3·1. The hyperelliptic strata

Note that $\lambda$ is trivial on the hyperelliptic locus (see [ Reference Cornalba and HarrisCH ]), which implies that the hyperelliptic strata have trivial tautological rings and are affine varieties.

3·2. $\mathcal P_3^1(4)^{\operatorname{odd}}$ and $\mathcal P_3^1(3,1)$

The divisor H parameterising hyperelliptic curves in $\mathcal M_3$ is disjoint from these strata and has divisor class $9\lambda$ (see [ Reference Chen and MöllerCM1 , section 2·5, equation (1)]).

3·3. $\mathcal P_3^1(2,2)^{\operatorname{odd}}$

For $(X, p_1, p_2)\in \mathcal P_3^1(2,2)^{\operatorname{odd}}$ , by definition $p_1 + p_2$ is an odd theta characteristic, which maps $\mathcal P_3^1(2,2)^{\operatorname{odd}}$ to the odd spin moduli space $\mathcal S_3^-$ . The divisor $Z_3$ in $\mathcal S_3^-$ parameterises odd theta characteristics with a double zero. It is disjoint from $\mathcal P_3^1(2,2)^{\operatorname{odd}}$ and has divisor class $11\lambda$ (see [ Reference Chen and MöllerCM1 , section 5·3]).

3·4. $\mathcal P_3^1(2,1,1)$

Marking the first two zeros maps $\mathcal P_3^1(2,1,1)$ to $\mathcal M_{3,2}$ . The Brill–Noether divisor $BN_{3,(1,2)}^1$ in $\mathcal M_{3,2}$ parameterises curves that admit a $g^1_3$ given by $p_1 + 2p_2$ . It is disjoint from $\mathcal P_3^1(2,1,1)$ and has divisor class $-\lambda + \psi_1 + 3\psi_2$ (see [ Reference Chen and MöllerCM1 , section 2·5, equation (5)]).

3·5. $\mathcal P_4^1(6)^{\operatorname{even}}$

For $(X, p)\in \mathcal P_4^1(6)^{\operatorname{even}}$ , by definition 3p is an even theta characteristic. The theta-null divisor $\Theta_4$ in $\mathcal M_{4,1}$ parameterises curves that admit an odd theta characteristic whose support contains the marked point. It is disjoint from $\mathcal P_4^1(6)^{\operatorname{even}}$ and has divisor class $30\lambda + 60 \psi_1$ (see [ Reference Chen and MöllerCM1 , section 2·5, equation (3)]).

3·6. $\mathcal P_4^1(6)^{\operatorname{odd}}$ and $\mathcal P_4^1(5,1)$

Marking the zero of the largest order, these strata map to $\mathcal M_{4,1}$ . The Brill–Noether divisor $BN_{3,(2)}^1$ in $\mathcal M_{4,1}$ parameterises curves that admit a $g^1_3$ ramified at the marked point. It is disjoint from both strata and has divisor class $8\lambda + 4\psi_1$ (see [ Reference Chen and MöllerCM1 , section 2·5, equation (7)]).

3·7. $\mathcal P_4^1(3,3)^{\operatorname{nonhyp}}$

The divisor $\operatorname{Lin}_3^1$ in $\mathcal M_{3,2}$ parameterises curves that admit a $g^1_3$ with a fiber containing both marked points. It is disjoint from $\mathcal P_4^1(3,3)^{\operatorname{nonhyp}}$ and has divisor class $8\lambda - \psi_1 - \psi_2$ (see [ Reference Chen and MöllerCM1 , section 2·5, equation (8)]).

3·8. $\mathcal P_4^1(2,2,2)^{\operatorname{odd}}$

For $(X, p_1, p_2, p_3)\in \mathcal P_4^1(2,2,2)^{\operatorname{odd}}$ , by definition $p_1 + p_2 + p_3$ is an odd theta characteristic. The divisor $Z_4$ in the odd spin moduli space $\mathcal S_4^-$ parameterises odd theta characteristics with a double zero. It is disjoint from $\mathcal P_4^1(2,2,2)^{\operatorname{odd}}$ and has divisor class $12\lambda$ (see [ Reference Chen and MöllerCM1 , section 5·3]).

