Proof. Let $f: S \to X$ be the restriction of $\phi $ to a general fibre of q. The fact that $N_f$ is generically globally generated follows from basic deformation theory and the fact that X is swept out by images of surfaces from this family. Indeed, let $B_X=g^{-1}([X])$ and $\phi _X: \mathcal S_X\to X$ the restriction of $\phi $ to the fibre over $B_X$ . Then $\phi _X$ is dominant by our assumption. So by generic smoothness, for a general point $(b,s)$ of $\mathcal S_X$ , the induced map on Zariski tangent spaces $T_{\mathcal S_X,(b,s)} \to T_{X,x}=f^*T_X|_s$ is surjective. Therefore the map $T_{\mathcal S_X,(b,s)} \to N_{f}|_s$ is surjective as well. There is a map from $T_{\mathcal S_X,(b,s)}$ to $H^0(N_f)$ (see, for example, [Reference SernesiSe, Theorem 3.4.8]), and the map $T_{\mathcal S_X,(b,s)}\to N_{f}|_s$ factors through the map $T_{\mathcal S_X,(b,s)} \to H^0(N_f)$ , so the desired result follows.

For the second claim, we only use the assumption that for a general hypersurface X, there exists a generically finite morphism from a fibre of q to X.

We can take an étale base change $U \to H^0(\mathcal {O}_{\mathbb {P}^n}(d))$ to obtain a family $\mathcal {X}_U \to U$ of hypersurfaces with a family $\mathcal {Y} \to U$ of rational surfaces parametrised by q mapping to fibres of $\mathcal {X}_U \to U$ via a map $\psi : \mathcal {Y} \to \mathcal {X}_U$ such that $\mathcal {Y}$ admits a natural $\operatorname {PGL}_{n+1}$ action. Denote by $\pi $ the projection map from $\mathcal X_U$ to $\mathbb {P}^n$ , and let $\pi ' = \pi \circ \psi $ . The induced map on tangent bundles $T_{\mathcal {Y}} \to \pi ^{\prime *}T_{\mathbb {P}^n}$ is surjective because of the $\operatorname {PGL}_{n+1}$ invariance of $\mathcal {Y}$ . We have the following commutative diagram:

If u is a general point of U and $f: \mathcal Y_u \to \mathcal X_u$ is the restriction of $\psi $ to the fibre over u, then $N_{\psi ,\mathcal X_U}|_{\mathcal Y_u} = N_{f, \mathcal X_u}$ , so to show $N_{f, \mathcal X_u}(H)$ is globally generated, it is enough to show $T_{\mathcal {X}_U/ \mathbb {P}^n} \otimes \pi ^*\mathcal {O}_{\mathbb {P}^n}(1)$ is globally generated. Consider the following diagram:

Using the eight lemma and looking at the first column, it follows that $T_{\mathcal {X}_U/\mathbb {P}^n}$ is the kernel of the map $\mathcal {O} \otimes S_d \to \pi ^*\mathcal {O}(d)$ . Such bundles are called Lazarsfeld-Mukai bundles, so we may say $T_{\mathcal {X}_U/\mathbb {P}^n} \cong M_d$ , the pullback of the Lazarsfeld-Mukai bundle of $\mathcal {O}_{\mathbb {P}^n}(d)$ .

We can similarly define $M_1$ to be the kernel of the natural map $\mathcal {O} \otimes S_1 \to \pi ^*\mathcal {O}(1)$ . The bundle $M_d$ admits a surjection from a direct sum of copies of $M_1$ , with maps given by multiplication by a general degree $d-1$ polynomial. It follows that $N_{h,\mathcal {X}_U}$ admits a surjection from a direct sum of copies of $M_1$ . Taking the second wedge power of the sequence

$$\begin{align*}0 \to M_1 \to \mathcal{O} \otimes S_1 \to \mathcal{O}(1) \to 0, \end{align*}$$

we see that $M_1(1)$ is globally generated, and hence $M_d(1)$ is too, so the global generation result follows.

Proof. Since E is generically globally generated, choosing m general sections of E, we get an injective map $\mathcal {O}_S^m \to E$ . The cokernel of this map, denoted by T, is a torsion sheaf. Since $E(A)$ is globally generated, there is a surjective map $\mathcal {O}_S^l \to E(A)$ for some l. This in turn gives a surjective map $\mathcal {O}_S^l \to T(A)$ whose kernel we denote by M.

