Man

Paul Eduardo David Soto Rodriguez

Postdoc

Aix-Marseille Univeristy

Saint-Paul-lez Durance, Francia

Líneas de Investigación


Crecimiento (epitaxial, químico) y caracterización (magnético, eléctrico, óptico y estructural) de (nano-)materiales para diversas aplicaciones electroquimicas (biosensor, water-spliting, batería y sensor de gases). Construcción de Bacteriabots.

Educación

  •  Ingeniería en Sistemas Electrónicos, UNIVERSIDAD POLITECNICA DE MADRID. España, 2016
  •  Applied Physics, Specialization Functional (Nano-)Materials, Technische Universiteit Eindhoven. Holanda, 2010
  •  Magister en Ciencia en la especialidad de Fisica, UNIVERSIDAD DE SANTIAGO DE CHILE. Chile, 2006
  •  Licenciado en Fisica Aplicada, UNIVERSIDAD DE SANTIAGO DE CHILE. Chile, 2004

Experiencia Académica

  •   Postdoc Full Time

    UNIVERSIDAD COMPLUTENSE DE MADRID

    Quimica

    Madrid, España

    2016 - 2017

  •   Postdoc Full Time

    INSTITUTO DE BIOINGENIERÍA DE CATALUNYA IBEC

    Barcelona, España

    2018 - 2020

  •   Postdoc Full Time

    AIX-MARSEILLE UNIVERSITY

    Institute of Biosciences and Biotechnologies (BIAM)

    Cadarache, Francia

    2020 - A la fecha

Experiencia Profesional

  •   Phd student Full Time

    ISOM

    Madrid, España

    2011 - 2016

  •   Chemist Full Time

    Orion High Technologies S. L.

    Madrid, España

    2017 - 2017

Formación de Capital Humano


________________________________________ REVIEWER EXPERIENCE
Since 2015: Reviewer for the following journals: Scientific Reports, Journal of Luminescence, Electroanalysis, International Journal of Hydrogen Energy, Computational Material Science, Thin Solid films, Journal of Applied Physics, International Journal of Molecular Sciences, Journal of Alloys and Compounds and Crystal Growth & Design, ACS applied energy materials, ACS applied materials & interfaces Sensors, Biosensors, Applied System Innovation, Energies, Materials, Coatings, Nanomaterials, Micromachines, Symmetry.
Topic editor
Since Jan 2021: Topic editor at MDPI “nanomaterials” (IF:3.057)
Guest editor for Frontiers in chemistry, special issue enzyme-based smart Materials (2021) (IF: 5,221)
External Phd report examiner
Ago 2020: Sandra Jiménez Falcao, Complutense University, Madrid, Spain.

COURSES
Oct 2021: First UCA FOX, UCA Fall program on Complex Systems 2021 « Mobility, self-organization and swimming strategies » Nice and Fréjus (France)
April 2018: ALBA SYNCHROTRON de Barcelona, Seminario de Biociencias impartido por Iesmat y Malvern Panalytical sobre técnicas instrumentales aplicadas a Ciencias de la Vida. Workshop on experimental tools for lifesciences offered by Malvern Panalytical.
March 2009: Jülich, Germany, 40th IFF Spring School attendant “Spintronics- From GMR to Quantum Information”.
January 2003: Universidad Técnica Frederico Santa Maria, Chile, mini course attendant at IV Taller de Física: “Sistemas de Baja Dimensionalidad” (Low Dimensional Systems)
January 2003: Universidad Técnica Frederico Santa Maria, Chile, mini course attendant on “An introduction to Nanophysics”
March 2002: Antofagasta, Chile, Mini course attendant “Física de la Materia Condensada” (Physics of condensed materials)

