dcni@cua.uam.mx +52 (55) 5814 6534

Dr. Guillermo Chacón AcostaDEPARTAMENTO DE MATEMATICAS APLICADAS Y SISTEMAS

Resumen Curricular

<p><u>EDUCACI&Oacute;N</u></p> <ul> <li>Doctorado en Ciencias (F&iacute;sica) en la Universidad Aut&oacute;noma Metropolitana Unidad Iztapalapa (2011).</li> <li>Maestr&iacute;a en Ciencias (F&iacute;sica) en la Universidad Aut&oacute;noma Metropolitana Unidad Iztapalapa / Universidad Federal de Paran&aacute; Brasil (2007).</li> <li>Licenciatura en F&iacute;sica en la Universidad Aut&oacute;noma Metropolitana Unidad Iztapalapa (2005).</li> </ul> <p><u>EXPERIENCIA</u></p> <p style="margin-left:0cm; margin-right:0cm; text-align:justify">Cargos desempe&ntilde;ados y otros puestos:</p> <ul> <li>Miembro de la comisi&oacute;n dictaminadora divisional DCNI 2023-.</li> <li>Representante Acad&eacute;mico Suplente del DMAS ante el Consejo Divisional para el periodo 2019-2021.</li> <li>Miembro de la comisi&oacute;n acad&eacute;mica del Posgrado en Ciencias Naturales e Ingenier&iacute;a desde 2018.</li> <li><strong>Coordinador del Posgrado en Ciencias Naturales e Ingenier&iacute;a de la Divisi&oacute;n de Ciencias Naturales e Ingenier&iacute;a de la Unidad Cuajimalpa de la Universidad Aut&oacute;noma Metropolitana, a partir del 16 de septiembre de 2015 hasta 2018</strong></li> <li>Miembro de la mesa directiva de la Divisi&oacute;n de Gravitaci&oacute;n y F&iacute;sica Matem&aacute;tica, como tesorero, para el periodo 2015-2017.</li> <li>Representante Acad&eacute;mico Suplente del DMAS ante el Consejo Divisional para el periodo 2015-2016.</li> <li>Responsable del cuerpo acad&eacute;mico de F&iacute;sica-Matem&aacute;tica de PROMEP del 18 de junio de 2013 al 6 de julio de 2015.</li> </ul> <p>Distinciones</p> <ul> <li>SNII Nivel II de 2024-2029</li> <li>Perfil deseable PRODEP 2022-2025</li> </ul> <p>Estancias y cursos</p> <ul> <li>Instituto de F&iacute;sica y Astronom&iacute;a de la Universidad de Potsdam, Alemania. Estancia sab&aacute;tica con el Dr. Ralf Metzler (2022).</li> <li>Departamento dde f&iacute;sica de la Universidad de Barcelona, Espa&ntilde;a. Visita de investigaci&oacute;n con el Dr. Miguel Rub&iacute; (2022).</li> <li>Curso en l&iacute;nea &ldquo;Introducci&oacute;n a la facilitaci&oacute;n presencial en peque&ntilde;os grupos&rdquo;, Fundaci&oacute;n Carlos Slim (2019).</li> <li>Curso en l&iacute;nea &ldquo;Derechos Humanos y G&eacute;nero&rdquo;, Comision Nacional de los Derechos Humanos (2019).</li> <li>&quot;A short introduction to First-Passage Processes and some biological implictions&quot;, por Sidney Redner en UACM Campus del Valle, (2015).</li> <li>CIMAT, con el Dr. Victor P&eacute;rez Abreu (2011).</li> <li>Facultad de Ingenier&iacute;a de la UACHa, con el Dr. H&eacute;ctor Hugo Hern&aacute;ndez Hern&aacute;ndez (2011).</li> <li>The Institute for Gravitation and The Cosmos of The Pennsylvannia State University, con el Dr. Martin Bojowald (2010).</li> <li>Instituto de Matem&aacute;ticas UNAM Campus Morelia, con el Dr. Alejandro Corichi (2010).</li> <li>Universidad Johannes Gutenberg en Mainz, Alemania, con el Dr. Martin Reuter (2008).</li> <li>Universidad Federal de Paran&aacute; en Curitiba, Brasil, con el Dr. Gilberto M. Kremer (2006).</li> </ul> <p>Experiencia Docente</p> <ul> <li>Profesor Titular C, por tiempo indeterminado UAM-Cuajimalpa desde 2014.</li> <li>Profesor visitante A UAM-Cuajimalpa 2011-2014.</li> <li>Profesor de Asignatura en la Universidad Iberoamericana Departamento de F&iacute;sica y Matem&aacute;ticas de 2009 a 2010.</li> <li>Profesor ayudante de cursos de F&iacute;sica en la Universidad Aut&oacute;noma Metropolitana-Iztapalapa<strong> </strong>2004-2007.&nbsp;</li> </ul> <p><u>P&Aacute;GINAS EXTERNAS</u>:</p> <p>https://scholar.google.com.mx/citations?user=2CovOF8AAAAJ&amp;hl=es&amp;oi=ao</p> <p>https://www.researchgate.net/profile/Guillermo_Chacon-Acosta</p> <p>https://orcid.org/0000-0002-7213-7386</p> <p style="margin-left:0cm; margin-right:0cm"><a href="https://sciprofiles.com/profile/gchacon_uamc" style="color:blue; text-decoration:underline">https://sciprofiles.com/profile/gchacon_uamc</a></p>

