Boundedness of Dehn surgery slopes admitting hyperbolic PSL(2,mathbb{R})-representations for two-bridge knots
Pith reviewed 2026-06-28 20:24 UTC · model grok-4.3
The pith
For each fixed nontrivial two-bridge knot, the set of Dehn surgery slopes admitting non-abelian PSL(2,R) representations with hyperbolic meridian image is bounded.
A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.
Core claim
For each fixed nontrivial two-bridge knot, the set of surgery slopes admitting non-abelian PSL(2,R)-representations with hyperbolic meridian image is bounded. Equivalently, Dehn fillings along slopes with sufficiently large absolute value admit no non-abelian PSL(2,R) representations with hyperbolic meridian image. The proof obtains uniform endpoint estimates for the quotient of meridian and longitude translation parameters on each admissible real algebraic branch of the Riley polynomial.
What carries the argument
The Riley polynomial combined with Khoi's surgery-slope formula, supplying uniform endpoint estimates on the quotient of meridian and longitude translation parameters along each real algebraic branch.
If this is right
- Dehn fillings with sufficiently large absolute value on any fixed nontrivial two-bridge knot admit no non-abelian PSL(2,R) representations with hyperbolic meridian image.
- The bound on admissible slopes is effective in principle.
- The parameter sets and endpoint behavior on the algebraic branches can be illustrated explicitly for concrete knots.
Where Pith is reading between the lines
- The same boundedness question can be posed for knots outside the two-bridge class using analogous algebraic tools.
- The absence of such representations for large slopes may constrain the possible real projective structures on the filled manifolds.
Load-bearing premise
On each admissible real algebraic branch of the Riley polynomial, the meridian and longitude translation parameters admit uniform endpoint estimates for their quotient via Khoi's surgery-slope formula.
What would settle it
An explicit two-bridge knot together with a sequence of surgery slopes whose absolute values are unbounded, each of which admits a non-abelian PSL(2,R) representation with hyperbolic meridian image.
read the original abstract
We study Dehn fillings on two-bridge knots via non-abelian representations into $\mathrm{PSL}(2,\mathbb{R})$ whose meridian image is hyperbolic. For each fixed nontrivial two-bridge knot, we prove that the set of surgery slopes admitting such representations is bounded. Equivalently, Dehn fillings along slopes with sufficiently large absolute value admit no non-abelian $\mathrm{PSL}(2,\mathbb{R})$ representations with hyperbolic meridian image. The proof combines the Riley polynomial with Khoi's surgery-slope formula. On each admissible real algebraic branch, we express the meridian and longitude translation parameters as functions of the branch parameter and derive uniform endpoint estimates for their quotient. The resulting bound is effective in principle but not optimized. We also provide examples illustrating the parameter sets and endpoint behavior.
Editorial analysis
A structured set of objections, weighed in public.
Referee Report
Summary. The paper proves that for each fixed nontrivial two-bridge knot, the set of Dehn surgery slopes admitting non-abelian PSL(2,R)-representations with hyperbolic meridian image is bounded. Equivalently, sufficiently large |p/q| yield no such representations. The argument parametrizes the representations via real branches of the Riley polynomial, applies Khoi's formula expressing the slope as a quotient of meridian and longitude translation lengths, and obtains uniform endpoint estimates for this quotient on each admissible branch.
Significance. If the endpoint estimates are valid, the result supplies a new boundedness theorem for PSL(2,R) representations of two-bridge knot complements, with an effective (though unoptimized) bound. The reduction to a finite check per knot, together with the explicit algebraic approach and illustrative examples, constitutes a concrete contribution to the study of real character varieties and Dehn fillings.
major comments (1)
- [Abstract (and the corresponding proof section)] The load-bearing step is the derivation of uniform endpoint estimates for the meridian/longitude translation quotient on each real algebraic branch of the Riley polynomial (via Khoi's formula). Because the Riley polynomial is fixed for any given knot, the branches are finite; the manuscript must therefore supply an explicit, checkable argument that the quotient remains bounded at every endpoint of every admissible branch, including a clear classification of which branches are admissible.
minor comments (1)
- The abstract states that the resulting bound is 'effective in principle but not optimized'; a brief discussion of how the bound could be computed for a concrete knot (e.g., the figure-eight knot) would improve readability.
Simulated Author's Rebuttal
We thank the referee for the positive evaluation of our contribution and for identifying the need for greater explicitness in the load-bearing argument. We address the major comment below.
read point-by-point responses
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Referee: [Abstract (and the corresponding proof section)] The load-bearing step is the derivation of uniform endpoint estimates for the meridian/longitude translation quotient on each real algebraic branch of the Riley polynomial (via Khoi's formula). Because the Riley polynomial is fixed for any given knot, the branches are finite; the manuscript must therefore supply an explicit, checkable argument that the quotient remains bounded at every endpoint of every admissible branch, including a clear classification of which branches are admissible.