3·9. $\mathcal P_4^1(3,2,1)$

The Brill–Noether divisor $BN_{4,(1,1,2)}^1$ in $\mathcal M_{4,3}$ parameterises curves that admit a $g^1_4$ given by $p_1 + p_2 + 2p_3$ . It is disjoint from $\mathcal P_4^1(3,2,1)$ and has divisor class $-\lambda + \psi_1 + \psi_2 + 3\psi_3$ (see [ Reference Chen and MöllerCM1 , section 2·5, equation (6)]).

3·10. $\mathcal P_5^1(8)^{\operatorname{even}}$

The Brill–Noether divisor $BN_{3}^1$ in $\mathcal M_{5,1}$ parameterises curves with a $g^1_3$ . It is disjoint from $\mathcal P_5^1(8)^{\operatorname{even}}$ and has divisor class $8\lambda$ (see [ Reference Chen and MöllerCM1 , section 2·5, equation (4)]).

3·11. $\mathcal P_5^1(8)^{\operatorname{odd}}$

The divisor $\operatorname{Nfold}_{5,4}^1(1)$ in $\mathcal M_{5,1}$ parameterises curves that admit a $g^1_4$ with a fiber containing 3p. It is disjoint from $\mathcal P_5^1(8)^{\operatorname{odd}}$ and has divisor class $ 7\lambda + 15\psi_1$ (see [ Reference Chen and MöllerCM1 , section 2·5, equation (9)]).

3·12. $\mathcal P_5^1(5,3)$

The Brill–Noether divisor $BN_{4,(1,2)}^1$ in $\mathcal M_{5,2}$ parameterises curves that admit a $g^1_4$ with a fiber containing $p_1 + 2p_2$ . It is disjoint from $\mathcal P_5^1(5,3)$ and has divisor class $7\lambda + 7\psi_1 + 2\psi_2$ (see [ Reference Chen and MöllerCM1 , section 2·5, equation (10)]).

3·13. $\mathcal P_4^1(4,2)^{\operatorname{even}}$ , $\mathcal P_4^1(4,2)^{\operatorname{odd}}$ , and $\mathcal P_5^1(6,2)^{\operatorname{odd}}$

The nonvarying property of these strata was proved in [ Reference Yu and ZuoYZ ] by using the Harder–Narasimhan filtration of the Hodge bundle (see also [ Reference Chen and MöllerCM2 , appendix A]). Note that the filtration holds not only on a Teichmüller curve but also on (the interior of) each stratum. Let $L_\mu$ be the sum of (nonnegative) Lyapunov exponents which satisfies that $\lambda = L_\mu \eta$ from the Harder–Narasimhan filtration on these strata. In these cases we know that $L_\mu \neq \kappa_\mu / 12$ . Then the triviality of $\eta$ on these strata follows from the two distinct relations $\lambda = (\kappa_\mu/12) \eta$ and $\lambda = L_\mu \eta$ .

3·14. Nonvarying strata of quadratic differentials in genus one and two

Strata in genus $\leq 2$ can be generally dealt with as in Sections 4·2 and 4·3 below.

3·15. $\mathcal P^2_3(9,-1)^{\operatorname{irr}}$

This stratum is disjoint from the hyperelliptic divisor H in $\mathcal M_3$ whose divisor class is $9\lambda$ (see [ Reference Chen and MöllerCM2 , section 3·1, equation (6)]).

3·16. $\mathcal P^2_3(8)$ , $\mathcal P^2_3(7,1)$ , $\mathcal P^2_3(8,1,-1)$ , $\mathcal P^2_3(10, -1, -1)^{\operatorname{nonhyp}}$ and $\mathcal P^2_3(9,-1)^{\operatorname{reg}}$

Marking the zero of the largest order, these strata map to $\mathcal M_{3,1}$ . The divisor W of Weierstrass points in $\mathcal M_{3,1}$ is disjoint from these strata and has divisor class $ -\lambda + 6\psi_1$ (see [ Reference Chen and MöllerCM2 , section 3, equation (5)]).

