Invent. Math. 5 1968 63--84.
Comments
In my thesis, I proved results about pairs of abelian varieties, sometimes assuming that one
was a Jacobian (because that was all I need for the applications I had in mind). As Tate pointed
out, I never really used that the abelian variety was a Jacobian. So I extracted
the results from my theses on abelian varieties and publishing them separately.
Let
$A$ and $B$ be abelian varieties over a finite field $k$. Let $(\alpha_i)$
(resp. $(\beta_j)$) be a $\mathbb{Z}$-base for $\mathrm{Hom}(A,B)$
(resp. $\mathrm{Hom}(B,A)$. Then, to quote Tate (Bourbaki Seminar 1968,
page 352-15), I prove that the group $\mathrm{Ext}^1(A,B)$ is finite
and the product of its order with $\mathrm{det}(\alpha_i\beta_j)$ is
calculated by "une belle formule" in terms of the characteristic polynomials
of the Frobenius elements $\pi_A$ and $\pi_B$.
The proof of the formula uses the Tate conjecture for divisors on abelian varieties
over finite fields (proved by Tate in 1966). Sometime in the 2000s,
Niranjan Ramachandran suggested to me that we generalize
the formula to motives. This led to a series of articles in which we generalize
it to a conjectural formula for motives or complexes of motives
(in the sense of Voevodsky completed at $p$), and we proved that the formula is implied by the Tate conjecture.
In fact, the conjecture could be true even if the Tate conjecture fails: all it needs is a sufficiently
good theory of rational structures on the $l$-adic spaces of Tate classes.
Erratum
p.81 line 2 from bottom.
The formula should read $z(g)=\left\vert q^{m_{1}n_{2}}
\prod\left( 1-\frac{a_{i}}{b_{j}}\right) \right\vert _{p}$.
pp.78,79 Lemma 4. Because of the change on p81, the lemma
should state that%
\[
z(g)=\left\vert q^{d(G^{t})\cdot d(H)}\prod_{a_{i}\neq b_{j}}\left(
1-\frac{a_{i}}{b_{j}}\right) \right\vert _{p}=z(g_{1}),
\]
not $\cdots q^{d(G)\cdot d(H^{t})}\cdots$.
Examples
Recall that the main theorem (Theorem 3) says that, if $A$ and $B$ are abelian
varieties over $\mathbb{F}{}_{q}$, then
\[
q^{d(A)d(B)}\prod_{a_{i}\neq b_{j}}\left( 1-\frac{a_{i}}{b_{j}}\right)
=[\mathrm{Ext}_{k}^{1}(A,B)]|\det(\langle\alpha_{i},\beta_{j}\rangle)|.
\]
Example 1.
Assume that the characteristic polynomials $c_{A}(T)$ and
$c_{B}(T)$ have no common root. Then $\mathrm{Hom}(A,B)=0$ and $|\det(\langle\alpha
_{i},\beta_{j}\rangle)|=1$. For a fixed $i$,
\[
\prod\nolimits_{j}\left( 1-\frac{a_{i}}{b_{j}}\right) =\frac{\prod
\nolimits_{j}(b_{j}-a_{i})}{\prod\nolimits_{j}b_{j}}=q^{-d(B)}\prod
\nolimits_{j}(b_{j}-a_{i}),
\]
and so
\[
\prod\nolimits_{i,j}\left( 1-\frac{a_{i}}{b_{j}}\right) =q^{-d(A)d(B)}
\prod\nolimits_{i,j}(b_{j}-a_{i}).
\]
Hence
\[
\lbrack\mathrm{Ext}_{k}^{1}(A,B)]=q^{-d(A)d(B)}\prod\nolimits_{i,j}(b_{j}
-a_{i})=q^{-d(A)d(B)}\cdot\mathrm{Resultant}(c_{A},c_{B}).