We claim $H^1( T(A+D)) = 0$ . By our assumption, $H^1(\mathcal {O}_S(D)) =0$ , so applying the long exact sequence of cohomology to the first sequence twisted with $\mathcal {O}_S(D)$ , the claim follows if we show $H^2(M(D))) = 0$ . Applying the Leray spectral sequence corresponding to the map p, it is enough to show that $H^1(M(D)|_C)=0$ , where C is a general fibre of $\pi $ . Since C is a general fibre, the first short exact sequence above remains exacts after restricting to C, so $M|_C$ is torsion free. If $M|_C = \mathcal {O}(a_1) \oplus \dots \oplus \mathcal {O}(a_l)$ , then since $M|_C$ injects into $\mathcal {O}_C^{ l}$ , we have $a_i \leq 0$ for each i. Also,

$$ \begin{align*}\sum_{i=1}^l a_i = - \deg (T(A))|_C = -\deg T|_C = -\deg E|_C\end{align*} $$

since $T|_C$ is torsion. If $a_i < -1-D \cdot C$ for some i, then

$$ \begin{align*}0 \geq \sum_{j \neq i} a_j = - \deg E|_C - a_i> -\deg E|_C+D\cdot C +1,\end{align*} $$

contradicting assumption (b). So $a_i \geq -1 - D \cdot C$ for every i and therefore $H^1(M(D)|_C) =0$ .

This shows that $H^1(T(A+D))=0$ , so $\chi (T(A+D)) \geq 0$ , and the desired result follows from the short exact sequence

$$ \begin{align*}0 \to \mathcal{O}_S(A+D)^m \to E(A+D) \to T(A+D) \to 0.\\[-38pt] \end{align*} $$

Proof. By Proposition 2.1, for a general $f: S \to X$ , $N_f$ is generically globally generated and $N_f(H)$ is globally generated. We apply Proposition 2.2 to $E=N_f$ , $D=(n+1-d)H+K$ and $A=H$ . After possibly blowing up S at a point, we may assume there is a morphism $\pi : S \to \mathbb {P}^1$ whose general fibres are smooth rational curves. Condition (a) of Proposition 2.2 is satisfied by our assumption. Since $\deg N_f|_C = (n+1-d) H \cdot C - 2$ for a general fibre C of $\pi $ , condition (b) is satisfied. By the Kawamata-Viehweg vanishing theorem, condition (c) is also satisfied, so $\chi (N_f((n+2-d)H+K)) \geq (n-3) \; \chi (\mathcal {O}_S(n+2-d)H+K).$ Applying the Riemann-Roch theorem, we get the desired inequality.

Proof. This is a straightforward computation using the pullback of the Euler sequence on $\mathbb {P}^n$ and twisting it with $tH+K$ :

$$ \begin{align*}0 \to \mathcal{O}_S(tH+K) \to \mathcal{O}((t+1)H+K)^{n+1} \to f^*T_{\mathbb{P}^n}(tH+K) \to 0\end{align*} $$

and the short exact sequence

$$ \begin{align*}0 \to f^*T_X(tH+K) \to f^*T_{\mathbb{P}^n}(tH+K) \to \mathcal{O}((d+t)H+K) \to 0. \\[-38pt] \end{align*} $$

Proof. This follows from comparing Corollary 2.3 with Lemma 2.4 when $t=n+2-d$ .

Proof of Corollary 2.6.

Suppose to the contrary that a very general hypersurface X is covered by images of such morphisms. Blowing down S, we can further assume $f: S \to X$ does not contract any $(-1)$ -curve. Applying Theorem 2.5 to the hypotheses given, we conclude that there is a generically finite morphism $f: S \to X$ that does not contract any $(-1)$ -curve and satisfies the inequality of Theorem 2.5. Since H is nef, applying Reider’s theorem to $3H$ , we see that $3H+K$ is base-point free. Therefore $(3H+K)^2\geq 0$ , so $-2K^2 \leq 18H^2+12H \cdot K$ . Since $d \geq \lambda b$ and $\lambda> 2-\sqrt {2}$ , the coefficient of $H^2$ in 2.1 becomes arbitrarily negative compared to the coefficient of $H \cdot K$ , so we get a contradiction.