Authors: We agree that the current presentation would benefit from a more explicit and checkable treatment of the endpoint estimates. In the revised manuscript we will insert a new subsection that (i) gives a precise definition and classification of admissible branches (those real branches of the Riley polynomial yielding non-abelian PSL(2,R) representations with hyperbolic meridian), (ii) records the explicit algebraic expressions for the meridian and longitude translation lengths on each such branch, and (iii) supplies a uniform, branch-by-branch verification that the quotient remains bounded at every finite endpoint. Because the Riley polynomial is fixed for each knot, this classification and verification are finite and can be carried out symbolically or numerically for any concrete example. revision: yes
Circularity Check
No significant circularity; derivation self-contained
full rationale
The paper establishes the boundedness claim by combining the Riley polynomial (a fixed algebraic object for each given two-bridge knot) with Khoi's surgery-slope formula. On each real branch it expresses the meridian/longitude translation parameters explicitly as functions of the branch parameter and derives uniform endpoint estimates for their quotient. This is a finite, direct analytic task per knot with no parameter fitting, no self-citation load-bearing the central step, and no reduction of the target bound to a quantity defined by the same data. The argument therefore remains independent of its inputs.
Axiom & Free-Parameter Ledger
axioms (2)
- domain assumption The Riley polynomial encodes the non-abelian PSL(2,R) representations of the knot group.
- domain assumption Khoi's surgery-slope formula expresses the slope as a quotient of meridian and longitude translation lengths.
Reference graph
Works this paper leans on
-
[1]
J. Bochnak, M. Coste, and M.-F. Roy,Real Algebraic Geometry, Ergeb. Math. Grenzgeb. (3), vol. 36, Springer- Verlag, Berlin, 1998. DOI:10.1007/978-3-662-03718-8
-
[2]
S. Boyer, D. Rolfsen, and B. Wiest, Orderable 3-manifold groups, Ann. Inst. Fourier (Grenoble)55(2005), no. 1, 243–288. DOI:10.5802/aif.2098
-
[3]
R. Brooks and W. Goldman, Volumes in Seifert space, Duke Math. J.51(1984), no. 3, 529–545. DOI:10.1215/S0012-7094-84-05126-3
-
[4]
M. Culler and P. B. Shalen, Varieties of group representations and splittings of 3-manifolds, Ann. of Math. (2) 117(1983), no. 1, 109–146. DOI:10.2307/2006973
-
[5]
P. Derbez, Y. Liu, and S. Wang, Chern–Simons theory, surface separability, and volumes of 3-manifolds, J. Topol. 8(2015), no. 4, 933–974. DOI:10.1112/jtopol/jtv023
-
[6]
Gao, Slope of orderable Dehn filling of two-bridge knots, J
X. Gao, Slope of orderable Dehn filling of two-bridge knots, J. Knot Theory Ramifications31(2022), no. 1, Paper No. 2250006, 24 pp. DOI:10.1142/S0218216522500067
-
[7]
R. Hakamata and M. Teragaito, Left-orderable fundamental groups and Dehn surgery on genus one 2-bridge knots, Algebr. Geom. Topol.14(2014), no. 4, 2125–2148. DOI:10.2140/agt.2014.14.2125
-
[8]
V. T. Khoi, A cut-and-paste method for computing the Seifert volumes, Math. Ann.326(2003), no. 4, 759–801. DOI:10.1007/s00208-003-0438-5
-
[9]
V. T. Khoi, M. Teragaito, and A. T. Tran, Left orderable surgeries of double twist knots II, Canad. Math. Bull. 64(2021), no. 3, 624–637. DOI:10.4153/S0008439520000703
-
[10]
Riley, Parabolic representations of knot groups, I, Proc
R. Riley, Parabolic representations of knot groups, I, Proc. London Math. Soc. (3)24(1972), no. 2, 217–242. DOI:10.1112/plms/s3-24.2.217. 14 SHUNJIANG JIANG AND RAN TAO
-
[11]
Riley, Nonabelian representations of 2-bridge knot groups, Quart
R. Riley, Nonabelian representations of 2-bridge knot groups, Quart. J. Math. Oxford Ser. (2)35(1984), no. 138, 191–208. DOI:10.1093/qmath/35.2.191
-
[12]
Teragaito, Left-orderability and exceptional Dehn surgery on twist knots, Canad
M. Teragaito, Left-orderability and exceptional Dehn surgery on twist knots, Canad. Math. Bull.56(2013), no. 4, 850–859. DOI:10.4153/CMB-2012-011-0
-
[13]
O. Thakar, Left-orderable surgeries on the knot 6 2 via hyperbolic gPSL(2,R)-representations, arXiv:2307.00107, 2023
-
[14]
A. T. Tran, Left orderable surgeries of double twist knots, J. Math. Soc. Japan73(2021), no. 3, 753–765. DOI:10.2969/jmsj/84058405. Neijiang Vocational & Technical College, Neijiang, Sichuan Province, China Email address:shunjiangnitu@foxmail.com School of Mathematical Sciences and V.C. & V.R. Key Lab, Sichuan Normal University, Chengdu, Sichuan Province,...
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