SUPERVISING EXPERIENCE
2022: supervised an Aix-Marseille University (AMU) Master 1 student, Quentin.Desicyhuiez, his internship Project title was:" Magnetotatic bacteria MSR1
Microfluidic synthesis of Janus bacteria"
2021: Co-supervised toether with Dr. Mila Sirinelli an Aix-Marseille University (AMU) Bachelor student, Maximilien, during his internship L3 Biochimie Rouzaud Project title: “Développement d’une bactérie magnéto-robot”
2018-2019: Batx2Lab: Supervised a Highschool student, for the experimental part of the Project” NANODISPOSITIUS PER A LA CURA DEL CÀNCER”
2016: Co-supervised together with Dr. Reynaldo Villalonga a PhD visting student, Zabiholah Zabihi, from Iran (Amirkabir University of Technology)
2014: Together with Dr. Reynaldo Villalonga co-supervised the master thesis of Veronica Calderon, research done in collaboration with the Analytical Chemistry group of Universidad Complutense de Madrid. Thesis title: Propiedades electrocataliticas de nanoestructuras de InGaN para el diseño de biosensores de interés biomédico (Electrocatalytic properties of InGaN nanostructures in biosensor design for biomedical applications).

TEACHING
2022: Plinius PhD course: Microfluidics for Microbiologists
Jul-Oct 2005:High school teacher. I developed outreach activities devoted to high school students under a joint project between Universidad de Santiago de Chile (USACH) and EXPLORA (foundation to foster children's interest in science). In the second stage of the project, I supervised students in developing a brief scientific project.
Apr-Jun 2005: Auxiliary teacher (physics mechanics laboratory). Universidad de Santiago de Chile (USACH), project between the University and EXPLORA foundation. At this first stage of the project, the students (High school) acquired basic lab skills in physics.
2003-2005: Auxiliary Teacher, Universidad de Santiago de Chile. Auxiliary teacher for the course “Topics in physics” offered to industrial engineers.
2001-2005: Lab assistant experimental physics for engineers of several courses at Universidad de Santiago de Chile.
October 2003: Scientific guide in museum. Santiago (Chile), Museo Interactivo Mirador (MIM), EXPLORA foundation (Conycit), collaborating with the exposition “Micro Mundo” (The micro world)
Aug–Nov 2002: Scientific guide in the scientific museum in Santiago (Chile). At the Museo Interactivo Mirador, I worked as a guide in the exposition “Materia Granular” (granular material)


Difusión y Transferencia


Contribuciones a conferencias y
1. Charla invitada "Investigaciones sobre Nanoestructuras de nitruros del grupo III: Aplicaciones en Foto-electrolisis y Bio-Sensores", 30 de Septiembre 2016 en la Facultad de Ciencia de la Universidad de Valparaíso, Chile
2. Charla invitada "Investigaciones sobre Nanoestructuras de nitruros del grupo III: Aplicaciones en Foto-electrolisis y Bio-Sensores", 6 de Octubre 2016 en el Departamento de Fìsica de la Universidad Santiago de Chile, Chile
3. 6th EuCheMS Chemistry Congress, 2016. (Sevilla, España).
Alfredo Sánchez, Paul E.D. Soto-Rodriguez, Gema Luna, Íñigo Fernández, Paula Díez, Paloma Martínez-Ruiz, Prospero Di Pierro, Rafael Porta, Maroua Saadaoui, Susana Campuzano, Noureddine Raouafi, José M. Pingarrón, Reynaldo Villalonga. “Electrochemical biosensors based on mesoporous silica thin films”.
4. International Conference on Solid State Devices and Materials, Tsukuba, Ibaraki, Japon. Septiembre 8-11, 2014.
P. Aseev, P. E. D. Soto Rodriguez, V. J. Gomez, Praveen Kumar, N. H. Alvi, J. M. Mánuel, F. M. Morales, J. J. Jiménez, R. García, E. Calleja and R. Notzel, “Direct Growth of Uniform In-rich InGaN on Si: A New Basic Technology”.
5. 32nd International Conference on the Physics of Semiconductors (ICPS32), Austin, Texas, EEUU, Agosto 3-8, 2014
P. Aseev, P. E. D. Soto Rodriguez, P. Kumar, V. J. Gomez, N. Alvi, Z. Gacevic, E. Calleja and R. Notzel. “High In content InGaN layers on Si(111) for infrared applications”.
6. 3rd European Conference on NanoFilms & Al-Nano FuncFinal Conference: Microstructural and chemical characterization in the nano-scale, Sevilla, España. Julio 7-11, 2014.
Enrique Calleja, Richard Nötzel and Francisco M. Morales José M. Mánuel, Juan J. Jiménez, Pavel Aseev, N. H. Alvi, Paul E. D. Soto-Rodríguez, Praveen Kumar, Víctor J. Gómez,Ginesa Blanco, Rafael García. “Electron microscopy study of InGaN grown on Si (111) by MBE for tandem solar cells”.
7. 3rd International Conference on Physics at Surfaces and Interfaces, Blue Lily Beach Resort Hotel, Puri, India. Febrero 24-28, 2014.
Praveen Kumar, P. E. D. Soto Rodriguez, N. H. Alvi, P. Aseev, V. J. Gómez and R. Nötzel “Direct growth of InN/InGaN quantum dots on Si(111)”
8. ISOM-UPM Seminario, Instituto de Sistemas Optoelectrónicos y Microtecnología de la Universidad Politécnica de Madrid (ISOM-UPM), Madrid, Spain. 10 de Mayo, 2013.
P. E. D. Soto Rodríguez, VJ. Gómez, P. Kumar, E. Calleja, R. Nötzel “Near-infrared InN quantum dots on high-In composition InGaN”.
9. XIV Simposio Chileno de Física, Universidad Católica del Norte, Antofagasta, Chile, Noviembre 14-19, 2004.
P. Soto, J.Mejia-Lopez, and D. Altbir, “Inversión Asimétrica en una Curva de Magnetización de Nanopuntos con Exchange Bias”