Área de interés/experiencia en investigación

<p>F&iacute;sica estad&iacute;stica,&nbsp;Teor&iacute;a cin&eacute;tica de los gases, Teor&iacute;a de la difusi&oacute;n</p> <ul> <li>Procesos de difusi&oacute;n en sistemas confinados, superficies curvas y redes complejas</li> <li>Procesos de reacci&oacute;n-difusion y patrones de Turing</li> <li>Teor&iacute;a cin&eacute;tica y f&iacute;sica estad&iacute;stica de sistemas relativistas</li> <li>Procesos con reinicio estoc&aacute;stico</li> <li>Difusi&oacute;n an&oacute;mala y transitoria, c&aacute;lculo fraccionario</li> <li>Particulas activas</li> <li>Econof&iacute;sica. Modelos de agentes intercambiarios para la distribuci&oacute;n de la riqueza</li> <li>Ecuaci&oacute;n de Black-Scholes para el valor de opciones financieras</li> <li>Aproximaci&oacute;n semicl&aacute;sica de la Mec&aacute;nica cu&aacute;ntica en t&eacute;rminos de momentos estad&iacute;sticos</li> <li>Termoestad&iacute;stica de sistemas cu&aacute;nticos polim&eacute;ricos para la fenomenolog&iacute;a de la&nbsp;cuantizaci&oacute;n por lazos de la gravedad.</li> </ul> <p>&nbsp;</p>

