In mathematics, the connective constant is a numerical quantity associated with self-avoiding walks on a lattice. It is studied in connection with the notion of universality in two-dimensional statistical physics models.[1] While the connective constant depends on the choice of lattice so itself is not universal (similarly to other lattice-dependent quantities such as the critical probability threshold for percolation), it is nonetheless an important quantity that appears in conjectures for universal laws. Furthermore, the mathematical techniques used to understand the connective constant, for example in the recent rigorous proof by Duminil-Copin and Smirnov that the connective constant of the hexagonal lattice has the precise value , may provide clues[2] to a possible approach for attacking other important open problems in the study of self-avoiding walks, notably the conjecture that self-avoiding walks converge in the scaling limit to the Schramm–Loewner evolution.

Definition

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The connective constant is defined as follows. Let   denote the number of n-step self-avoiding walks starting from a fixed origin point in the lattice. Since every n + m step self avoiding walk can be decomposed into an n-step self-avoiding walk and an m-step self-avoiding walk, it follows that  . Then by applying Fekete's lemma to the logarithm of the above relation, the limit   can be shown to exist. This number   is called the connective constant, and clearly depends on the particular lattice chosen for the walk since   does. The value of   is precisely known only for two lattices, see below. For other lattices,   has only been approximated numerically. It is conjectured that   as n goes to infinity, where   and  , the critical amplitude, depend on the lattice, and the exponent  , which is believed to be universal and dependent on the dimension of the lattice, is conjectured to be  .[3]

Known values

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Lattice Connective constant
Hexagonal  
Triangular  
Square  
Kagomé  
Manhattan  
L-lattice  
  lattice  
  lattice  

These values are taken from the 1998 Jensen–Guttmann paper [4] and a more recent paper by Jacobsen, Scullard and Guttmann.[5] The connective constant of the   lattice, since each step on the hexagonal lattice corresponds to either two or three steps in it, can be expressed exactly as the largest real root of the polynomial

 

given the exact expression for the hexagonal lattice connective constant. More information about these lattices can be found in the percolation threshold article.

Duminil-Copin–Smirnov proof

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In 2010, Hugo Duminil-Copin and Stanislav Smirnov published the first rigorous proof of the fact that   for the hexagonal lattice.[2] This had been conjectured by Nienhuis in 1982 as part of a larger study of O(n) models using renormalization techniques.[6] The rigorous proof of this fact came from a program of applying tools from complex analysis to discrete probabilistic models that has also produced impressive results about the Ising model among others.[7] The argument relies on the existence of a parafermionic observable that satisfies half of the discrete Cauchy–Riemann equations for the hexagonal lattice. We modify slightly the definition of a self-avoiding walk by having it start and end on mid-edges between vertices. Let H be the set of all mid-edges of the hexagonal lattice. For a self-avoiding walk   between two mid-edges   and  , we define   to be the number of vertices visited and its winding   as the total rotation of the direction in radians when   is traversed from   to  . The aim of the proof is to show that the partition function

 

converges for   and diverges for   where the critical parameter is given by  . This immediately implies that  .

Given a domain   in the hexagonal lattice, a starting mid-edge  , and two parameters   and  , we define the parafermionic observable

 

If   and  , then for any vertex   in  , we have

 

where   are the mid-edges emanating from  . This lemma establishes that the parafermionic observable is divergence-free. It has not been shown to be curl-free, but this would solve several open problems (see conjectures). The proof of this lemma is a clever computation that relies heavily on the geometry of the hexagonal lattice.

