Proof. Suppose that $e(H)>k|T|$ . Then, by Jensen’s inequality,

$$ \begin{align*}\sum_{v\in T} \binom{d_H(v)}{k}\geq |T|\binom{e(H)/|T|}{k}\geq |T|\left(\frac{e(H)}{k|T|}\right)^k.\end{align*} $$

By the degree condition we have $e(H)\geq k|S||T|^{1-1/k}$ . Then $\frac {e(H)}{k|T|}\geq |S||T|^{-1/k}$ and therefore, $\sum _{v\in T} \binom {d_H(v)}{k} \geq |S|^k\geq k\binom {|S|}{k}$ . This implies that there is some $R\subset S$ of size k whose common neighbourhood in T has size at least k. Then H contains $K_{k,k}$ , which is a contradiction.

Proof. Let $A=\{u_1,u_2,\dots ,u_n\}$ , and let $G_0=G$ . Let us define spanning subgraphs $G_1,\dots ,G_n$ of G recursively as follows. Having defined $G_{i-1}$ for some $1\leq i\leq n$ , let $T=N_{G_{i-1}}(u_i)$ , let $S=\{u_j: j>i \text { and } d_{G_{i-1}}(u_i,u_j)>k m^{1-1/k}\}$ and let $H=G_{i-1}[S\cup T]$ . Since H is a subgraph of G, it is $K_{k,k}$ -free. Moreover, for any $u_j\in S$ , $d_H(u_j)=d_{G_{i-1}}(u_i,u_j)>k m^{1-1/k}\geq k |T|^{1-1/k}$ . Hence, by Lemma 3.1, $e(H)\leq k|T|$ . Let $G_i$ be the subgraph of $G_{i-1}$ obtained by deleting the edges in H. Then $e(G_{i-1})-e(G_i)=e(H)\leq kd_{G_{i-1}}(u_i)$ .

Observe that for any $i<j$ , we have $d_{G_n}(u_i,u_j)\leq km^{1-1/k}$ . Moreover, note that for any $1\leq i\leq n$ , $d_{G_n}(u_i)=d_{G_{i-1}}(u_i)$ , so

$$ \begin{align*}e(G_n)=\sum_{i=1}^n d_{G_n}(u_i)=\sum_{i=1}^n d_{G_{i-1}}(u_i)\geq \sum_{i=1}^n (e(G_{i-1})-e(G_i))/k=(e(G_0)-e(G_n))/k.\end{align*} $$

Thus, $e(G_n)\geq e(G_0)/(k+1)=e(G)/(k+1)$ , which means that $G'=G_n$ satisfies the conditions described in the lemma.

Proof. Choose A, B and D according to Definition 3.4. Define $B'$ to be a random subset of B where each $v\in B$ is kept independently with probability $\frac {d}{D}$ . Let $G'$ be the subgraph of $G[A\cup B']$ obtained by deleting all edges $uv$ with $|N_G(u)\cap B'|\geq 4Ld$ . Clearly, $\Delta (G')\leq \max (4Ld,d)=4Ld$ .

Let $X=e(G[A\cup B'])$ , and let Y be the number of edges $uv\in E(G[A\cup B'])$ with $|N_G(u)\cap B'|\geq 4Ld$ . Now,

$$ \begin{align*}\mathbb{E}[X]=\sum_{uv\in E(G)} \mathbb{P}(v\in B')=e(G)\frac{d}{D}\end{align*} $$

and

$$ \begin{align*} \mathbb{E}[Y] &=\sum_{uv\in E(G)} \mathbb{P}(v\in B' \text{ and } |N_G(u)\cap B'|\geq 4Ld) \\ &=\sum_{uv\in E(G)} \mathbb{P}(v\in B')\mathbb{P}\left(|N_G(u)\cap B'|\geq 4Ld \hspace{1mm} | \hspace{1mm} v\in B'\right). \end{align*} $$

For any $uv\in E(G)$ , we have

$$ \begin{align*}\mathbb{E}[|N_G(u)\cap B'| \hspace{1mm} | \hspace{1mm} v\in B']=1+(d_G(u)-1)\frac{d}{D}\leq 1+LD\frac{d}{D}= 1+Ld\leq 2Ld,\end{align*} $$

so it follows by Markov’s inequality that

$$ \begin{align*}\mathbb{P}\left(|N_G(u)\cap B'|\geq 4Ld \hspace{1mm} | \hspace{1mm} v\in B'\right)\leq 1/2.\end{align*} $$