Publicaciones en Revistas

<ol> <li>Guillermo Chac&oacute;n-Acosta, Alejandro Le&oacute;n-Ram&iacute;rez, Oswaldo Gonz&aacute;lez-Gaxiola, &quot;<strong>Biharmonic Fick-Jacobs diffusion in narrow channels</strong>,&quot; Physica A, 628 (2023).&nbsp;https://doi.org/10.1016/j.physa.2023.129155</li> <li>J. F&eacute;lix Salazar, A. L. Garc&iacute;a-Perciante, A. R. M&eacute;ndez, G. Chac&oacute;n-Acosta, &quot;<strong>Stability Analysis of a Self-Gravitating Fluid within EIT Theory</strong>,&quot; Universe, 339, (2023).&nbsp;https://doi.org/10.3390/ universe9070339</li> <li>A. Le&oacute;n-Ram&iacute;rez, O. Gonz&aacute;lez-Gaxiola, G. Chac&oacute;n-Acosta, &ldquo;<strong>Analytical Solutions to the Chavy-Waddy&ndash;Kolokolnikov Model of Bacterial Aggregates in Phototaxis by Three Integration Schemes,</strong>&rdquo; Mathematics, 11, 2352 (2023). <a href="https://doi.org/10.3390/math11102352" style="color:blue; text-decoration:underline">https://doi.org/10.3390/math11102352</a></li> <li>A. Ledesma-Dur&aacute;n, D. A. Le&oacute;n-Velasco, G. Chac&oacute;n-Acosta, and L. H. Ju&aacute;rez-Valencia, &ldquo;<strong>Surface diffusion in narrow channels on curved domains</strong>&rdquo;, Phys. Rev. E, 107, 034801 (2023). DOI: 10.1103/PhysRevE.107.034801</li> <li>J. Cervantes-Ojeda, M. G&oacute;mez-Fuentes, G. Chac&oacute;n-Acosta, &ldquo;<strong>Can non-developers learn a simplified modeling notation quickly?</strong>&rdquo; J. Softw. Evol. Proc. e2841 (2022) https://doi.org/10.1002/smr.2481</li> <li>O. Gonz&aacute;lez-Gaxiola, A. Le&oacute;n-Ram&iacute;rez, G. Chac&oacute;n-Acosta, &ldquo;<strong>Application of the Kudryashov Method for Finding Exact Solutions of the Schamel-Kawahara Equation</strong>&rdquo; Rus. J. Nonlin. Dyn., 18, 203-215 (2022). DOI: 10.20537/nd220204</li> <li>E. Castellanos, G. Chac&oacute;n-Acosta, J. Mastache, &ldquo;<strong>Non-relativistic stars as N-body quantum systems</strong>&rdquo;, International Journal of Modern Physics D (IJMPD), 31 No. 7, 2250050 (2022) <a href="https://doi.org/10.1142/S021827182250050X" style="color:blue; text-decoration:underline">https://doi.org/10.1142/S021827182250050X</a></li> <li>Mayra N&uacute;&ntilde;ez-L&oacute;pez, Guillermo Chac&oacute;n-Acosta, &ldquo;<strong>Pattern formation in a predator-prey system with finite interaction range in a channel-like region using the Fick-Jacobs diffusion approach</strong>&rdquo;, Phys. D 433, 133194 (2022). <a href="https://doi.org/10.1016/j.physd.2022.133194" style="color:blue; text-decoration:underline" title="Persistent link using digital object identifier">https://doi.org/10.1016/j.physd.2022.133194</a></li> <li>A. R. M&eacute;ndez, A. L. Garc&iacute;a-Perciante, G. Chac&oacute;n-Acosta, &ldquo;<strong>Dissipative properties of degenerate relativistic gases: The complete kernel calculation in a (d+1) flat space-time</strong>&rdquo;, J. Stat. Phys. 186, 39, 1-26, (2022). https://doi.org/10.1007/s10955-022-02883-w</li> <li>G. Chac&oacute;n-Acosta and R. O. Salas, &ldquo;<strong>Projection of the two-dimensional Black-Scholes equation for options with underlying stock and strike prices in two different currencies</strong>&rdquo;, Rev. Mex. F&iacute;s. 68 011401 (2022).&nbsp; <a href="https://doi.org/10.31349/RevMexFis.68.011401" style="color:blue; text-decoration:underline">https://doi.org/10.31349/RevMexFis.68.011401</a></li> <li>M. N&uacute;&ntilde;ez-L&oacute;pez, G. Chac&oacute;n-Acosta, &ldquo;<strong>Influencia de la curvatura en la formaci&oacute;n de patrones: el mecanismo de Turing en el c&iacute;rculo</strong>&rdquo;, P&Auml;DI Bolet&iacute;n cient&iacute;fico de Ciencias B&aacute;sicas e Ingenier&iacute;as del ICBI 10, 42 (2022). <a href="https://doi.org/10.29057/icbi.v10iEspecial.8411" style="color:blue; text-decoration:underline">https://doi.org/10.29057/icbi.v10iEspecial.8411 </a></li> <li>G. Chac&oacute;n-Acosta and Angel Garcia-Chung, &ldquo;<strong>The relation between the symplectic group SP(4,R) and its Lie algebra: Applications to polymer quantum mechanics</strong>&rdquo;, Phys. Rev. D, 104, 126006 (2021). DOI: 10.1103/PhysRevD.104.126006</li> <li>D. Assaely Le&oacute;n-Velasco and Guillermo Chac&oacute;n-Acosta, &ldquo;<strong>Full finite element scheme for reaction-diffusion systems on embedded curved surfaces in R<sup>3</sup></strong>&rdquo;,&nbsp; Adv. Math. Phys. Vol. 2021 Article ID 8898484, (2021). <a href="https://doi.org/10.1155/2021/8898484" style="color:blue; text-decoration:underline">https://doi.org/10.1155/2021/8898484</a></li> <li>G. Chac&oacute;n-Acosta and