3·17. $\mathcal P^2_3(6,2)^{\operatorname{nonhyp}}$ , $\mathcal P^2_3(6,1,1)^{\operatorname{nonhyp}}$ , $\mathcal P^2_3(5,3)$ , $\mathcal P^2_3(5,2,1)$ , $\mathcal P^2_3(4,4)$ , $\mathcal P^2_3(4,3,1)$ , $\mathcal P^2_3(5,4,-1)$ , $\mathcal P^2_3(5,3,1,-1)$ , $\mathcal P^2_3(7,2,-1)$ , $\mathcal P^2_3(7,3, -1, -1)$ and $\mathcal P^2_3(6,3,-1)^{\operatorname{reg}}$

Marking the first two zeros, these strata map to $\mathcal M_{3,2}$ . The Brill–Noether divisor $BN^1_{3,(2,1)}$ in $\mathcal M_{3,2}$ parameterises curves that admit a $g^1_3$ given by $2p_1 + p_2$ . It is disjoint from these strata and has divisor class $-\lambda + 3\psi_1 + \psi_2$ (see [ Reference Chen and MöllerCM2 , section 3·1, equation (8)]).

3·18. $\mathcal P^2_3(4,2,2)$ , $\mathcal P^2_3(3,3,2)^{\operatorname{nonhyp}}$ , $\mathcal P^2_3(4,3,2,-1)$ , $\mathcal P^2_3(3,2,2,1)$ , $\mathcal P^2_3(3,3,1,1)^{\operatorname{nonhyp}}$ and $\mathcal P^2_3(3,3,3,-1)^{\operatorname{reg}}$

Marking the first three zeros, these strata map to $\mathcal M_{3,3}$ . The Brill–Noether divisor $BN^1_{3,(1,1,1)}$ in $\mathcal M_{3,3}$ parameterises curves that admit a $g^1_3$ given by $p_1 + p_2 + p_3$ . It is disjoint from these strata and has divisor class $-\lambda + \psi_1 + \psi_2 + \psi_3$ (see [ Reference Chen and MöllerCM2 , section 3·1, equation (7)]).

3·19. $\mathcal P^2_4(13, -1)$ , $\mathcal P^2_4(11, 1)$ and $\mathcal P^2_4(12)^{\operatorname{reg}}$

Marking the zero of the largest order, these strata map to $\mathcal M_{4,1}$ . The divisor W of Weierstrass points in $\mathcal M_{4,1}$ is disjoint from these strata and has divisor class $-\lambda + 10\psi_1$ (see [ Reference Chen and MöllerCM2 , lemma 3·2]).

3·20. $\mathcal P^2_4(10, 2)^{\operatorname{nonhyp}}$ , $\mathcal P^2_4(8,4)$ , $\mathcal P^2_4(8,3,1)$ and $\mathcal P^2_4(9,3)^{\operatorname{reg}}$

Marking the first two zeros, these strata map to $\mathcal M_{4,2}$ . The Brill–Noether divisor $BN^1_{4,(3,1)}$ in $\mathcal M_{4,2}$ parameterises curves that admit a $g^1_4$ given by $3p_1 + p_2$ . It is disjoint from these strata and has divisor class $-\lambda + 6\psi_1 + \psi_2 $ (see [ Reference Chen and MöllerCM2 , lemma 3·2]).

3·21. $\mathcal P^2_4(7,5)$ and $\mathcal P^2_4(6,6)^{\operatorname{reg}}$

The Brill–Noether divisor $BN^1_{4,(2,2)}$ in $\mathcal M_{4,2}$ parameterises curves that admit a $g^1_4$ given by $2p_1 + 2p_2$ . It is disjoint from these strata and has divisor class $-\lambda + 3\psi_1 + 3\psi_2$ (see [ Reference Chen and MöllerCM2 , lemma 3·2]).

3·22. $\mathcal P^2_4(7,3,2)$ , $\mathcal P^2_4(5,4,3)$ and $\mathcal P^2_4(6,3,3)^{\operatorname{reg}}$

The Brill–Noether divisor $BN^1_{4,(2,1,1)}$ in $\mathcal M_{4,3}$ parameterises curves that admit a $g^1_4$ given by $2p_1 + p_2 + p_3$ . It is disjoint from these strata and has divisor class $-\lambda + 3\psi_1 + \psi_2 + \psi_3 $ (see [ Reference Chen and MöllerCM2 , lemma 3·2]).

3·23. $\mathcal P^2_4(3,3,3,3)^{\operatorname{reg}}$

It is disjoint from the Brill–Noether divisor $BN^1_{4,(1,1,1,1)}$ in $\mathcal M_{4,4}$ whose divisor class is $-\lambda + \psi_1 + \psi_2 + \psi_3 + \psi_4$ (see [ Reference Chen and MöllerCM2 , lemma 3·2]).

