis's

The certificate was immediately found to have some defects, so it took Willis and his students another 14 months to correct it.

Review. 1September 1994 19 They finally handed over a complete and flawless scheme, and the nightmare of mathematics finally came to an end. 1997 6.

In August, Willis won the Wolfskeil Prize at the University of G? ttingen. 100000 FAK in that year was about $2 million.

However, when Willis received it, it was only worth about $50,000, but Willis has been recorded in the history books and will be immortal.

Prove Fermat's last theorem is correct

(that is, xn+yn = zn has no positive integer solution to n33)

Just prove that x4+ y4 = z4, xp+ yp = zp (P is an odd prime number) has no integer solution.

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Goldbach conjecture, one of the three major mathematical problems in the modern world.

Goldbach is a German middle school teacher and a famous mathematician. Born in 1690, 1725 was elected as an academician of the Academy of Sciences in Petersburg, Russia. 1742, Goldbach found in teaching that every even number not less than 6 is the sum of two prime numbers (numbers that can only be divisible by themselves), such as 6 = 3+. 12 = 5+7 and so on. 1742 On June 7th, Goldbach wrote to tell the great Italian mathematician Euler this problem and asked him to help prove it. In his reply to him on June 30th, Euler said that he thought this conjecture was correct, but he could not prove it. Even a top mathematician like Euler can't prove such a simple problem. This conjecture has attracted the attention of many mathematicians. They began to check the even number until it reached 330 million, which showed that the guess was correct. But for a larger number, the guess should be correct, but it cannot be proved. Euler didn't prove it until his death. Since then, this famous mathematical problem has attracted the attention of thousands of mathematicians all over the world. 200 years have passed. No one can prove it. Goldbach conjecture has become an unattainable "pearl" in the crown of mathematics. It was not until the 1920s that people began to approach it. 1920, the Norwegian mathematician Bujue proved it with an ancient screening method, and concluded that every even number greater than the ratio can be expressed as (99). This method of narrowing the encirclement is very effective, scientists. Gradually reduce the number of prime factors contained in each number until each number is a prime number, thus proving "Goldbach". In 2004, mathematician Rad mahar proved (7+7); 1932, mathematician eissmann proved (6+6); In 1938, mathematician Buchstaber proved (55), and in 1940, he proved (4+4). 1956, mathematician vinogradov proved (3+3); In 1958, China mathematician Wang Yuan proved (23). Later, Chen Jingrun, a young mathematician in China, also devoted himself to the study of Goldbach's conjecture. After 10 years of painstaking research, we finally made a major breakthrough on the basis of previous studies and took the lead in proving it (12). So far, Goldbach conjecture is only the last step (1+ 1). Chen Jingrun's paper was published in 1973 Science Bulletin of China Academy of SciencesNo. 17. This achievement has attracted the attention of international mathematicians, thus making China's number theory research leap to the leading position in the world. Chen Jingrun's related theory is called "Chen's Theorem". When Chen Jingrun was about to take off the jewel in the crown of mathematics, "When he was only one hurricane foot away from the brilliant peak of Goldbach's conjecture (1+ 1), he fell down exhausted ..." Behind him, more people would climb this peak.