V. &Aacute;ngeles-S&aacute;nchez, &ldquo;<strong>Effect of savings on a gas-like model economy with credit and debt</strong>&rdquo;, Entropy 23, 196 (2021). https://www.mdpi.com/1099-4300/23/2/196</li> <li>A. R. M&eacute;ndez, A. L. Garc&iacute;a-Perciante, G. Chac&oacute;n-Acosta, &ldquo;<strong>Dissipation in 2D degenerate gases with non-vanishing rest mass</strong>&rdquo;, Physica A 567, 125693 (2021); <a href="https://doi.org/10.1063/1.5128510" style="color:blue; text-decoration:underline">https://doi.org/10.1016/j.physa.2020.125693</a></li> <li>G. Chac&oacute;n-Acosta, H. H. Hern&aacute;ndez-Hern&aacute;ndez, M. Vel&aacute;zquez,<strong>&ldquo;Effective dynamics of the quantum falling particle&rdquo;</strong>, Eur. J. Phys. 42, 015404 (2021). <a href="https://doi.org/10.1088/1361-6404/abc13a" style="color:blue; text-decoration:underline">https://doi.org/10.1088/1361-6404/abc13a</a></li> <li>L. Arag&oacute;n-Mu&ntilde;oz, G. Chac&oacute;n-Acosta, H. Hernandez-Hernandez <strong>&ldquo;Effective quantum tunneling from a semiclassical momentous approach&rdquo;</strong>, (IJMPB) 34, 2050271 (2020). <a href="https:///dx.doi.org/10.1142/S0217979220502719?utm_source=wspc_mail_list&amp;utm_medium=email&amp;utm_campaign=repr_IJMPB_301120" style="color:blue; text-decoration:underline">https:///dx.doi.org/10.1142/S0217979220502719</a></li> <li>G. Chac&oacute;n-Acosta, M. N&uacute;&ntilde;ez-L&oacute;pez, I. Pineda, <strong>&ldquo;Turing instability conditions in confined systems with an effective position-dependent diffusion coefficient&rdquo;</strong>, J. Chem. Phys. 152, 024101 (2020); <a href="https://doi.org/10.1063/1.5128510" style="color:blue; text-decoration:underline">https://doi.org/10.1063/1.5128510</a></li> <li>A. R. M&eacute;ndez, A. L. Garc&iacute;a-Perciante, G. Chac&oacute;n-Acosta, <strong>&ldquo;Thermal Dissipation in Two Dimensional Relativistic Fermi Gases with a Relaxation Time Model&rdquo;</strong>, J. Stat. Phys. 178, 936-953 (2020); <a href="https://doi.org/10.1007/s10955-019-02473-3" style="color:blue; text-decoration:underline">https://doi.org/10.1007/s10955-019-02473-3</a></li> <li>J. A. Santiago, G. Chac&oacute;n-Acosta, F. Monroy, <strong>&ldquo;Membrane stress and torque induced by Frank&rsquo;s nematic textures: A geometric perspective using surface-based constraints&rdquo;</strong>, Phys. Rev. E 100, 012704 (2019).</li> <li>O. Gonz&aacute;lez-Gaxiola, G. Chac&oacute;n-Acosta, A. Le&oacute;n-Ram&iacute;rez, <strong>&ldquo;Approximate analytical solution of the nonlinear Bethe equation&rdquo;</strong>. Int. J. Appl. Comput. Math. 5: 25, (2019).</li> <li>Yoshua Ch&aacute;vez, Guillermo Chac&oacute;n-Acosta and Leonardo Dagdug, &ldquo;<strong>Unbiased diffusion of Brownian particles in a helical tube</strong>&rdquo;. J. Chem. Phys. 148, 214106 (2018). <a href="https://doi.org/10.1063/1.5030892" style="color:blue; text-decoration:underline">https://doi.org/10.1063/1.5030892</a></li> <li>Yoshua Ch&aacute;vez, Guillermo Chac&oacute;n-Acosta and Leonardo Dagdug, &ldquo;<strong>Effects of curved midline and varying width on the description of the effective diffusivity of Brownian particles</strong>&rdquo;. J. Phys.: Condens. Matter, 30, 194001 (2018). <a href="https://doi.org/10.1088/1361-648X/aaba0d" style="color:blue; text-decoration:underline">https://doi.org/10.1088/1361-648X/aaba0d</a></li> <li>O. Gonz&aacute;lez-Gaxiola, G. Chac&oacute;n-Acosta and J. A. Santiago,&nbsp; <strong><em>&ldquo;Nonlinear oscillations of a point charge in the electric field of charged ring using a particular He&#39;s frequency-amplitude formulation&rdquo;</em></strong> Int. J. Appl. Comput. Math. <strong>4</strong>, 43 (2018).</li> <li>E. Castellanos, G. Chac&oacute;n-Acosta, H&eacute;ctor H. Hern&aacute;ndez-Hern&aacute;ndez and E. Santos, <strong><em>&ldquo;Polymer quantization in the Bogoliubov&rsquo;s regime for a homogeneous one-dimensional Bose-Einstein condensate&rdquo;</em></strong>, Int. J. Theor. Phys.<strong> 57</strong>, 74-82, (2018), <a href="https://doi.org/10.1007/s10773-017-3542-0">https://doi.org/10.1007/s10773-017-3542-0</a></li> <li>G. Barrientos, G. Chac&oacute;n-Acosta, O. Gonz&aacute;lez-Gaxiola and J. A. Santiago, <strong><em>&ldquo;Forces on membranes with in-plane order&rdquo;,</em></strong> J. Phys. Commun. <strong>1</strong>, 045017 (2017), <a href="https://doi.org/10.1088/2399-6528/aa90cd">https://doi.org/10.1088/2399-6528/aa90cd</a></li> <li>M. N&uacute;&ntilde;ez-L&oacute;pez, G. Chac&oacute;n-Acosta, J. A. Santiago,<strong><em>&ldquo;Diffusion-Driven Instability on a curved surface: spherical case revisited&rdquo;</em></strong>&nbsp;Braz. J. Phys.