Next, we focus on a finite trapezoidal domain   with 2L cells forming the left hand side, T cells across, and upper and lower sides at an angle of  . (Picture needed.) We embed the hexagonal lattice in the complex plane so that the edge lengths are 1 and the mid-edge in the center of the left hand side is positioned at −1/2. Then the vertices in   are given by

 

We now define partition functions for self-avoiding walks starting at   and ending on different parts of the boundary. Let   denote the left hand boundary,   the right hand boundary,   the upper boundary, and   the lower boundary. Let

 

By summing the identity

 

over all vertices in   and noting that the winding is fixed depending on which part of the boundary the path terminates at, we can arrive at the relation

 

after another clever computation. Letting  , we get a strip domain   and partition functions

 

It was later shown that  , but we do not need this for the proof.[8] We are left with the relation

 .

From here, we can derive the inequality

 

And arrive by induction at a strictly positive lower bound for  . Since  , we have established that  .

For the reverse inequality, for an arbitrary self avoiding walk on the honeycomb lattice, we perform a canonical decomposition due to Hammersley and Welsh of the walk into bridges of widths   and  . Note that we can bound

 

which implies  . Finally, it is possible to bound the partition function by the bridge partition functions

 

And so, we have that   as desired.

Conjectures

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Nienhuis argued in favor of Flory's prediction that the mean squared displacement of the self-avoiding random walk   satisfies the scaling relation  , with  .[2] The scaling exponent   and the universal constant   could be computed if the self-avoiding walk possesses a conformally invariant scaling limit, conjectured to be a Schramm–Loewner evolution with  .[9]

See also

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References

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  1. ^ Madras, N.; Slade, G. (1996). The Self-Avoiding Walk. Birkhäuser. ISBN 978-0-8176-3891-7.
  2. ^ a b c Duminil-Copin, Hugo; Smirnov, Stanislav (2010). "The connective constant of the honeycomb lattice equals  ". arXiv:1007.0575 [math-ph].
  3. ^ Vöge, Markus; Guttmann, Anthony J. (2003). "On the number of hexagonal polyominoes". Theoretical Computer Science. 307 (2): 433–453. doi:10.1016/S0304-3975(03)00229-9.
  4. ^ Jensen, I.; Guttmann, A. J. (1998). "Self-avoiding walks, neighbor-avoiding walks and trails on semi-regular lattices" (PDF). Journal of Physics A. 31 (40): 8137–45. Bibcode:1998JPhA...31.8137J. doi:10.1088/0305-4470/31/40/008.
  5. ^ Jesper Lykke Jacobsen, Christian R Scullard and Anthony J Guttmann, 2016 J. Phys. A: Math. Theor. 49 494004
  6. ^ Nienhuis, Bernard (1982). "Exact critical point and critical exponents of O(n) models in two dimensions". Physical Review Letters. 49 (15): 1062–1065. Bibcode:1982PhRvL..49.1062N. doi:10.1103/PhysRevLett.49.1062.
  7. ^ Smirnov, Stanislav (2010). "Discrete Complex Analysis and Probability". Proceedings of the International Congress of Mathematicians (Hyderabad, India) 2010. pp. 565–621. arXiv:1009.6077. Bibcode:2010arXiv1009.6077S.
  8. ^ Smirnov, Stanislav (2014). "The critical fugacity for surface adsorption of SAW on the honeycomb lattice is  ". Communications in Mathematical Physics. 326 (3): 727–754. arXiv:1109.0358. Bibcode:2014CMaPh.326..727B. doi:10.1007/s00220-014-1896-1. S2CID 54799238.
  9. ^ Lawler, Gregory F.; Schramm, Oded; Werner, Wendelin (2004). "On the scaling limit of planar self-avoiding walk". In Lapidus, Michel L.; van Frankenhuijsen, Machiel (eds.). Fractal Geometry and Applications: A Jubilee of Benoît Mandelbrot, Part 2: Multifractals, Probability and Statistical Mechanics, Applications. Proceedings of Symposia in Pure Mathematics. Vol. 72. pp. 339–364. arXiv:math/0204277. Bibcode:2002math......4277L. doi:10.1090/pspum/072.2/2112127. ISBN 9780821836385. MR 2112127. S2CID 16710180.
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INTERN 1
Note 4