3·24. $\mathcal P^2_3(6,3,-1)^{\operatorname{irr}}$ , $\mathcal P^2_4(12)^{\operatorname{irr}}$ and $\mathcal P^2_4(9,3)^{\operatorname{irr}}$

We can use the Harder–Narasimhan filtration of the quadratic Hodge bundle for these strata (see [ Reference Chen and MöllerCM2 , appendix A] and [ Reference Chen and YuCY , section 4·2]) and argue as in Section 3·13.

To see this, let $\Delta_0$ be the locus of stable differentials of type $\mu$ on curves with separating nodes only, where the differentials have simple poles with opposite residues at the nodes. If $\mathcal P^1_g(\mu)$ is irreducible, then $\Delta_0$ is also irreducible and modeled on $\mathcal P^1_{g-1}(\mu, \{-1,-1\})$ . Moreover, every Teichmüller curve in $\mathcal P^1_g(\mu)$ only intersects $\Delta_0$ in the boundary (see [ Reference Chen and MöllerCM1 , corollary 3·2]).

Suppose that $\eta$ is trivial on $\mathcal P^1_g(\mu)$ . Then $\eta = e \delta_0$ on the partial compactification $\mathcal P^1_g(\mu)\cup \Delta_0$ for some constant e. Since $\lambda = (\kappa_\mu / 12)\eta$ on $\mathcal P^1_g(\mu)$ , we have $\lambda = \ell \delta_0$ on $\mathcal P^1_g(\mu)\cup \Delta_0$ for some constant $\ell$ . Then the sum of Lyapunov exponents of a Teichmüller curve C is given by $(\lambda \cdot C) / (\eta\cdot C) = \ell / e$ which is independent of C, contradicting that $\mathcal P^1_g(\mu)$ is a varying stratum.

Note that the above criterion is practically checkable for arithmetic Teichmüller curves generated by square-tiled surfaces by using the combinatorial description of area Siegel–Veech constants and sums of Lyapunov exponents (see [ Reference Eskin, Kontsevich and ZorichEKZ , section 2·5·1] and also [ Reference ChenC1 , theorem 1·8] for the relation with slopes of Teichmüller curves).

The same conclusion would hold for a varying stratum of quadratic differentials, assuming that all Teichmüller curves contained in the stratum intersect only one irreducible boundary divisor (see [ Reference Chen and MöllerCM2 , remark 4·7] for this assumption).

4·1. Strata in genus zero

Every stratum in genus zero is isomorphic to the corresponding moduli space of pointed smooth rational curves, which has a trivial Chow ring and is affine.

4·2. Strata in genus one

Since $\psi_i = 0$ on $\mathcal M_{1,n}$ for all i (see [ Reference Arbarello and CornalbaAC , theorem 2·2 (c)]), every stratum $\mathcal P^k_1(\mu)$ in genus one (including the case of some $m_i = -k$ in $\mu$ ) has a trivial tautological ring and is affine by Proposition 2·2. The affinity also follows from the fact that the ambient space $\mathcal M_{1,n}$ is affine (see [ Reference ChenC3 , theorem 3·1]).

4·3. Strata in genus two

Since $\lambda$ is trivial on $\mathcal M_2$ , every stratum $\mathcal P^k_2(\mu)$ in genus two with $m_i \neq -k$ for all i has a trivial tautological ring and is affine by Proposition 2·2.

4·4. Strata with poles of order $\leq - k$

Suppose $m_1 \leq -k$ . By the relations $\eta = (m_i + k)\psi_i$ for all i and $(2g-2)\eta = k \kappa - \sum_{i=1}^n m_i \psi_i$ , we obtain that

\begin{eqnarray*}k\Big(\kappa + \sum_{i=1}^n \psi_i\Big) & = & (2g-2+n) \eta \\[5pt] & = & (2g-2+n)(m_1+k) \psi_1.\end{eqnarray*}

It implies that $\kappa + \sum_{i=1}^n \psi_i + a \psi_1$ is trivial on $\mathcal P^k_g(\mu)$ where $a = - (2g-2+n)(m_1+k) / k \geq 0$ . Since $\kappa + \sum_{i=1}^n \psi_i + a \psi_1$ (as ample plus nef) remains ample on $\overline{\mathcal M}_{g,n}$ , it follows that $\mathcal P^k_g(\mu)$ is affine and Theorem 1·2 is justified.