&nbsp;<strong>47</strong>, 231-238 (2017).&nbsp;<span style="background-color:#fcfcfc; font-family:'Source Sans Pro',Helvetica,Arial,sans-serif; font-size:14px">doi:10.1007/s13538-017-0487-y</span></li> <li>J. A. Santiago, G. Chac&oacute;n-Acosta, O. Gonz&aacute;lez-Gaxiola, G. Torres-Vargas, <strong><em>&ldquo;Geometry of classical particles on curved surfaces&rdquo;</em></strong> Rev. Mex. F&iacute;s. <strong>63</strong>, 26-31 (2017).</li> <li>L. Dagdug, A.A. Garc&iacute;a-Chung and G. Chac&oacute;n-Acosta, <strong><em>&ldquo;On the description of Brownian particles in confinement on an non-Cartesian coordinate basis&rdquo;</em></strong>. J. Chem. Phys. <strong>145</strong> 074105 (2016).</li> <li>G. Chac&oacute;n-Acosta and H. H. Hern&aacute;ndez-Hern&aacute;ndez, <strong><em>&ldquo;Polymer quantum effects on compact stars models&rdquo;</em></strong>. International Journal of Modern Physics D (IJMPD) <strong>24</strong>, 1550033 (2015).</li> <li>A. A. Garc&iacute;a-Chung, Guillermo Chac&oacute;n-Acosta, and L. Dagdug, <strong><em>&ldquo;On the covariant description of diffusion in two-dimensional confined environments&rdquo;</em></strong>. J. Chem. Phys. <strong>142</strong> 064105 (2015).</li> <li>I. Pineda, G. Chac&oacute;n-Acosta, L. Dagdug, <strong><em>&ldquo;Diffusion coefficients for two-dimensional narrow asymmetric channels embedded on flat and curved surfaces&rdquo;</em></strong>, Eur. Phys. J. Special Topics <strong>223</strong>, 3045 (2014).</li> <li>Y. Ch&aacute;vez, G. Chac&oacute;n-Acosta, M.-V. V&aacute;zquez, and L. Dagdug, <strong><em>&ldquo;Unbiased diffusion to escape complex geometries: Is reduction to effective one-dimensional description adequate to&nbsp;assess narrow escape times?&rdquo;</em></strong> Applied Mathematics <strong>5</strong>, 1218-1225 (2014).</li> <li>G. Chac&oacute;n-Acosta, I. Pineda and L. Dagdug <strong>&ldquo;<em>Diffusion in narrow channels on curved manifolds&rdquo;</em></strong> J. Chem. Phys. <strong>139</strong> 214115 (2013).</li> <li>G. Chac&oacute;n-Acosta and H. H. Hern&aacute;ndez, <strong>&ldquo;<em>Effective description of the quantum Kepler problem&rdquo;</em></strong> Quantum Matter <strong>2</strong>, 364 (2013).</li> <li>O. Gonz&aacute;lez-Gaxiola, J. A. Santiago and G. Chac&oacute;n-Acosta, <strong><em>&ldquo;A solvable QSDE through semigroups of operators and some physical applications&rdquo;</em></strong> International Journal of Pure and Applied Mathematics (IJPAM), <strong>85</strong>, 669 (2013).</li> <li>B. S&aacute;nchez-Rey, G. Chac&oacute;n-Acosta, L. Dagdug and D. Cubero, <strong>&ldquo;<em>Thermal equilibrium in Einstein&#39;s Elevator&rdquo;</em></strong>, Phys. Rev. E <strong>87</strong> 052121 (2013).</li> <li>J. A. Santiago, G. Chac&oacute;n-Acosta and O. Gonz&aacute;lez-Gaxiola, <strong><em>&ldquo;Elastic curves and Surfaces under long-range forces: A geometric approach&rdquo;</em></strong>. International Journal of Modern Physics B (IJMPB) <strong>27</strong>, 1350043 (2013).</li> <li>E. Castellanos and G. Chac&oacute;n-Acosta, <strong>&ldquo;<em>Polymer Bose--Einstein Condensates&rdquo;</em></strong>, Phys. Lett. B <strong>722</strong>, 119 (2013).</li> <li>J. M. Romero, O. Gonz&aacute;lez-Gaxiola and G. Chac&oacute;n-Acosta, <strong>&ldquo;<em>Exact solutions to Fick-Jacobs equation&rdquo; </em></strong>International Journal of Pure and Applied Mathematics (IJPAM), <strong>82</strong>, 41 (2013).</li> <li>G. Chac&oacute;n-Acosta <strong>&ldquo;</strong><strong><em>Cien a&ntilde;os de la funci&oacute;n de distribuci&oacute;n de J&uuml;ttner para el gas relativista</em></strong><strong><em>&rdquo;</em></strong><strong>,</strong> Rev. Mex. F&iacute;s. <strong>58</strong>, 117-126 (2012).</li> <li>G. Chac&oacute;n-Acosta, E. Manrique, L. Dagdug and H. A. Morales-T&eacute;cotl, <strong><em>&ldquo;Statistical Thermodynamics of Polymer Quantum Systems&rdquo;</em></strong>, Symmetry, Integrability and Geometry: Methods and Applications (SIGMA) <strong>7,</strong> 110 (2011).</li> <li>G. Chac&oacute;n-Acosta, L. Dagdug and H. Morales-T&eacute;cotl, <strong>&ldquo;<em>Manifestly covariant J&uuml;ttner distribution and equipartition theorem&rdquo;</em>,</strong> Phys. Rev. E <strong>81</strong>, 021126 (2010).</li> <li>G. Chac&oacute;n-Acosta and G. M. Kremer, <strong>&ldquo;<em>Fokker-Planck-type equations for a simple gas and for a semirelativistic Brownian motion from a relativistic kinetic theory&rdquo;</em>,</strong> Phys. Rev. E <strong>76</strong>, 021201 (2007).</li> </ol>