Hence,

$$ \begin{align*}\mathbb{E}[Y]\leq \sum_{uv\in E(G)}\mathbb{P}(v\in B')/2=e(G)\frac{d}{2D}.\end{align*} $$

Thus, using $|A|D=|B|d=e(G)$ ,

$$ \begin{align*} \mathbb{E}[X-Y-(|A|+|B'|)d/4] &\geq e(G)\frac{d}{D}-e(G)\frac{d}{2D}-|A|d/4-|B|\frac{d}{D}d/4 \\ &= e(G)\frac{d}{D}-e(G)\frac{d}{2D}-e(G)\frac{d}{4D}-e(G)\frac{d}{4D}=0. \end{align*} $$

In particular, there is an outcome for which $X-Y\geq (|A|+|B'|)d/4$ . Since $e(G')=X-Y$ , this means that $G'$ has average degree at least $d/2$ .

Proof of Lemma 3.5.

Let $d=\lceil \frac {\delta }{4\log L}\rceil $ . Now, $\delta /(d-1)\geq 4\log L$ , so $\lfloor \delta /(d-1)\rfloor \geq 2\log L$ . Hence, $2^{\lfloor \delta /(d-1)\rfloor }\geq L^2\geq L\delta $ . By Lemma 3.6, G has a $(4,d)$ -almost-biregular subgraph $G'$ . By Lemma 3.7, $G'$ has a subgraph with average degree at least $d/2$ and maximum degree at most $16d$ . Repeatedly discarding vertices of degree less than $d/4$ , we end up with a nonempty subgraph $G"$ with minimum degree at least $d/4$ and maximum degree at most $16d$ . Clearly, $G"$ is $64$ -almost-regular. Moreover, the average degree of $G"$ is at least $d/4\geq \frac {\delta }{16\log L}$ .

Proof. Let $A_{s+1}=\{u\in A:d_G(u)\leq 2^{s+1}\}$ and for each $s+2\leq i\leq t$ , let $A_i=\{u\in A: 2^{i-1}<d_G(u)\leq 2^{i}\}$ . Observe that the sets $A_{s+1},\dots ,A_t$ partition A. For each $u\in A$ , let $\alpha (u)$ be the unique i with $u\in A_i$ . For $v\in B$ , let

$$ \begin{align*}\beta(v)=\sum_{u\in N_G(v)} \alpha(u).\end{align*} $$

Note that for every $v\in B$ , we have $(s+1)r\leq \beta (v)\leq tr$ , so there are at most $(t-s)r$ possible values for $\beta (v)$ . Hence, by the pigeonhole principle, there are some $\gamma \geq (s+1)r$ and a subset $\tilde {B}\subset B$ of size at least $\frac {|B|}{(t-s)r}$ such that $\beta (v)=\gamma $ for all $v\in \tilde {B}$ .

Let $A'$ be a random subset of A where each $u\in A$ is kept independently with probability $2^{\alpha (u)-t}$ . Let $B'=\{v\in \tilde {B}: N_G(v)\subset A'\}$ . Let $A"$ be the subset of $A'$ consisting of those vertices u with $|N_G(u)\cap B'|\leq 4r2^{\gamma -(r-1)t}$ , and let $B"=\{v\in B': N_G(v)\subset A"\}$ . Let $G'=G[A"\cup B"]$ . Then $d_{G'}(u)\leq 4r2^{\gamma -(r-1)t}$ for all $u\in A"$ .

The following claim shows that we expect $E(G[A'\cup B'])\setminus E(G')$ to be small.

Claim. For any $uv\in E(G[A\cup \tilde {B}])$ with $u\in A$ and $v\in \tilde {B}$ ,

$$ \begin{align*}\mathbb{P}(u\in A',v\in B' \text{ and } |N_G(u)\cap B'|\geq 4r2^{\gamma-(r-1)t})\leq \mathbb{P}(v\in B')/(2r).\end{align*} $$

Proof of Claim.

