Hilbert’s Mathematical Problems
Table of contents
(The actual text is on a separate page.)
Introduction. 
(Philosophy of problems, relationship between mathematics and science, role of proofs, axioms and formalism.) Précis 1 

Problem 1. 
Cantor’s problem of the cardinal number of the continuum. (The continuum hypothesis.) Number 1  K. Gödel. The consistency of the axiom of choice and of the generalized continuum hypothesis. Princeton Univ. Press, Princeton, 1940. 
Problem 2. 
The compatibility of the arithmetical axioms. Number 2  
Problem 3. 
The equality of two volumes of two tetrahedra of equal bases and equal altitudes. Number 3  V. G. Boltianskii. Hilbert’s Third Problem Winston, Halsted Press, Washington, New York, 1978. C. H. Sah. Hilbert’s Third Problem: Scissors Congruence. Pitman, London 1979. 
Problem 4. 
Problem of the straight line as the shortest distance between two points. (Alternative geometries.) Number 4  
Problem 5. 
Lie’s concept of a continuous group of transformations without the assumption of the differentiability of the functions defining the group. (Are continuous groups automatically differential groups?) Number 5  Montgomery and Zippin. Topological Transformation Groups. Wiley, New York, 1955. Kaplansky. Lie Algebras and Locally Compact Groups. Chicago Univ. Press, Chicago, 1971. 
Problem 6. 
Mathematical treatment of the axioms of physics. Number A  Leo Corry’s article “Hilbert and the Axiomatization of Physics (18941905)” in the research journal Archive for History of Exact Sciences, 51 (1997). 
Problem 7. 
Irrationality and transcendence of certain numbers. Number B  N.I.Feldman. Hilbert’s seventh problem (in Russian), Moscow state Univ, 1982, 312pp. MR 85b:11001 
Problem 8. 
Problems of prime numbers. (The distribution of primes and the Riemann hypothesis.) Number C  
Problem 9. 
Proof of the most general law of reciprocity in any number field. Number D  
Problem 10. 
Determination of the solvability of a diophantine equation. Number E  S. Chowla. The Riemann Hypothesis and Hilbert’s Tenth Problem. Gordon and Breach, New York, 1965. Yu. V. Matiyasevich. Hilbert’s Tenth Problem. MIT Press, Cambridge, Massachusetts,1993, available on the web. 
Maxim Vsemirnov’s Hilbert’s Tenth Problem page at the Steklov Institute of Mathematics at St.Petersburg.  
Problem 11. 
Quadratic forms with any algebraic numerical coefficients. Number F  
Problem 12. 
Extension of Kroneker’s theorem on abelian fields to any algebraic realm of rationality. Number G  R.P. Holzapfel. The Ball and Some Hilbert Problems. SpringerVerlag, New York, 1995. 
Problem 13. 
Impossibility of the solution of the general equation of the 7th degree by means of functions of only two arguments. (Generalizes the impossibility of solving 5th degree equations by radicals.) Number H  
Problem 14. 
Proof of the finiteness of certain complete systems of functions. Number I  Masayoshi Nagata. Lectures on the fourteenth problem of Hilbert. Tata Institute of Fundamental Research, Bombay, 1965. 
Problem 15. 
Rigorous foundation of Schubert’s enumerative calculus. Number J  
Problem 16. 
Problem of the topology of algebraic curves and surfaces. Number K  Yu. Ilyashenko, and S. Yakovenko, editors. Concerning the Hilbert 16th problem. American Mathematical Society, Providence, R.I., 1995. B.L.J. Braaksma, G.K. Immink, and M. van der Put, editors. The Stokes Phenomenon and Hilbert’s 16th Problem. World Scientific, London, 1996. 
Problem 17. 
Expression of definite forms by squares. Number L  
Problem 18. 
Building up of space from congruent polyhedra. (ndimensional crystallography groups, fundamental domains, sphere packing problem.) Number M  
Comments 
on the theory of analytic functions. Number N  
Problem 19. 
Are the solutions of regular problems in the calculus of variations always necessarily analytic? Number  
Problem 20. 
The general problem of boundary values. (Variational problems.) Number  
Problem 21. 
Proof of the existence of linear differential equations having a prescribed monodromic group. Number  
Problem 22. 
Uniformization of analytic relations by means of automorphic functions. Number  
Problem 23. 
Further development of the methods of the calculus of variations. Number  
Final comments. 
Précis 2 