Memorias de Congreso

<ul> <li>G. Chac&oacute;n-Acosta and M. N&uacute;&ntilde;ez-L&oacute;pez, &ldquo;<strong>Patterns Formation in a Prey-predator System with finite interaction length and space-dependent diffusivity in confined enviroments</strong>&rdquo;, pp. 44-47 of Proceedings of the 14th Conference of the Society of Physicists of Macedonia. Eds. I. Petreska, et al.&nbsp; (2023).</li> <li>G. Chac&oacute;n-Acosta and M. N&uacute;&ntilde;ez-L&oacute;pez, &ldquo;<strong>Patterns in a Time-Fractional Predator&ndash;Prey System with Finite Interaction Range</strong>&rdquo;, Proceedings of the 5th Mexican Workshop on Fractional Calculus. Comput. Sci. Math. Forum, 4, 3 (2022). <a href="https://sae.uam.mx/saa/php/detalle_act.php?movimiento=M&amp;seleccion=1&amp;grados=0&amp;sel_rubro=&amp;inicio_fe=&amp;fin_fe=&amp;rubroact=465X1.2.1.3&amp;edo_act_cl=0" style="color:blue; text-decoration:underline">https://doi.org/10.3390/cmsf2022004003</a></li> <li>L. Arag&oacute;n-Mu&ntilde;oz and G. Chac&oacute;n-Acosta, &ldquo;<strong>Modified relativistic J&uuml;ttner-like distribution functions with \eta-parameter</strong>&rdquo;, XI Workshop of the Gravitation and Mathematical Physics Division of the Mexican Physical Society, J. Phys.: Conf. Ser. 1030, 012004 (2018).</li> <li>G. Chac&oacute;n-Acosta, M. N&uacute;&ntilde;ez-L&oacute;pez and J. A. Santiago, <strong><em>&ldquo;Curvature effects on a simplified reaction-diffusion model of biodegradation&rdquo;</em>,</strong> <em>Proceedings of Diffusion Fundamentals VII.</em> diffusion-fundamentals.org <strong>30</strong>, 5 pp. 1-7 (2017).</li> <li>G. Chac&oacute;n-Acosta, <strong><em>&ldquo;Equilibrium and non-equilibrium properties of a relativistic gas at the transition temperature&rdquo;</em>,</strong> <em>30<sup>th</sup> International symposium on Rarified Gas Dynamics</em>, AIP Conf. Proc. <strong>1786</strong>, 070016 (2016).</li> <li>G. Chac&oacute;n-Acosta, A. A. Garc&iacute;a-Chung and H. H. Hernandez-Hernandez, <strong><em>&ldquo;Thermal properties for an ensamble of polymer Fermi oscillators&rdquo;</em></strong><strong>,</strong>&nbsp;J. Phys.: Conf. Ser. <strong>654</strong>, 012002 (2015).</li> <li>M. Romero-Mu&ntilde;oz, L. Dagdug and G. Chac&oacute;n-Acosta <strong><em>&ldquo;Vanishing condition for the heat flux and slow evolution of a spherically fluid distribution&rdquo;</em></strong><strong>,</strong>&nbsp;J. Phys.: Conf. Ser. <strong>582</strong>, 012044 (2015).</li> <li>M. Romero-Mu&ntilde;oz, L. Dagdug and G. Chac&oacute;n-Acosta <strong><em>&ldquo;Vanishing condition for the heat flux of a relativistic fluid in a moving frame&rdquo;</em></strong><strong>,</strong>&nbsp;J. Phys.: Conf. Ser. <strong>545</strong>, 012012 (2014).</li> <li>J. A. Santiago, G. Chac&oacute;n-Acosta and O. Gonz&aacute;lez-Gaxiola, <strong><em>&ldquo;Effective potentials in geodesic curves on surfaces&rdquo;</em></strong><strong>,</strong><em> </em>J. Phys.: Conf. Ser. <strong>545</strong>, 012014 (2014).</li> <li>G. Chac&oacute;n-Acosta, I. Pineda and L. Dagdug, <strong><em>&ldquo;Effective One-dimensional Diffusion on Curved Surfaces: Catenoid and Pseudosphere&rdquo;</em>,</strong>&nbsp;AIP Conf. Proc. <strong>1579</strong>, 112 (2014).</li> <li>A. R. M&eacute;ndez, G. Chac&oacute;n-Acosta and A. L. Garc&iacute;a-Perciante, <strong><em>&ldquo;Two temperature gas equilibration with a Fokker-Planck type collision operator&rdquo;</em>,</strong> AIP Conf. Proc. <strong>1578</strong>, 110-113 (2014).</li> <li>G. Chac&oacute;n-Acosta, I. Pineda and L. Dagdug, <strong><em>&ldquo;Projection of two-dimensional diffusion in a curved midline and narrow varying width channel embedded on a curved surface&rdquo;</em>,</strong> diffusion-fundamentals.org <strong>20</strong>, 110 pp 1-8 (2013).</li> <li>G. Chac&oacute;n-Acosta and H&eacute;ctor H. Hern&aacute;ndez, <strong><em>&ldquo;One-dimensional polymer Fermi gas at zero temperature&rdquo;</em>,</strong>&nbsp;AIP Conf. Proc. <strong>1548</strong>, 179-182 (2013).</li> <li>G. Chac&oacute;n-Acosta, <strong><em>&ldquo;Thermostatistics of a polymer gas of hydrogen atoms&rdquo;</em>,</strong>&nbsp;AIP Conf. Proc. <strong>1473</strong>, 153 (2012).</li> <li>H&eacute;ctor H. Hern&aacute;ndez and G. Chac&oacute;n-Acosta, <strong><em>&ldquo;Effective equations for the quantum pendulum and loop quantization&rdquo;</em>,</strong> AIP Conf. Proc. <strong>1473</strong>, 168 (2012).</li> <li>G. Chac&oacute;n-Acosta, L. Dagdug and H. Morales-T&eacute;cotl, <strong><em>&ldquo;On microstates counting in many body polymer quantum systems&rdquo;</em>,</strong>&nbsp;AIP Conf. Proc. <strong>1396</strong>, pp. 99-103 (2011).</li> <li>G. Chac&oacute;n-Acosta, L. Dagdug and H. Morales-T&eacute;cotl, <strong><em>&ldquo;</em></strong><strong><em>A covariant Fokker-Planck equation for a simple gas from relativistic kinetic theory</em></strong><strong><em>&rdquo;</em></strong>,&nbsp;AIP Conf. Proc. <strong>1312</strong>, 73-79 (2010).</li> <li>G. Chac&oacute;n-Acosta, L. Dagdug and H. Morales-T&eacute;cotl, <strong><em>&ldquo;Relativistic Momentum and Manifestly Covariant Equipartition Theorem Revisited&rdquo;</em></strong><em>,</em> AIP Conf. Proc. <strong>1256</strong>, 231-238 (2010).</li> </ul>

Capítulos en Libros

<ul> <li>&ldquo;<strong>XI Mexican School on Gravitation and Mathematical Physics, Quantum Gravity: schemes, models and phenomenology</strong>&rdquo;, Hector Hernandez, Guillermo Chac&oacute;n and Miguel Sabido (Eds.). J. Phys. Conf. Series. <strong>1030</strong> (2018).</li> <li>&ldquo;<strong>XI Workshop of the Gravitation and Mathematical Physics Division of the Mexican Physical Society</strong>&rdquo;, Hector Hernandez, Guillermo Chac&oacute;n and Miguel Sabido (Eds.). J. Phys. Conf. Series. <strong>1010</strong> (2018).</li> <li><strong><em>&ldquo;</em></strong><strong><em>Plasma Physics</em></strong><strong><em> and relativistic fluids. </em></strong><strong><em>V Leopoldo Garc&iacute;a-Col&iacute;n&rsquo;s Mexican Meeting on Mathematical and Experimental Physics&rdquo;</em></strong><strong><em>,</em></strong> Guillermo Chac&oacute;n-Acosta, A. L. Garc&iacute;a-Perciante, A. Sandoval-Villalbazo. AIP Conf. Proc. <strong>1578</strong> (2014). ISBN 978-0-7354-208-8, ISSN 0094-243X.</li> <li><strong><em>&ldquo;100 a&ntilde;os de teor&iacute;a cin&eacute;tica relativista&rdquo;,</em></strong> Leopoldo Garc&iacute;a-Col&iacute;n Scherer, Guillermo Chac&oacute;n Acosta y Leonardo Dagdug Lima, Universidad Aut&oacute;noma Metropolitana Unidad (2013). ISBN 978-607-477-903-5.</li> </ul> <p>&nbsp;</p>