Note that

(4.1) $$ \begin{align} &\mathbb{E}[|N_G(u)\cap B'| \hspace{1mm} | \hspace{1mm} v\in B'] =\sum_{w\in N_G(u)\cap \tilde{B}} \mathbb{P}(w\in B' \hspace{1mm} | \hspace{1mm} v\in B') \nonumber \\ &= \sum_{\substack{w\in N_G(u)\cap \tilde{B}: \\ N_G(w)\cap N_G(v)=\{u\}}} \mathbb{P}(w\in B' \hspace{1mm} | \hspace{1mm} v\in B') + \sum_{\substack{w\in N_G(u)\cap \tilde{B}: \\ N_G(w)\cap N_G(v)\neq \{u\}}} \mathbb{P}(w\in B' \hspace{1mm} | \hspace{1mm} v\in B'). \end{align} $$

We now bound the two sums separately. If some $w\in N_G(u)\cap \tilde {B}$ satisfies $N_G(w)\cap N_G(v)=\{u\}$ , then

$$ \begin{align*} \mathbb{P}(w\in B' \hspace{1mm} | \hspace{1mm} v\in B') &=\mathbb{P}(w\in B' \hspace{1mm} | \hspace{1mm} u\in A')=\prod_{z\in N_G(w)\setminus \{u\}} \mathbb{P}(z\in A')=\prod_{z\in N_G(w)\setminus \{u\}} 2^{\alpha(z)-t} \nonumber \\ &=2^{\sum_{z\in N_G(w)\setminus \{u\}} \alpha(z)-(r-1)t}=2^{\beta(w)-\alpha(u)-(r-1)t}=2^{\gamma-\alpha(u)-(r-1)t}. \end{align*} $$

Since $d_G(u) \leq 2^{\alpha (u)}$ , we have that

$$ \begin{align*}\sum_{\substack{w\in N_G(u)\cap \tilde{B}: \\ N_G(w)\cap N_G(v)=\{u\}}} \mathbb{P}(w\in B' \hspace{1mm} | \hspace{1mm} v\in B')\leq d_G(u)2^{\gamma-\alpha(u)-(r-1)t}\leq 2^{\gamma-(r-1)t}.\end{align*} $$

As for the second sum, the number of $w\in N_G(u)\cap \tilde {B}$ with $N_G(w)\cap N_G(v)\neq \{u\}$ is at most $r2^{rs-(r-1)t}$ . Indeed, v has r neighbours in G, so there are at most r ways to choose a vertex $u'\in N_G(w)\cap N_G(v)\setminus \{u\}$ , and, by assumption, any such $u'$ has at most $2^{rs-(r-1)t}$ common neighbours with u. Now, using ${\gamma \geq (s+1)r}$ , we have $2^{\gamma -(r-1)t}\geq 2^{r}2^{rs-(r-1)t}\geq r2^{rs-(r-1)t}$ . This implies that

$$ \begin{align*}\sum_{\substack{w\in N_G(u)\cap \tilde{B}: \\ N_G(w)\cap N_G(v)\neq \{u\}}} \mathbb{P}(w\in B' \hspace{1mm} | \hspace{1mm} v\in B')\leq r2^{rs-(r-1)t}\leq 2^{\gamma-(r-1)t}.\end{align*} $$

Thus, by (4.1),

$$ \begin{align*}\mathbb{E}[|N_G(u)\cap B'| \hspace{1mm} | \hspace{1mm} v\in B']\leq 2^{\gamma-(r-1)t+1}.\end{align*} $$

This implies, by Markov’s inequality, that

$$ \begin{align*}\mathbb{P}(|N_G(u)\cap B'|\geq 4r2^{\gamma-(r-1)t} \hspace{1mm} | \hspace{1mm} v\in B')\leq 1/(2r).\end{align*} $$

Thus,

$$ \begin{align*} &\mathbb{P}(u\in A',v\in B' \text{ and } |N_G(u)\cap B'|\geq 4r2^{\gamma-(r-1)t}) \\ &=\mathbb{P}(v\in B' \text{ and } |N_G(u)\cap B'|\geq 4r2^{\gamma-(r-1)t}) \\ &=\mathbb{P}(v\in B')\mathbb{P}(|N_G(u)\cap B'|\geq 4r2^{\gamma-(r-1)t} \hspace{1mm} | \hspace{1mm} v\in B')\leq \mathbb{P}(v\in B')/(2r), \end{align*} $$

completing the proof of the claim.