Proof. Suppose to the contrary that X is covered by images of generically finite morphisms from del Pezzo surfaces. Then by Theorem 2.5, there exist a del Pezzo surface S and a generically finite morphism $f: S \to X$ for which inequality (2.1) holds. We show that this is not possible. Let B be the coefficient of $H^2$ in inequality (2.1). We first show $B < -5n-4$ . To see this, note that since $d> (2-\sqrt {2})n+3$ , $n-d < (\sqrt {2}-1)n-3$ , so

$$ \begin{align*}B < 2((\sqrt{2}-1)n-2)((\sqrt{2}-1)n-1)+n+1-((2-\sqrt{2})n+3)^2 \leq -5n-4.\end{align*} $$

Since S is a del Pezzo surface, $-K$ is effective, so $H \cdot K < 0$ and $K^2> 0$ . So the left-hand side of inequality (2.1) is at most $-5n-4-(3n-3d+5)-2+24$ , which is negative since $d \leq n$ and $n \geq 3$ . This gives a contradiction.

Proof. Suppose to the contrary that a very general hypersurface X of degree d is covered by the images of generically finite morphisms from blowups of $\mathbb {P}^2$ in general points. Then by Theorem 2.5, there is a rational surface S obtained by blowing up $\mathbb {P}^2$ in general points and a generically finite morphism $f: S \to X$ such that inequality (2.1) is satisfied. We can assume f does not contract any $(-1)$ -curve, since otherwise we can consider the induced morphism from the blow-down of S to X instead. By the Harbourne-Hirschowitz conjecture, $H^1(S,\mathcal {O}_S(H))=0$ , so by the Riemann-Roch theorem, $H(H-K) =2\chi (H) -2\geq -2$ . Therefore $H \cdot K \leq H^2+2$ .

By [Reference Riedl and YangRY, Theorem 2.3], if $n < \frac {d^2+3d+6}{6}$ , then there is no rational curve on the space of lines in X. Our assumption on the degree implies this inequality is satisfied, so we can assume the image of S under f is not covered by a pencil of lines. In particular, the image of S has degree at least $2$ , so $H^2 \geq 2$ . Since the image of S is not covered by lines, and since H is big and nef, by Reider’s theorem [Reference ReiderRe], $2H+K$ is base-point free. Therefore $(2H+K)^2\geq 0$ , so $-2K^2 \leq 8H^2+8H \cdot K \leq 16H^2+16$ . So if we denote the left-hand side of inequality 2.1 by A, then we have

$$ \begin{align*} \begin{aligned} A & \leq (2(n+1-d)(n+2-d)+n+1-d^2+(3n-3d+5)+16) \; H^2 + 2(3n-3d+5) + 40. \\ \end{aligned} \end{align*} $$

Denote the coefficient of $H^2$ in the above inequality by B. We claim $B < -(3n-3d+5)-20$ . This is because by our assumption $n-d \leq (\sqrt {2}-1)n-4$ , so

$$ \begin{align*} \begin{aligned} B + (3n-3d+5)+20 &< 2((\sqrt{2}-1)n-3)((\sqrt{2}-1)n-2)+n+1-((2-\sqrt{2})n+4)^2 \\ & \;\;\;\;\; +6((\sqrt{2}-1)n-4) +46 \\ & = (4\sqrt{2}-11)n+19\\ & <0, \end{aligned} \end{align*} $$

where the last line follows from the assumption $n \geq 4$ . Since $H^2 \geq 2$ , we get $A <0$ , a contradiction.

Proof. Consider the map $\operatorname {Hom^0}(S,X) \times S \to X \times S$ . Then for any $(f,p) \in \operatorname {Hom}^0(S,X) \times S$ , we have the following diagram:

Let $(p,f)$ be a general point of an irreducible component of $\operatorname {Hom}^0(S,X) \times S$ that dominates $X \times S$ . Then if $\mathcal {U}_{red}$ is the largest reduced subscheme of $\operatorname {Hom}^0(S,X)$ , generic smoothness shows that $\alpha |_{T_{\mathcal {U}_{red},(p,f)}}$ is surjective, and hence $\pi _2 \circ \alpha $ is surjective. It follows that $\beta $ is surjective, and hence $f^*T_X$ is generically globally generated.