Libros

<ul> <li>&ldquo;<strong>XI Mexican School on Gravitation and Mathematical Physics, Quantum Gravity: schemes, models and phenomenology</strong>&rdquo;, Hector Hernandez, Guillermo Chac&oacute;n and Miguel Sabido (Eds.). J. Phys. Conf. Series. <strong>1030</strong> (2018).</li> <li>&ldquo;<strong>XI Workshop of the Gravitation and Mathematical Physics Division of the Mexican Physical Society</strong>&rdquo;, Hector Hernandez, Guillermo Chac&oacute;n and Miguel Sabido (Eds.). J. Phys. Conf. Series. <strong>1010</strong> (2018).</li> <li><strong><em>&ldquo;</em></strong><strong><em>Plasma Physics</em></strong><strong><em> and relativistic fluids. </em></strong><strong><em>V Leopoldo Garc&iacute;a-Col&iacute;n&rsquo;s Mexican Meeting on Mathematical and Experimental Physics&rdquo;</em></strong><strong><em>,</em></strong> Guillermo Chac&oacute;n-Acosta, A. L. Garc&iacute;a-Perciante, A. Sandoval-Villalbazo. AIP Conf. Proc. <strong>1578</strong> (2014). ISBN 978-0-7354-208-8, ISSN 0094-243X.</li> <li><strong><em>&ldquo;100 a&ntilde;os de teor&iacute;a cin&eacute;tica relativista&rdquo;,</em></strong> Leopoldo Garc&iacute;a-Col&iacute;n Scherer, Guillermo Chac&oacute;n Acosta y Leonardo Dagdug Lima, Universidad Aut&oacute;noma Metropolitana Unidad (2013). ISBN 978-607-477-903-5.</li> </ul> <p>&nbsp;</p>