For any $uv\in E(G[A\cup \tilde {B}])$ ,

(4.2) $$ \begin{align} \mathbb{P}(u\in A', v\in B')=\mathbb{P}(v\in B')=\prod_{w\in N_G(v)} \mathbb{P}(w\in A')=\prod_{w\in N_G(v)} 2^{\alpha(w)-t}=2^{\gamma-rt}. \end{align} $$

Let $X=e(G[A'\cup B'])$ , and let Y be the number of edges $uv\in E(G[A'\cup B'])$ with $|N_G(u)\cap B'|\geq 4r2^{\gamma -(r-1)t}$ . Note that $e(G')\geq X-rY$ . Indeed, $E(G')$ is obtained from $E(G[A'\cup B'])$ by deleting all edges incident to vertices $v\in B'$ which have a neighbour u with $|N_G(u)\cap B'|> 4r2^{\gamma -(r-1)t}$ . Clearly, there are at most Y such vertices $v\in B'$ , so at most $rY$ edges are deleted. By equation (4.2) and the claim, we have

$$ \begin{align*} &\mathbb{E}[X-rY] \\ &\quad=\sum_{uv\in E(G[A\cup \tilde{B}])} \left(\mathbb{P}(u\in A', v\in B')-r\mathbb{P}(u\in A', v\in B' \text{ and } |N_G(u)\cap B'|\geq 4r2^{\gamma-(r-1)t})\right) \\ &\quad\geq \sum_{uv\in E(G[A\cup \tilde{B}])} (\mathbb{P}(v\in B')-\mathbb{P}(v\in B')/2) = e(G[A\cup \tilde{B}])2^{\gamma-rt-1} \\ &\quad=|\tilde{B}|r2^{\gamma-rt-1}\geq \frac{|B|}{(t-s)r}r 2^{\gamma-rt-1}= \frac{e(G)}{(t-s)r}2^{\gamma-rt-1}. \end{align*} $$

Note that, for every $u\in A$ , we have $2^{\alpha (u)}\leq 2^{s+1}+2d_G(u)$ . Indeed, this is trivial if $\alpha (u)=s+1$ , and else $d_G(u)\geq 2^{\alpha (u)-1}$ . Also recall that $e(G)\geq 2^s|A|$ . Therefore,

$$ \begin{align*} \mathbb{E}\lbrack |A'|\rbrack &=\sum_{u\in A}\mathbb{P}(u\in A')=\sum_{u\in A} 2^{\alpha(u)-t}\leq 2^{-t}\sum_{u\in A} (2^{s+1}+2d_G(u)) \\ &=2^{-t}(|A|2^{s+1}+2e(G))\leq 2^{-t}4e(G). \end{align*} $$

Hence,

$$ \begin{align*}\mathbb{E}\left[X-rY-|A'|\frac{2^{\gamma-(r-1)t}}{10(t-s)r}\right]>0.\end{align*} $$

It follows that there exists an outcome for which $X-rY-|A'|\frac {2^{\gamma -(r-1)t}}{10(t-s)r}>0$ . Then $e(G')\geq X-rY\geq |A'|\frac {2^{\gamma -(r-1)t}}{10(t-s)r}$ . Hence, $d'=e(G')/|A"|$ satisfies $d'\geq e(G')/|A'|\geq \frac {2^{\gamma -(r-1)t}}{10(t-s)r}\geq \frac {2^{rs-(r-1)t}}{10(t-s)r}$ and $d_{G'}(u)\leq 4r2^{\gamma -(r-1)t}\leq 40(t-s)r^2d'$ for all $u\in A"$ , completing the proof.

Proof. We prove the lemma by induction on $t-s$ (with r fixed). If $t-s\leq 5\log r$ , then we can take $s^*=s$ , $t^*=t$ , $A^*=A$ and $B^*=B$ . Assume now that $t-s>5\log r$ . Note that $2rs-(2r-1)t\leq rs-(r-1)t$ , so for any two distinct $u,u'\in A$ , we have $d_G(u,u')\leq 2^{rs-(r-1)t}$ . By Lemma 4.1, there are subsets $A'\subset A$ and $B'\subset B$ such that $N_G(v)\subset A'$ for every $v\in B'$ and, writing $G'=G[A'\cup B']$ and $d'=e(G')/|A'|$ , we have $d'\geq \frac {2^{rs-(r-1)t}}{10(t-s)r}$ and $d_{G'}(u)\leq 40(t-s)r^2 d'$ for all $u\in A'$ . By the codegree condition, $2rs-(2r-1)t\geq 0$ , so $rs-(r-1)t\geq (t-s)r$ and hence $d'\geq 2$ . Let $s'=\lfloor \log d' \rfloor $ , and let $t'=\lceil \log (40(t-s)r^2d') \rceil $ . Then $s'<t'$ , $d_{G'}(v)=r$ for every $v\in B'$ , $d_{G'}(u)\leq 2^{t'}$ for every $u\in A'$ and $e(G')\geq 2^{s'}|A'|$ . Moreover, using $d'\geq \frac {2^{rs-(r-1)t}}{10(t-s)r}$ , we have $t'\geq rs-(r-1)t$ . Hence,

