Almost Mathieu operator

In mathematical physics, the almost Mathieu operator, named for its similarity to the Mathieu operator[1] introduced by Émile Léonard Mathieu,[2] arises in the study of the quantum Hall effect. It is given by

acting as a self-adjoint operator on the Hilbert space . Here are parameters. In pure mathematics, its importance comes from the fact of being one of the best-understood examples of an ergodic Schrödinger operator. For example, three problems (now all solved) of Barry Simon's fifteen problems about Schrödinger operators "for the twenty-first century" featured the almost Mathieu operator.[3] In physics, the almost Mathieu operators can be used to study metal to insulator transitions like in the Aubry–André model.

For , the almost Mathieu operator is sometimes called Harper's equation.

The 'Ten Martini Problem'

edit

The structure of this operator's spectrum was first conjectured by Mark Kac, who offered ten martinis for the first proof of the following conjecture:

For all  , all irrational  , and all integers  , with  , there is a gap for the almost Mathieu operator on which  , where   is the integrated density of states.

This problem was named the 'Dry Ten Martini Problem' by Barry Simon as it was 'stronger' than the weaker problem which became known as the 'Ten Martini Problem':[1]

For all  , all irrational  , and all  , the spectrum of the almost Mathieu operator is a Cantor set.

The spectral type

edit

If   is a rational number, then   is a periodic operator and by Floquet theory its spectrum is purely absolutely continuous.

Now to the case when   is irrational. Since the transformation   is minimal, it follows that the spectrum of   does not depend on  . On the other hand, by ergodicity, the supports of absolutely continuous, singular continuous, and pure point parts of the spectrum are almost surely independent of  . It is now known, that

  • For  ,   has surely purely absolutely continuous spectrum.[4] (This was one of Simon's problems.)
  • For  ,   has surely purely singular continuous spectrum for any irrational  .[5]
  • For  ,   has almost surely pure point spectrum and exhibits Anderson localization.[6] (It is known that almost surely can not be replaced by surely.)[7][8]

That the spectral measures are singular when   follows (through the work of Yoram Last and Simon) [9] from the lower bound on the Lyapunov exponent   given by

 

This lower bound was proved independently by Joseph Avron, Simon and Michael Herman, after an earlier almost rigorous argument of Serge Aubry and Gilles André. In fact, when   belongs to the spectrum, the inequality becomes an equality (the Aubry–André formula), proved by Jean Bourgain and Svetlana Jitomirskaya.[10]

The structure of the spectrum

edit
 
Hofstadter's butterfly

Another striking characteristic of the almost Mathieu operator is that its spectrum is a Cantor set for all irrational   and  . This was shown by Avila and Jitomirskaya solving the by-then famous 'Ten Martini Problem' [11] (also one of Simon's problems) after several earlier results (including generically[12] and almost surely[13] with respect to the parameters).

Furthermore, the Lebesgue measure of the spectrum of the almost Mathieu operator is known to be

 

for all  . For   this means that the spectrum has zero measure (this was first proposed by Douglas Hofstadter and later became one of Simon's problems).[14] For  , the formula was discovered numerically by Aubry and André and proved by Jitomirskaya and Krasovsky. Earlier Last [15][16] had proven this formula for most values of the parameters.

The study of the spectrum for   leads to the Hofstadter's butterfly, where the spectrum is shown as a set.

References

edit
  1. ^ a b Simon, Barry (1982). "Almost periodic Schrodinger operators: a review". Advances in Applied Mathematics. 3 (4): 463–490.
  2. ^ "Mathieu equation". Encyclopedia of Mathematics. Springer. Retrieved February 9, 2024.
  3. ^ Simon, Barry (2000). "Schrödinger operators in the twenty-first century". Mathematical Physics 2000. London: Imp. Coll. Press. pp. 283–288. ISBN 978-1860942303.
  4. ^ Avila, A. (2008). "The absolutely continuous spectrum of the almost Mathieu operator". arXiv:0810.2965 [math.DS].
  5. ^ Jitomirskaya, S. (2021). "On point spectrum of critical almost Mathieu operators" (PDF). Advances in Mathematics. 392: 6. doi:10.1016/j.aim.2021.107997.
  6. ^ Jitomirskaya, Svetlana Ya. (1999). "Metal-insulator transition for the almost Mathieu operator". Ann. of Math. 150 (3): 1159–1175. arXiv:math/9911265. Bibcode:1999math.....11265J. doi:10.2307/121066. JSTOR 121066. S2CID 10641385.
  7. ^ Avron, J.; Simon, B. (1982). "Singular continuous spectrum for a class of almost periodic Jacobi matrices". Bull. Amer. Math. Soc. 6 (1): 81–85. doi:10.1090/s0273-0979-1982-14971-0. Zbl 0491.47014.
  8. ^ Jitomirskaya, S.; Simon, B. (1994). "Operators with singular continuous spectrum, III. Almost periodic Schrödinger operators" (PDF). Comm. Math. Phys. 165 (1): 201–205. Bibcode:1994CMaPh.165..201J. CiteSeerX 10.1.1.31.4995. doi:10.1007/bf02099743. S2CID 16267690. Zbl 0830.34074.
  9. ^ Last, Y.; Simon, B. (1999). "Eigenfunctions, transfer matrices, and absolutely continuous spectrum of one-dimensional Schrödinger operators". Invent. Math. 135 (2): 329–367. arXiv:math-ph/9907023. Bibcode:1999InMat.135..329L. doi:10.1007/s002220050288. S2CID 9429122.
  10. ^ Bourgain, J.; Jitomirskaya, S. (2002). "Continuity of the Lyapunov exponent for quasiperiodic operators with analytic potential". Journal of Statistical Physics. 108 (5–6): 1203–1218. doi:10.1023/A:1019751801035. S2CID 14062549.
  11. ^ Avila, A.; Jitomirskaya, S. (2005). "Solving the Ten Martini Problem". The Ten Martini problem. Lecture Notes in Physics. Vol. 690. pp. 5–16. arXiv:math/0503363. Bibcode:2006LNP...690....5A. doi:10.1007/3-540-34273-7_2. ISBN 978-3-540-31026-6. S2CID 55259301.
  12. ^ Bellissard, J.; Simon, B. (1982). "Cantor spectrum for the almost Mathieu equation". J. Funct. Anal. 48 (3): 408–419. doi:10.1016/0022-1236(82)90094-5.
  13. ^ Puig, Joaquim (2004). "Cantor spectrum for the almost Mathieu operator". Comm. Math. Phys. 244 (2): 297–309. arXiv:math-ph/0309004. Bibcode:2004CMaPh.244..297P. doi:10.1007/s00220-003-0977-3. S2CID 120589515.
  14. ^ Avila, A.; Krikorian, R. (2006). "Reducibility or non-uniform hyperbolicity for quasiperiodic Schrödinger cocycles". Annals of Mathematics. 164 (3): 911–940. arXiv:math/0306382. doi:10.4007/annals.2006.164.911. S2CID 14625584.
  15. ^ Last, Y. (1993). "A relation between a.c. spectrum of ergodic Jacobi matrices and the spectra of periodic approximants". Comm. Math. Phys. 151 (1): 183–192. Bibcode:1993CMaPh.151..183L. doi:10.1007/BF02096752. S2CID 189834787.
  16. ^ Last, Y. (1994). "Zero measure spectrum for the almost Mathieu operator". Comm. Math. Phys. 164 (2): 421–432. doi:10.1007/BF02101708.