latest publication + invited talk

.gitignore

@@ -13,5 +13,6 @@ src/*.log
 src/*.out
 src/*.pdf
 src/*.run.xml
+src/*-SAVE-ERROR
 src/*.synctex.gz
 src/*.xdv

src/cv_en.tex

@@ -57,7 +57,7 @@
 %\programming{{SageMath\slash Mathematica / 3}, {Bash $\textbullet$ C\slash C++ / 5}, {Python / 5.5}}{6}
 % Programming
 \programming{
-Python \faPython, C/C++, GNU/Linux \faLinux, Git, symbolic computation (SageMath), HTML/JS/CSS.\\
+Python \faPython, C/C++, GNU/Linux \faLinux, Git, symbolic computation (SageMath), HTML/JS/CSS, \LaTeX.\\
 
 \vspace{-15pt}
 Molecular dynamics, parallelisation on CPU and GPU (OpenMP, HOOMD), biased path ensemble algorithms.
@@ -74,8 +74,6 @@
 % Interests
 \interests{
 \begin{itemize}
-%\item[$\ast$] Involvement in the \'Ecole normale\\
-%sup\'erieure de Lyon's associations
 \setlength\itemsep{-0.8pt}
 \item[$\ast$] Extreme music.
 \item[$\ast$] Free software, open knowledge.
@@ -126,7 +124,7 @@ \section{Research}
 \cvitem
 	{Sep 2020}
 	{Sep 2023}
-  {PhD: ``Emergence of disordered collective motion in dense systems of isotropic self-propelled particles''}
+  {\href{https://theses.hal.science/tel-04530690v1}{PhD: ``Emergence of disordered collective motion in dense systems of isotropic self-propelled particles''}}
   {Laboratoire Charles Coulomb, UMR 5221 CNRS,\\ Universit\'e de Montpellier \worldflag{FR}\\
   \href{https://scglass.uchicago.edu}{Simons collaboration on \textit{Cracking the Glass Problem}}}
   {umontpellier.pdf,simons.pdf}{4.8}{-6.5}
@@ -243,11 +241,20 @@ \section{Conferences}
 
 \begin{cvbody}
 
+\cvitem
+	{Apr 2024}
+	{}
+	{Interdisciplinary challenges in non-equilibrium physics: from soft to active, biological and complex matter}
+	{Max-Planck-Institut für Physik komplexer Systeme, Dresden \worldflag{DE}\vspace{-5pt}}
+	{}{}{}
+	{}
+	{Invited talk, ``Fluctuations in dense active matter''.\\}
+
 \cvitem
 	{Jan 2024}
 	{}
 	{NWO Physics}
-	{NH Koningshof, Veldhoven \worldflag{NL}\vspace{-5pt}}
+	{NH Koningshof, Veldhoven \worldflag{NL}}
 	{}{}{}
 	{}
 	{Contributed talk, ``Disordered collective motion in dense and persistent active matter''.\\}
@@ -270,14 +277,14 @@ \section{Conferences}
 	{}
 	{Contributed talk, ``Disordered collective motion in dense and \textit{very}\\ persistent active matter''.\\}
 
-\cvitem
-	{Nov 2022}
-	{}
-	{GDR IDE ``Interaction, Disorder, Elasticity''}
-	{Universit\'e Grenoble Alpes \worldflag{FR}}
-	{}{}{}
-	{}
-	{Contributed talk, ``Intermittent active dynamics at infinite persistence''.\\}
+% \cvitem
+% 	{Nov 2022}
+% 	{}
+% 	{GDR IDE ``Interaction, Disorder, Elasticity''}
+% 	{Universit\'e Grenoble Alpes \worldflag{FR}}
+% 	{}{}{}
+% 	{}
+% 	{Contributed talk, ``Intermittent active dynamics at infinite persistence''.\\}
 
 \cvitem
 	{Jun 2022}
@@ -288,14 +295,14 @@ \section{Conferences}
 	{}
 	{Poster.\\}
 
-\cvitem
-	{Jun 2022}
-	{}
-	{Beg Rohu Summer School 2022}
-	{Quiberon, Brittany \worldflag{FR}}
-	{}{}{}
-	{}
-	{``Out of Equilibrium Dynamics''. Summer school. Poster.\\}
+% \cvitem
+% 	{Jun 2022}
+% 	{}
+% 	{Beg Rohu Summer School 2022}
+% 	{Quiberon, Brittany \worldflag{FR}}
+% 	{}{}{}
+% 	{}
+% 	{``Out of Equilibrium Dynamics''. Summer school. Poster.\\}
 