$$ \begin{align*} 2rs'-(2r-1)t' &=t'-2r(t'-s')\geq t'-2r(\log(40(t-s)r^2)+2) \\ &\geq rs-(r-1)t-2r\log(160(t-s)r^2) \\ &=2rs-(2r-1)t+r(t-s)-2r\log(160(t-s)r^2) \\ &\geq 2rs-(2r-1)t, \end{align*} $$

where the last inequality uses that $t-s\geq 5\log r$ and that r is sufficiently large. Hence, for any distinct $u,u'\in A'$ , we have $d_{G'}(u,u')\leq d_G(u,u')\leq 2^{2rs-(2r-1)t}\leq 2^{2rs'-(2r-1)t'}$ . Finally, $t'-s'\leq \log (40(t-s)r^2)+2<t-s$ .

Thus, by the induction hypothesis, there exist positive integers $s^*\geq 2rs'-(2r-1)t'$ , $t^*>s^*$ and sets $A^*\subset A'$ , $B^*\subset B'$ such that $N_{G'}(v)\subset A^*$ for every $v\in B^*$ , $t^*-s^*\leq 5\log r$ and, writing $G^*=G'[A^*\cup B^*]=G[A^*\cup B^*]$ and $d^*=e(G^*)/|A^*|$ , we have $d^*\geq 2^{s^*}$ and $d_{G^*}(u)\leq 2^{t^*}$ for all $u\in A^*$ . Since $N_G(v)=N_{G'}(v)$ for every $v\in B'$ , we have $N_{G}(v)\subset A^*$ for every $v\in B^*$ . As $2rs'-(2r-1)t'\geq 2rs-(2r-1)t$ , it follows that $s^*\geq 2rs-(2r-1)t$ , so $s^*$ , $t^*$ , $A^*$ and $B^*$ are suitable for the conclusion of the lemma.

Proof. By the assumption on the codegrees, we have $2rs-(2r-1)t-r\geq 0$ , so $2rs-(2r-1)t\geq r$ . Hence, by Lemma 4.2, G has a $(2^{5\log r},r)$ -almost-biregular subgraph $G^*$ (the condition $2rs-(2r-1)t\geq r$ ensures that $s^*\geq r$ and so $d^*\geq r$ ). Then, by Lemma 3.5 with $L=2^{5\log r}$ and $\delta =r$ , $G^*$ has a $64$ -almost-regular subgraph with average degree at least $\frac {r}{80\log r}$ .

Proof. We may assume that $r\geq k\log r$ , otherwise the conclusion of the lemma is trivial. By Lemma 3.2, G has a spanning subgraph $G'$ such that $e(G')\geq e(G)/(k+1)$ and $d_{G'}(u,u')\leq k 2^{(1-1/k)t}$ for any two distinct $u,u'\in A$ . Since $s\leq t-1$ and $s\geq t(1-\frac {1}{6r})$ , we have $t\geq 6r$ . Hence, $2^{\frac {t}{2k}}\geq 2^{3r/k}\geq 2^{\log r}=r\geq k$ . Thus, $k 2^{(1-1/k)t}\leq 2^{(1-\frac {1}{2k})t}$ , so $d_{G'}(u,u')\leq 2^{(1-\frac {1}{2k})t}$ for any two distinct $u,u'\in A$ . Let $\tilde {B}$ be the subset of B consisting of those vertices v which satisfy $d_{G'}(v)\geq r/(2k+2)$ . Now, the number of edges in $G'$ between A and $B\setminus \tilde {B}$ is at most $|B|r/(2k+2)=e(G)/(2k+2)\leq e(G')/2$ , so there are at least $e(G')/2$ edges between A and $\tilde {B}$ . Let $r'=\lceil r/(2k+2)\rceil $ and let $G"$ be a spanning subgraph of $G'[A\cup \tilde {B}]$ obtained by keeping precisely $r'$ edges from each $v\in \tilde {B}$ . Clearly, $e(G")\geq e(G'[A\cup \tilde {B}])/(2k+2)\geq e(G')/(4k+4)\geq e(G)/(4(k+1)^2)\geq 2^s|A|$ . Note that