Formación de Recursos Humanos

<ul> <li>Proyecto Terminal de &Aacute;ngel David Del Valle&nbsp;sobre <strong>Reseteo estoc&aacute;stico finito para el movimiento browniano geom&eacute;trico</strong>, DMAS, UAM-Cuajimalpa (2023).</li> <li>Proyecto Terminal de Gabriel Guti&eacute;rrez sobre <strong>Modelos Cin&eacute;ticos para medir la Desigualdad</strong>, DMAS, UAM-Cuajimalpa (2022).</li> <li>Proyecto Terminal de Samara Guadalupe Valle Villar sobre <strong>Efecto en las velocidades de propagaci&oacute;n finitas en la ecuaci&oacute;n de Black-Scholes para una opci&oacute;n financiera</strong>, DMAS, UAM-Cuajimalpa (2021).</li> <li>Proyecto Terminal de Arianna Dinorah Solano Eleuterio sobre <strong>Efectos geom&eacute;tricos en la ecuaci&oacute;n de Black-Scholes</strong>, DMAS, UAM-Cuajimalpa (2021).</li> <li>Proyecto Terminal de Marcos Guerrero Morales, sobre <strong>Condensados de Bose-Einstein para modelar opciones financieras</strong>, DMAS, UAM-Cuajimalpa (2021).</li> <li>Proyecto Terminal de Danae Sarah&iacute; Gal&aacute;n Covarrubias, sobre <strong>El efecto de un operador de difusi&oacute;n fraccionario en la ecuaci&oacute;n de Black-Scholes</strong>, DMAS, UAM-Cuajimalpa (2021).</li> <li>Proyecto Terminal junto con Diana Assaely Le&oacute;n de Mar&iacute;a Guadalupe P&eacute;rez Hern&aacute;ndez, sobre <strong>Modelo bidimensional de un tumor con la ecuaci&oacute;n de Fisher-Kolmogorov</strong>, DMAS, UAM-Cuajimalpa (2021).</li> <li>Proyecto Terminal junto con Diana Assaely Le&oacute;n de Oscar Iv&aacute;n Rivera Montiel, sobre <strong>Modelos epidemiol&oacute;gicos basados en ecuaciones diferenciales</strong>, DMAS, UAM-Cuajimalpa (2021).</li> <li>Proyecto de Servicio Social de Mar&iacute;a Guadalupe P&eacute;rez Hern&aacute;ndez y &Aacute;lvaro Y&aacute;&ntilde;ez Hern&aacute;ndez, titulado <strong>Modelos probabil&iacute;sticos gr&aacute;ficos</strong>, DMAS, UAM - Cuajimalpa (2020).</li> <li>Proyecto de Servicio Social de H&eacute;ctor Vilchis Peralta, titulado <strong>Estudio de la difusi&oacute;n con reinicio como caso particular en las UEA&rsquo;s de C&aacute;lculo Estoc&aacute;stico y Procesos Estoc&aacute;sticos en F&iacute;sica</strong>, DMAS, UAM - Cuajimalpa (2020).</li> <li>Proyecto Terminal junto con Juli&aacute;n Fres&aacute;n de Vianey Tenorio, sobre <strong>Formaci&oacute;n de patrones a trav&eacute;s del mec&aacute;nismo reacci&oacute;n-difusi&oacute;n de Turing en gr&aacute;ficas completas</strong>, DMAS, UAM-Cuajimalpa (2020). Este proyecto fue acreedor al Diploma a la investigaci&oacute;n 2020.</li> <li>Proyecto de Servicio Social de Marco Antonio &Aacute;lvarez Carrillo y Sof&iacute;a Fabi&aacute;n Guti&eacute;rrez, titulado <strong>Estad&iacute;stica Bayesiana</strong>, DMAS, UAM - Cuajimalpa (2020).</li> <li>Proyecto Terminal de Miguel &Aacute;ngel Mendoza Huitr&oacute;n y Jonathan Osiris Cruz Sierra, sobre <strong>Geometr&iacute;a de superficies deformadas</strong>, DMAS, UAM-Cuajimalpa (2019).</li> <li>Director de la Tesis de Maestr&iacute;a en Ciencias Econ&oacute;micas&nbsp;de Vanessa &Aacute;ngeles S&aacute;nchez junto con el Dr. Gerardo &Aacute;ngeles Castro, titulada&nbsp;<strong><em>Modelo cin&eacute;tico de agentes intercambiarios para la desigualdad en la distribuci&oacute;n del ingreso en M&eacute;xico</em></strong>, en la Escuela Superior de Econom&iacute;a del Instituto Polit&eacute;cnico Nacional (2019).</li> <li>Proyecto Terminal de Rub&eacute;n O. Salas&nbsp;Castellanos, sobre <strong><em>Proyecci&oacute;n a una dimensi&oacute;n de la ecuaci&oacute;n de Black-Scholes bidimensional para una opci&oacute;n cuyo precio de ejercicio est&aacute; en una divisa distinta a la del activo,&nbsp;</em></strong>DMAS, UAM - Cuajimalpa (2017).</li> <li>Proyecto de Investigaci&oacute;n con Adri&aacute;n P&eacute;rez y Dr. Dami&aacute;n Hern&aacute;ndez Herr&aacute;n (UACM), sobre <strong><em>Efectos de la curvatura en procesos de sub-difusi&oacute;n a tiempos cortos,</em></strong>&nbsp;DMAS, UAM - Cuajimalpa (2017).</li> <li>Tesis de Licenciatura de &nbsp;Luis Fernando Arag&oacute;n Mu&ntilde;oz, sobre <strong><em>Estudio sobre la distribuci&oacute;n de J&uuml;ttner modificada como alternativa para la descripci&oacute;n estad&iacute;stica de fluidos relativistas</em></strong>, en la Universidad Aut&oacute;noma de Chihuahua (2017).</li> <li>Coasesor de la Tesis de Doctorado en Ciencias (F&iacute;sica) de &nbsp;Mart&iacute;n Romero Mu&ntilde;oz, sobre <strong><em>Estudio de las propiedades del vector t&eacute;rmico</em></strong>, en la Universidad Aut&oacute;noma Metropolitana Unidad Iztapalapa (en proceso).</li> <li>Proyecto Terminal de Viviana Garc&iacute;a Le&oacute;n, sobre <strong><em>Ecuaciones Efectivas en Mec&aacute;nica Cu&aacute;ntica,</em></strong> DMAS, UAM - Cuajimalpa (2015).</li> <li>Coasesor de la Tesis de Maestr&iacute;a en Ciencias (F&iacute;sica) de&nbsp;Mart&iacute;n Romero Mu&ntilde;oz, con el t&iacute;tulo: <strong><em>Sobre el flujo de Calor y Tensor de energ&iacute;a momento en un fluido relativista</em></strong>,&nbsp;Universidad Aut&oacute;noma Metropolitana Unidad Iztapalapa (2014).</li> <li>Servicio Social de Vanessa &Aacute;ngeles S&aacute;nchez, sobre <strong><em>Movimiento Browniano en el estudio de la difusi&oacute;n en sistemas biol&oacute;gicos confinados,&nbsp;</em></strong>DMAS, UAM - Cuajimalpa (2014).&nbsp;Este proyecto fue acreedor al Diploma a la investigaci&oacute;n 2014.</li> <li>Proyecto Terminal de Michelle Jacqueline Yllescas Ram&iacute;rez, sobre el estudio del <strong><em>Ensamble relativista para una econom&iacute;a en equilibrio: An&aacute;lisis cr&iacute;tico de la realidad del modelo econof&iacute;sico, </em></strong>DMAS, UAM - Cuajimalpa (2013).</li> <li>Proyecto Terminal de&nbsp;Vanessa &Aacute;ngeles S&aacute;nchez, sobre <strong><em>Ensambles Estad&iacute;sticos para Modelos Econ&oacute;micos con Ingreso, Cr&eacute;dito y Deuda</em></strong>, DMAS, UAM - Cuajimalpa (2013). Este proyecto fue acreedor al Diploma a la investigaci&oacute;n 2013.</li> <li>Proyecto Terminal&nbsp;junto con la Dra. Ana Laura Garc&iacute;a Perciante, de Etelberto V&aacute;zquez Cort&eacute;s, sobre <strong><em>Estudio de un fluido cargado en presencia de un campo electromagn&eacute;tico a trav&eacute;s del formalismo de Kaluza,</em></strong> DMAS, UAM - Cuajimalpa (2013).</li> <li>Servicio Social de Jes&uacute;s Salvador Mendoza Mac&iacute;as, sobre <strong><em>Movimiento Browniano en el estudio de la difusi&oacute;n en sistemas biol&oacute;gicos confinados </em></strong>DMAS, UAM - Cuajimalpa (2012).</li> </ul>

Otra Información de Relevancia Académica

<ul> <li>5 pl&aacute;ticas invitadas</li> <li>25 trabajos en congresos internacionales</li> <li>47 trabajos en congresos nacionales</li> <li>39 trabajos en coloquios, seminarios</li> <li>19 pl&aacute;ticas de divulgaci&oacute;n</li> <li>16 ex&aacute;menes de posgrado</li> <li>Miembro del comit&eacute; organizador de m&aacute;s de 21 eventos nacionales e internacionales</li> <li>Revisor de trabajos en revistas internacionales y nacionales</li> <li>Evaluador en comisiones dictaminadoras</li> <li>Perfil deseable PRODEP</li> <li>Nivel II del Sistema Nacional de Investigadores e Investigadoras</li> </ul> <p>&nbsp;</p>

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