To prove $f^*T_X(H)$ is globally generated, we repeat the argument of Proposition 2.1 with $\mathcal {X}$ replaced by $\mathcal {X} \times S$ . We can find a dominant morphism $U \to H^0(\mathcal {O}_{\mathbb {P}^n}(d))$ and a morphism $\psi : U \times S \to \mathcal {X}_U \times S$ such that if $\pi ': U \times S \to \mathbb {P}^n$ is the natural morphism, then the induced map on tangent spaces $T_{U \times S} \to \pi ^{\prime *} T_{\mathbb {P}^n\times S}$ is surjective. The same argument as in Proposition 2.1 shows that $T_{\mathcal {X}_U \times S / \mathbb {P}^n \times S}(H)$ is globally generated, and therefore $N_{\psi , \mathcal {X}_U \times S}(H)$ is globally generated. If $f: S \to X$ is the restriction of $\psi $ to $\{u\}\times S$ for a general point u of U, then $N_{\psi , \mathcal {X}_U \times S}|_{u \times S} = N_{f, X \times S} = f^*T_X$ , and the desired result follows.

Proof. Assume to the contrary that X is strongly swept out by S. Then by Proposition 3.1, there is $f:S \to X$ such that $f^*T_X$ is generically globally generated and $f^*T_X(H)$ is globally generated. Passing to finite characteristic, we can assume there is a sufficiently large prime number p, a rational surface $S_p$ , a smooth hypersurface $X_p$ of degree d and a morphism $f_p:S_p\to X_p$ , all defined over an algebraically closed field of characteristic p such that $f_p^*T_{X_p}$ is generically globally generated and $f_p^*T_{X_p}(H)$ is globally generated.

For a coherent sheaf F on $S_p$ , let $F^{(p)}$ denote the pullback of F under the absolute Frobenius morphism of X (see [Reference HartshorneHa, Proposition 6.1]). Since $f_p^*T_{X_p}(H)$ is globally generated, $(f_p^*T_{X_p})^{(p)}(pH)$ is also globally generated. Since $f_p^*T_{X_p}$ is generically globally generated, $(f_p^*T_{X_p})^{(p)}$ will be as well. Let K denote the canonical divisor of $S_p$ . A similar computation as in Lemma 2.4 shows that

(3.1) $$ \begin{align} \chi(f_p^*T_{X_p}^{(p)}(tpH+K)) = \frac{1}{2}(p^2(n(t+1)^2+2t+1-(d+t)^2) H^2 + p(nt+n+1-d-t)HK) +(n-1). \end{align} $$

We can now apply Proposition 2.2 with $E=f_p^*T_{X_p}^{(p)}$ , $A =pH$ and $D=p(n+2-d)H+K$ to get a contradiction. Since $S_p$ is a rational surface, by [Reference MukaiMu, Theorem 3], $H^1(D+pH)=0$ , so condition (c) of Proposition 2.2 is satisfied. After possibly blowing up $S_p$ at a point, we can assume there is a morphism $S_p \to \mathbb {P}^1$ whose general fibres are smooth rational curves. If C denotes a general fibre of this morphism, then $\deg (f_p^*T_{X_p}^{(p)})|_C = p(n+1-d) H \cdot C \leq p(n+2-d)H\cdot C -2$ , so condition (b) is also satisfied. Therefore,

$$ \begin{align*} \begin{aligned} \chi(f_p^*T_{X_p}^{(p)}((n+3-d)pH+K)) & \geq (n-1) \chi (\mathcal{O}_{S_p}((n+3-d)pH+K))\\ & = \frac{1}{2}(p^2(n-1)(n+3-d)^2 H^2+p(n-1)(n+3-d)HK)+ (n-1). \end{aligned} \end{align*} $$

Comparing the coefficients of $H^2$ in this equation and Equation (3.1) when $t=n+3-d$ , and letting p increase, we see if the above inequality holds, then we must have

$$ \begin{align*}n(t+1)^2+2t+1-(d+t)^2 \geq (n-1)(n+3-d)^2.\end{align*} $$

Letting $t=n+3-d$ , this gives

$$ \begin{align*}n+(n+3-d)^2+2(n+3-d)(n+1)+1-(n+3)^2 \geq 0.\end{align*} $$

But since we assume $d> (2-\sqrt {2})n+2$ , we have $n-d < (\sqrt {2}-1)n-2$ , so the left-hand side of the above inequality is smaller than

$$ \begin{align*}n+((\sqrt{2}-1)n+1)^2+2((\sqrt{2}-1)n+1)(n+1)+1-(n+3)^2 = -5-(6-4\sqrt{2})n < 0,\end{align*} $$

a contradiction.