$$ \begin{align*} 2r's-(2r'-1)t-r' &=t-r'(2t-2s+1)\geq t-\frac{r}{k}(2t-2s+1)\geq t-\frac{3r}{k}(t-s) \\ &\geq t-\frac{3r}{k}\cdot \frac{t}{6r}=(1-\frac{1}{2k})t, \end{align*} $$

so $d_{G"}(u,u')\leq 2^{2r's-(2r'-1)t-r'}$ holds for any distinct $u,u'\in A$ . Thus, we can apply Lemma 5.1 with $G"$ in place of G and $r'$ in place of r to get a $64$ -almost-regular subgraph with average degree at least $\frac {r'}{80\log r'}\geq \frac {r}{160(k+1)\log r}$ .

Proof. Since r is sufficiently large, the degree conditions imply that $\Delta $ is also sufficiently large. Moreover, we may assume that $r\geq k$ , otherwise the conclusion of the lemma is trivial. Note that G has a bipartite subgraph $G'$ with average degree at least $40r^2\log \log \Delta $ and $G'$ has a nonempty subgraph $G"$ with minimum degree at least $20r^2\log \log \Delta $ (this subgraph can be obtained by repeatedly discarding vertices of degree less than $20r^2\log \log \Delta $ ). Let A and B be the parts of $G"$ such that $|A|\leq |B|$ . Let H be a spanning subgraph of $G"$ such that $d_H(v)=20r^2\log \log \Delta $ for every $v\in B$ .

Let $t_0=r (\log r)(\log \log \Delta )^{1/2}$ and let $\ell $ be the smallest nonnegative integer such that $t_0/(1-\frac {1}{10r})^{\ell }\geq \log \Delta $ . Note that $(1-\frac {1}{10r})^{10r\log \log \Delta }\leq \exp (-\log \log \Delta )\leq 1/\log \Delta $ , so $\ell \leq 10r\log \log \Delta $ . For $1\leq i\leq \ell $ , let $t_i=t_0/(1-\frac {1}{10r})^{i}$ . Clearly, $t_\ell \geq \log \Delta $ .

Let $A_0=\{u\in A: d_H(u)\leq 2^{t_0}\}$ and for $1\leq i\leq \ell $ , let $A_i=\{u\in A: 2^{t_{i-1}}<d_H(u)\leq 2^{t_i}\}$ . Clearly, these sets partition A. Hence, for every $v\in B$ , either v has at least $d_H(v)/2= 10r^2\log \log \Delta $ neighbours (in the graph H) in $A_0$ or $\ell>0$ and there is some $1\leq i\leq \ell $ such that v has at least $d_H(v)/(2\ell )\geq r$ neighbours in $A_i$ .

Therefore, at least one of the following two cases must occur.

Case 1. There are at least $|B|/2$ vertices $v\in B$ which have at least $10r^2\log \log \Delta $ neighbours in $A_0$ .

Case 2. There exist some $1\leq i\leq \ell $ and at least $|B|/(2\ell )$ vertices $v\in B$ which have at least r neighbours in $A_i$ .

In Case 1, let $B'\subset B$ be a set of size at least $|B|/2$ such that every $v\in B'$ has at least $10r^2\log \log \Delta $ neighbours in $A_0$ . For technical reasons, let us take a random subset $A_0'\subset A_0$ of size $|A_0|/3$ . With positive probability, there is a set $B"\subset B'$ of at least $2|B'|/3$ vertices which all have at least $r^2\log \log \Delta $ neighbours in $A_0'$ . Let $H'$ be a spanning subgraph of $H[A_0'\cup B"]$ obtained by keeping precisely $r^2\log \log \Delta $ edges from each vertex in $B"$ . Now, note that $|A_0'|=|A_0|/3\leq |A|/3\leq |B|/3\leq 2|B'|/3\leq |B"|$ . Moreover, $d_{H'}(u)\leq d_H(u)\leq 2^{t_0}$ for every $u\in A_0'$ . This implies that $H'$ is $(L,d)$ -almost biregular for $L=2^{t_0}=2^{r(\log r)(\log \log \Delta )^{1/2}}$ and $d=r^2\log \log \Delta $ . Hence, by Lemma 3.5, $H'$ has a $64$ -almost-regular subgraph with average degree at least $\frac {r^2\log \log \Delta }{16r(\log r)(\log \log \Delta )^{1/2}}\geq \frac {r}{160(k+1)\log r}$ .