 \cvitem
 	{Feb 2022}
@@ -306,14 +313,14 @@ \section{Conferences}
 	{}
 	{Contributed talk, ``Disordered collective motion in dense assemblies\\ of persistent particles''.\\}
 
-\cvitem
-	{Oct 2021}
-	{}
-	{UCA Fall program on Complex Systems 2021}
-	{Universit\'e de Nice \worldflag{FR}}
-	{}{}{}
-	{}
-	{``Mobility, self-organization and swimming strategies''. Summer school.\\}
+% \cvitem
+% 	{Oct 2021}
+% 	{}
+% 	{UCA Fall program on Complex Systems 2021}
+% 	{Universit\'e de Nice \worldflag{FR}}
+% 	{}{}{}
+% 	{}
+% 	{``Mobility, self-organization and swimming strategies''. Summer school.\\}
 
 \cvitem
 	{Mar 2021}
@@ -332,45 +339,13 @@ \section{Conferences}
 
 \section{Refereeing}
 
-\begin{cvbody}
-
-\cvitem
-	{2022}
-	{}
-	{Nature Communications}
-	{\vspace{-5pt}}
-	{}{}{}
-	{}
-	{}
-
-\cvitem
-	{2022}
-	{}
-	{Scientific Reports}
-	{}
-	{}{}{}
-	{}
-	{}
-
-\cvitem
-	{2022}
-	{}
-	{Physical Review E}
-	{}
-	{}{}{}
-	{}
-	{}
-
-\cvitem
-	{2022}
-	{}
-	{SciPost}
-	{}
-	{}{}{}
-	{}
-	{}
-
-\end{cvbody}
+\begin{itemize}
+    \item[$\ast$] Nature Communications
+    \item[$\ast$] Scientific Reports
+    \item[$\ast$] Physical Review E
+    \item[$\ast$] SciPost
+\end{itemize}
+\vspace{25pt}
 
 %----------------------------------------------------------------------------------------
 %	 TEACHING
@@ -437,7 +412,7 @@ \section{Responsibilities}
 \cvitem
 	{2023}
 	{Present}
-	{Co-organisation of the ``Smart, Living, and Active Matter'' seminar}
+	{\href{https://slam-leiden.nl}{Co-organisation of the ``Smart, Living, and Active Matter'' seminar}}
 	{Universiteit Leiden \worldflag{NL}\vspace{-5pt}}
 	{}{}{}
     {}

src/publications.bib

@@ -1,14 +1,17 @@
-@article{keta2023emerging,
-  title = {Emerging Mesoscale Flows and Chaotic Advection in Dense Active Matter},
+@article{keta2024emerging,
+  title = {Emerging {{Mesoscale Flows}} and {{Chaotic Advection}} in {{Dense Active Matter}}},
   author = {Keta, Yann-Edwin and Klamser, Juliane U. and Jack, Robert L. and Berthier, Ludovic},
   author+an = {1=highlight},
-  year = {2023},
-  month = jun,
-  number = {arXiv:2306.07172},
-  journal = {arXiv},
-  arxiv = {2306.07172},
-  doi = {10.48550/arXiv.2306.07172},
-  abstract = {We study two models of overdamped self-propelled disks in two dimensions, with and without aligning interactions. Active mesoscale flows leading to chaotic advection emerge in both models in the homogeneous dense fluid away from dynamical arrest, forming streams and vortices reminiscent of multiscale flow patterns in turbulence. We show that the characteristics of these flows do not depend on the specific details of the active fluids, and result from the competition between crowding effects and persistent propulsions. Our results suggest that dense active fluids present a type of ``active turbulence'' distinct from collective flows reported in other types of active systems.}
+  year = {2024},
+  month = may,
+  journal = {Physical Review Letters},
+  volume = {132},
+  number = {21},
+  pages = {218301},
+  publisher = {American Physical Society},
+  doi = {10.1103/PhysRevLett.132.218301},
+  abstract = {We study two models of overdamped self-propelled disks in two dimensions, with and without aligning interactions. Both models support active mesoscale flows, leading to chaotic advection and transport over large length scales in their homogeneous dense fluid states, away from dynamical arrest. They form streams and vortices reminiscent of multiscale flow patterns in turbulence. We show that the characteristics of these flows do not depend on the specific details of the active fluids, and result from the competition between crowding effects and persistent propulsions. This observation suggests that dense active suspensions of self-propelled particles present a type of “active turbulence” distinct from collective flows reported in other types of active systems.},
+  arxiv = {2306.07172}
 }
 
 @article{ADD,