\]
For example, if $A$ and $B$ are elliptic curves, then
\begin{align*}
\lbrack\mathrm{Ext}^{1}(A,B)] & =q^{-1}
\begin{vmatrix}
1 & n_{1}-q-1 & q & 0\\
0 & 1 & n_{2}-q-1 & q\\
1 & n_{2}-q-1 & q & 0\\
0 & 1 & n_{2}-q-1 & q
\end{vmatrix}
\\
& =q^{-1}
\begin{vmatrix}
0 & n_{1}-n_{2} & 0 & 0\\
0 & 0 & n_{1}-n_{2} & 0\\
1 & n_{2}-q-1 & q & 0\\
0 & 1 & n_{2}-q-1 & q
\end{vmatrix}
\\
& =q^{-1}
\begin{vmatrix}
n_{1}-n_{2} & 0\\
0 & n_{1}-n_{2}
\end{vmatrix}
\begin{vmatrix}
1 & 0\\
0 & q
\end{vmatrix}
\\
& =(n_{1}-n_{2})^{2}.
\end{align*}
For higher dimensional abelian varieties, it is a priori obvious that
$[\mathrm{Ext}^{1}(A,B)]$ can be expressed in terms of $n_{1}^{(1)},\,n_{1}
^{(2)},\,\ldots$ and $n_{2}^{(1)},\,n_{2}^{(2)},\,\ldots$ where $n_{1}
^{(i)}=[A(\mathbb{F}{}_{q^{i}})]$ and $n_{2}^{(i)}=[B(\mathbb{F}{}_{q^{i}})]$,
but not in terms of $n_{1}$ and $n_{2}$ alone.
Example 2.
Suppose that $A=B$ and $c_{A}(T)$ is irreducible over $\mathbb{Q}{}$
(hence without multiple roots). Let $d=d(A)$. For fixed $i$,
\[
\prod_{j\neq i}\left( 1-\frac{a_{i}}{a_{j}}\right) =\frac{\prod
\nolimits_{j\neq i}(a_{j}-a_{i})}{\prod\nolimits_{j\neq i}a_{j}}\text{.}
\]
Now
\begin{align*}
\prod_{i,\,j\,i\neq j}\left( 1-\frac{a_{i}}{a_{j}}\right) & =\frac
{\prod\nolimits_{i\neq j}(a_{j}-a_{i})}{(\prod\nolimits_{i\neq j}a_{j}
)^{2d-1}}\\
& =q^{-2d^{2}+d}\prod\nolimits_{i\neq j}(a_{j}-a_{i})\\
& =q^{d-d^{2}}\mathrm{disc}(c_{A}(T)).
\end{align*}
Let $E=\mathrm{End}(A)$ and $F=\mathbb{Z}{}[\pi]\subset E$, where $\pi$ is the
Frobenius endomorphism of $A$ over $\mathbb{F}{}_{q}$.
An endomorphism $\alpha$ of $A$ has a characteristic polynomial as an element
of $E\otimes\mathbb{Q}{}$ over $\mathbb{Q}{}$ and as an endomorphism of $A$.
These are both monic of degree $2d$, and hence equal.
Let $\alpha_{1},\ldots,\alpha_{r}$ be a basis for $E/\mathbb{Z}{}$. Then
\begin{align*}
|\det\langle\alpha_{i},\alpha_{j}\rangle| & =\mathrm{disc}(E/\mathbb{Z}{})\\
\mathrm{dis\mathrm{c}}(c_{A}(T)) & =\mathrm{disc}(\mathbb{Z}{}[\pi
]/\mathbb{Z}{})
\end{align*}
and so
\[
\lbrack\mathrm{Ext}^{1}(A,A)]=q^{d-d^{2}}\frac{\mathrm{disc}(\mathbb{Z}{}
[\pi]/\mathbb{Z}{})}{\mathrm{disc}(E/\mathbb{Z}{})}=q^{d-d^{2}}(E\colon
\mathbb{Z}{}[\pi])^{2}.
\]
For example, if $A$ is an elliptic curve, then
\[
\lbrack\mathrm{Ext}^{1}(A,A)]=(E\colon\mathbb{Z}{}[\pi])^{2}.
\]
Example 3.
$A=B$ and $c_{A}$ is a power of a linear polynomial. In this case,
\[
\lbrack\mathrm{Ext}^{1}(A,A)]=\left( \frac{q}{p^{2}}\right) ^{d^{2}}.
\]
For example, if $A$ is a supersingular elliptic curve, then
\[
\lbrack\mathrm{Ext}^{1}(A,A)]=\frac{q}{p^{2}}.
\]