In Case 2, let us choose some $1\leq i\leq \ell $ and a set $B'\subset B$ of size at least $|B|/(2\ell )$ such that for every $v\in B'$ , v has at least r neighbours in $A_i$ . Let $H'$ be a subgraph of $H[A_i\cup B']$ obtained by keeping precisely r edges incident to each $v\in B'$ . We will apply Lemma 5.2 for this graph. Let $t=t_i$ and let $s=t(1-\frac {1}{6r})$ . Note that for any $u\in A_i$ , $d_{H'}(u)\leq d_{H}(u)\leq 2^{t}$ . Let $C=4(r+1)^2$ . Using that $|B|\cdot 20r^2\log \log \Delta = e(H)\geq |A_i|2^{t_{i-1}}$ , we get

$$ \begin{align*} e(H') &=|B'|r\geq |B|r/(2\ell)=\frac{e(H)}{40\ell r \log \log \Delta}\geq \frac{e(H)}{400r^2(\log \log \Delta)^2}\geq \frac{C|A_i|2^{t_{i-1}}}{400Cr^2(\log \log \Delta)^2} \\ &=C|A_i|2^{t_{i-1}-\log(400Cr^2(\log \log \Delta)^2)}. \end{align*} $$

Note that

$$ \begin{align*}t_{i-1}-\log(400Cr^2(\log \log \Delta)^2)=t\left(1-\frac{1}{10r}\right)-\log(400Cr^2(\log \log \Delta)^2)\geq t\left(1-\frac{1}{6r}\right)=s,\end{align*} $$

where the inequality follows from $t/r\geq t_0/r=(\log r)(\log \log \Delta )^{1/2}$ and since $\Delta $ is sufficiently large. Hence, $e(H')\geq C|A_i|2^s\geq 4(k+1)^2|A_i|2^s$ .

Thus, we can apply Lemma 5.2 to the graph $H'$ and get a $64$ -almost-regular subgraph with average degree at least $\frac {r}{160(k+1)\log r}$ .

Proof of Theorem 1.2.

Let r be sufficiently large in terms of k, and let $C=80r^2$ . Let G be a graph with maximum degree $\Delta $ and average degree at least $C\log \log \Delta $ . If G contains $K_{k,k}$ as a subgraph, then it has a k-regular subgraph. Else, by Theorem 5.3, G has a $64$ -almost-regular subgraph $G'$ with average degree at least $\frac {r}{160(k+1)\log r}$ . Since r is sufficiently large in terms of k, Theorem 3.8 implies that $G'$ has a k-regular subgraph.

Proof. Let $n_0$ be sufficiently large in terms of $m_0$ , and let G be a graph with $n\geq n_0$ vertices and at least $n\log n$ edges. Let $r=\frac {\sqrt {\log n}}{10\sqrt {\log \log n}}$ , and let $\Delta $ be the maximum degree of G. Since $\Delta \leq n$ , the average degree of G is at least $\log n\geq 100r^2\log \log \Delta $ . If $K_{m_0,m_0}$ is a subgraph of G, then we are done. Else, by Theorem 5.3, G has a $64$ -almost-regular subgraph $G'$ with average degree at least $\frac {r}{160(m_0+1)\log r}$ . This is at least for some that depends only on $m_0$ . Now, if m is the number of vertices in $G'$ , then $m\geq m_0$ (since n is sufficiently large) and $G'$ has at least edges, as desired.

Proof. We only prove the first assertion – the second one has a very similar proof.

Let G be an n-vertex graph with average degree d. We may assume that $d/\log \log n$ is sufficiently large, otherwise the statement is trivial. Let be a sufficiently small positive absolute constant, and let . We want to show that G has a $64$ -almost-regular subgraph with average degree at least k. Let $r=(\frac {d}{80\log \log n})^{1/2}$ . If G contains $K_{k,k}$ as a subgraph, then we are done; else, by Theorem 5.3, G has a $64$ -almost-regular subgraph with average degree at least $\frac {r}{160(k+1)\log r}$ . But for sufficiently small , we have $\frac {r}{160(k+1)\log r}\geq k$ , so the proof is complete.