The weakness of being cohesive, thin or free in reverse mathematics

Informally, a mathematical statement is robust if its strength is left unchanged under variations of the statement. In this paper, we investigate the lack of robustness of Ramsey’s theorem and its consequence under the frameworks of reverse mathematics and computable reducibility. To this end, we study the degrees of unsolvability of cohesive sets for different uniformly computable sequence of sets and identify different layers of unsolvability. This analysis enables us to answer some questions of Wang about how typical sets help computing cohesive sets.We also study the impact of the number of colors in the computable reducibility between coloring statements. In particular, we strengthen the proof by Dzhafarov that cohesiveness does not strongly reduce to stable Ramsey’s theorem for pairs, revealing the combinatorial nature of this nonreducibility and prove that whenever k is greater than l, stable Ramsey’s theorem for n-tuples and k colors is not computably reducible to Ramsey’s theorem for n-tuples and l colors. In this sense, Ramsey’s theorem is not robust with respect to his number of colors over computable reducibility. Finally, we separate the thin set and free set theorem from Ramsey’s theorem for pairs and identify an infinite decreasing hierarchy of thin set theorems in reverse mathematics. This shows that in reverse mathematics, the strength of Ramsey’s theorem is very sensitive to the number of colors in the output set. In particular, it enables us to answer several related questions asked by Cholak, Giusto, Hirst and Jockusch.

[1]  Vasco Brattka,et al.  On the Uniform Computational Content of Ramsey's Theorem , 2017, J. Symb. Log..

[2]  Joseph S. Miller,et al.  Lowness for Kurtz randomness , 2009, The Journal of Symbolic Logic.

[3]  Ludovic Patey,et al.  Degrees bounding principles and universal instances in reverse mathematics , 2014, Ann. Pure Appl. Log..

[4]  Steven M. Kautz An Improved Zero-One Law for Algorithmically Random Sequences , 1998, Theor. Comput. Sci..

[5]  S. G. Simpson An extension of the recursively enumerable Turing degrees , 2007 .

[6]  Theodore A. Slaman,et al.  On the Strength of Ramsey's Theorem , 1995, Notre Dame J. Formal Log..

[7]  Carl G. Jockusch,et al.  Ramsey's theorem and recursion theory , 1972, Journal of Symbolic Logic.

[8]  Jeremy Avigad,et al.  Algorithmic randomness, reverse mathematics, and the dominated convergence theorem , 2012, Ann. Pure Appl. Log..

[9]  Manuel Lerman,et al.  Separating Principles below Ramsey's Theorem for Pairs , 2013, J. Math. Log..

[10]  Jiayi Liu,et al.  RT2 2 does not imply WKL0 , 2012, The Journal of Symbolic Logic.

[11]  Steven M. Kautz Degrees of random sets , 1991 .

[12]  Bjorn Kjos-Hanssen,et al.  Infinite subsets of random sets of integers , 2014, 1408.2881.

[13]  Stephen G. Simpson,et al.  Subsystems of second order arithmetic , 1999, Perspectives in mathematical logic.

[14]  Wei Wang,et al.  Some logically weak Ramseyan theorems , 2014 .

[15]  Antonio Montalb An OPEN QUESTIONS IN REVERSE MATHEMATICS , 2010 .

[16]  Jeffrey B. Remmel,et al.  Pi01-Classes and Rado's Selection Principle , 1991, J. Symb. Log..

[17]  Steffen Lempp,et al.  On the role of the collection principle for Sigma^0_2-formulas in second-order reverse mathematics , 2010 .

[18]  Ludovic Patey,et al.  A Ramsey-Type K\"onig's lemma and its variants , 2014 .

[19]  Ludovic Patey Controlling iterated jumps of solutions to combinatorial problems , 2017, Comput..

[20]  C. Jockusch Degrees of generic sets , 1980 .

[21]  D. Scott Algebras of sets binumerable in complete extensions of arithmetic , 1962 .

[22]  Damir D. Dzhafarov Cohesive avoidance and strong reductions , 2014 .

[23]  R. Soare,et al.  Π⁰₁ classes and degrees of theories , 1972 .

[24]  Denis R. Hirschfeldt,et al.  Combinatorial principles weaker than Ramsey's Theorem for pairs , 2007, J. Symb. Log..

[25]  Masahiro Kumabe,et al.  Degrees of generic sets , 1996 .

[26]  Damir D. Dzhafarov,et al.  STRONG REDUCTIONS BETWEEN COMBINATORIAL PRINCIPLES , 2016, The Journal of Symbolic Logic.

[27]  Peter A. Cholak FREE SETS AND REVERSE MATHEMATICS , 2003 .

[28]  Frank Stephan,et al.  Martin-Löf random and PA-complete sets , 2016 .

[29]  Joseph R. Shoenfield,et al.  Degrees of unsolvability , 1959, North-Holland mathematics studies.

[30]  Joseph R. Mileti,et al.  On uniform relationships between combinatorial problems , 2012, 1212.0157.

[31]  C. T. CHONG,et al.  ON THE ROLE OF THE COLLECTION PRINCIPLE FOR Σ2-FORMULAS IN SECOND-ORDER REVERSE MATHEMATICS , 2009 .

[32]  Wei Wang Omitting cohesive sets , 2013, 1309.5428.

[33]  Andrey Bovykin,et al.  The strength of infinitary Ramseyan principles can be accessed by their densities , 2017, Ann. Pure Appl. Log..

[34]  C. Chong,et al.  THE METAMATHEMATICS OF STABLE RAMSEY'S THEOREM FOR PAIRS , 2014 .

[35]  Ludovic Patey Iterative forcing and hyperimmunity in reverse mathematics , 2017, Comput..

[36]  Antonio Montalbán,et al.  Open Questions in Reverse Mathematics , 2011, The Bulletin of Symbolic Logic.

[37]  ON COMBINATORIAL WEAKNESSES OF RAMSEYAN PRINCIPLES , 2015 .

[38]  Donald A. Martin,et al.  The Degrees of Hyperimmune Sets , 1968 .

[39]  Joseph R. Mileti Partition Theorems and Computability Theory , 2005, Bull. Symb. Log..

[40]  Carl G. Jockusch,et al.  On the strength of Ramsey's theorem for pairs , 2001, Journal of Symbolic Logic.

[41]  Michiel van Lambalgen,et al.  The Axiomatization of Randomness , 1990, J. Symb. Log..

[42]  Ludovic Patey,et al.  On the logical strengths of partial solutions to mathematical problems , 2014, 1411.5874.

[43]  Joseph S. Miller,et al.  FORCING WITH BUSHY TREES , 2015, The Bulletin of Symbolic Logic.

[44]  Jeffrey B. Remmel,et al.  Π01-classes and Rado's selection principle , 1991, Journal of Symbolic Logic.

[45]  D. Dzhafarov Cohesive avoidance and arithmetical sets , 2012, 1212.0828.

[46]  Richard Friedberg,et al.  A criterion for completeness of degrees of unsolvability , 1957, Journal of Symbolic Logic.

[47]  Wei Wang,et al.  THE DEFINABILITY STRENGTH OF COMBINATORIAL PRINCIPLES , 2014, The Journal of Symbolic Logic.

[48]  Frank Stephan,et al.  A Cohesive Set which is not High , 1993, Math. Log. Q..