For color-critical F with χ(F)=r+1≥4, λ²(G) ≥ 2(1-1/r)m + q implies N_F(G) ≥ (B_F - o(1)) q m^{(f-2)/2} for small q, with sharp B_F = α_F/4 ⋅ (2r/(r-1))^{f/2}.
On clique-to-clique densities
1 Pith paper cite this work. Polarity classification is still indexing.
abstract
Let $k_r(G)$ denote the number of $r$-cliques in a graph $G$ and let $F_r(\cdot)$ be the Lov\'asz--Simonovits $r$-clique density function. For any integers $2\le s<t$, we determine the asymptotically sharp lower bound on $k_t(G)$ in an $n$-vertex graph $G$ with a prescribed number $k_s(G)$, by showing that \[ \frac{k_t(G)}{n^t}\ge F_t\!\left(F_s^{-1}\!\left(\frac{k_s(G)}{n^s}\right)\right), \] where $F_s^{-1}$ denotes the generalized inverse. This strengthens Bollob\'as's piecewise-linear interpolation bound and, in the case $s=2$, recovers Reiher's clique density theorem via a new inductive proof.
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math.CO 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
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An edge-spectral supersaturation of Mubayi's theorem for color-critical graphs
For color-critical F with χ(F)=r+1≥4, λ²(G) ≥ 2(1-1/r)m + q implies N_F(G) ≥ (B_F - o(1)) q m^{(f-2)/2} for small q, with sharp B_F = α_F/4 ⋅ (2r/(r-1))^{f/2}.