Proof. First observe that for $m> d+1$ , the space of lines in any degree d hypersurface in $\mathbb {P}^n$ will sweep out X, so case (3) of Theorem 3.3 cannot occur. We next show that case (2) cannot occur. Let $\mathcal {B}_1 \subset \mathcal {U}_{1,d}$ , and let $\mathcal {B}_n \subset \mathcal {U}_{n,d}$ be the tower of induced varieties. It suffices to show $\mathcal {B}_{d+1}$ is dense in $\mathcal {U}_{d+1,d}$ . If a general element of $\mathcal {B}_1$ has at least two distinct points, it follows from [Reference Coskun and RiedlCR] Proposition 4.10(1) that $\mathcal {B}_n$ is dense in $\mathcal {U}_{n,d}$ , which contradicts the hypothesis. Thus, it remains to consider the cases where $\mathcal {B}_1$ consists of d-fold points and show that the tower of induced varieties is dense in $\mathcal {U}_{m,d}$ . To see this, let $(p,V(F)) \in \mathcal {U}_{n,d}$ be a general point. Expand the equation of F around p to get $F = F_1+\cdots F_d$ , where $F_i$ is the ith order part of F near p. Then the space of lines in $\mathbb {P}^n$ meeting $V(F)$ to order d near p is $V(F_1,\dots ,F_{d-1})$ . This is nonempty for $d \leq n-1$ , so the result follows.

Proof. Let $\mathcal {B}_{n,d}$ be the locus in $\mathcal {U}_{n,d}$ swept out by surfaces in the given class, and let $\mathcal {B}_{r,d}$ be the tower of induced varieties from $\mathcal {B}_{n,d}$ . Then by assumption, we have that $\mathcal {B}_{n+c,d}$ has codimension at least $1$ in $\mathcal {U}_{n+c,d}$ . By Corollary 3.4, it follows that $\mathcal {B}_{n,d}$ has codimension at least $2c+1$ in $\mathcal {U}_{n,d}$ , and the first part of the result follows. Since generically finite morphisms from a surface to X must sweep out a subvariety of dimension at least 2, we see that X will admit no such morphisms if $2c+1 \geq n-1-1 = n-2$ . The second result follows.

Proof. This is a direct application of Theorem 3.5 to the results of Corollary 2.6, replacing $\lambda $ with $\frac {2\lambda }{3}$ .

Proof. Observe that the result is immediate for $d> n$ , so we may assume $d \leq n$ . Let $p \in S$ be a general point, and let $\mathcal {B}_{n,d}$ be the locus of images of p under a generically finite morphism $S \to X$ . Let $\mathcal {B}_{n+1,d}$ be part of the tower of induced varieties of $\mathcal {B}_{n,d}$ . Then by Proposition 3.2, $\mathcal {B}_{n+1,d}$ has codimension at least 1 in $\mathcal {U}_{n+1,d}$ . By Corollary 3.4, it follows that $\mathcal {B}_{n,d}$ has codimension at least 3 in $\mathcal {U}_{n,d}$ . Thus, the locus in X swept out by the images of p under generically finite morphisms from S is codimension at least 3 in X. It follows that the images of S under generically finite morphisms sweep out a subvariety of codimension at least 1, as required.

Proof. As we saw in the proof of Corollary 3.7, for any fixed surface S in the fibres of $\mathcal {S} \to B$ , we can construct $\mathcal {B}_{r,d}$ , the tower of induced varieties on the locus in $\mathcal {U}_{n,d}$ swept out by generically finite images from S. We have already seen that $\mathcal {B}_{m,d}$ has codimension at least $1$ in $\mathcal {U}_{m,d}$ for some m satisfying $d> (2-\sqrt {2})(m+1)+2$ . Thus, $\mathcal {B}_{m-c,d}$ will have codimension at least $2c+1$ in $\mathcal {U}_{m-c,d}$ for r in this range. If we let $\mathcal {B}^{\prime }_{m,d}$ be the union of all the $\mathcal {B}_{m,d}$ over all the different possible S, then $\mathcal {B}^{\prime }_{m-c,d}$ will have codimension at least $2c+1-k$ in $\mathcal {U}_{m-c,d}$ . If $2c+1-k \geq m-c$ , then we see that a very general X of degree d in $\mathbb {P}^{m-c}$ will admit no generically finite maps from the fibres of S. Using $m-c = n$ and rearranging, we see that the result holds as claimed.