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Community Bot
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Is there a smooth, rationally connected, projective variety $M$, which is not a projective space and is equipped with an ample line bundle $L$, such that the homology class of the curves $[A]$ which connect any two points satisfies $c_1(L)([A])=1$?

This is closely related (but not equivalent) to my other question

G.W. invariants $<[pt],[pt]>_{0,[A]} \neq 0$ such that there exists ample L with $c_1(L)([A])=1$G.W. invariants $<[pt],[pt]>_{0,[A]} \neq 0$ such that there exists ample L with $c_1(L)([A])=1$

but phrased in a classical way.

Is there a smooth, rationally connected, projective variety $M$, which is not a projective space and is equipped with an ample line bundle $L$, such that the homology class of the curves $[A]$ which connect any two points satisfies $c_1(L)([A])=1$?

This is closely related (but not equivalent) to my other question

G.W. invariants $<[pt],[pt]>_{0,[A]} \neq 0$ such that there exists ample L with $c_1(L)([A])=1$

but phrased in a classical way.

Is there a smooth, rationally connected, projective variety $M$, which is not a projective space and is equipped with an ample line bundle $L$, such that the homology class of the curves $[A]$ which connect any two points satisfies $c_1(L)([A])=1$?

This is closely related (but not equivalent) to my other question

G.W. invariants $<[pt],[pt]>_{0,[A]} \neq 0$ such that there exists ample L with $c_1(L)([A])=1$

but phrased in a classical way.

edited title
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Daniel Pomerleano
Daniel Pomerleano
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Is there a smooth rationally connected, proper variety $M$ over $\mathbb{C}$ such that c_1(L)([A]) = 1 ? which is not projective space?

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Daniel Pomerleano
Daniel Pomerleano
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Is there a smooth rationally connected, proper variety $M$ over $\mathbb{C}$ such that c_1(L)([A]) = 1 ? which is not projective space?

Is there a smooth, rationally connected, projective variety $M$, which is not a projective space and is equipped with an ample line bundle $L$, such that the homology class of the curves $[A]$ which connect any two points satisfies $c_1(L)([A])=1$?

This is closely related (but not equivalent) to my other question

G.W. invariants $<[pt],[pt]>_{0,[A]} \neq 0$ such that there exists ample L with $c_1(L)([A])=1$

but phrased in a classical way.