Reseña divulgativas para público en general
1. Indium nitride surface quantum dots on silicon substrates, Articulo en Semiconductor-Today, Enero, 30, 2015.
http://www.semiconductor-today.com/news_items/2015/jan/updm_300115.shtml
2. New more accurate and efficient sensor for the detection of diabetes, Articulo en Diabetes.net all diabetes, Febrero, 25, 2013.
http://www.ladiabetes.net/nuevo-sensor-mas-preciso-yeficaz-para-la-deteccion-de-la-diabetes/2537
3. Direct growth of InGaN on silicon, Articulo en Semiconductor-Today Febrero, 25, 2013.
http://www.semiconductor-today.com/news_items/2013/FEB/ISOM_250213.html
4. Development of a glucose biosensor for clinical diagnosis, Diabetes Channel items, Febrero 22, 2013.
http://www.canaldiabetes.com/category/diabetes-mellitus/
5. Development of a glucose biosensor for clinical diagnosis, RDI in Press, Febrero 21, 2013.
http://www.rdipress.com/tag/richard-notzel/
6. Development of a glucose biosensor for clinical diagnosis, Infodiabético, Febrero 20, 2013.
http://www.infodiabetico.com/index.php?option=com_content&view=frontpage&Itemid=14
7. Innovative glucose biosensor for clinical diagnosis, Innovaticias/Tecnologías, Febrero 19, 2013.
http://www.innovaticias.com/tecnologias/13357/innovador-biosensor-glucosadiagnostico-clinico
8. Development of a glucose biosensor for clinical diagnosis, mi+d, Febrero 18, 2013.
http://www.madrimasd.org/informacionidi/noticias/noticia.asp?id=55837
9. Development of a glucose biosensor for clinical diagnosis, Sinc, Febrero 17, 2013.
http://www.agenciasinc.es/Noticias/Biosensor-de-glucosa-para-el-diagnostico-clinico
10. Development of a glucose biosensor for clinical diagnosis, CanalUPM news, Febrero 17, 2013.
http://www.upm.es/institucional/UPM/CanalUPM/Noticias/a3461c0146cec310VgnVCM10000009c7648aRCRD
11. Bioengineering: Biosensor Glucose For Medical Diagnosis, Marzo 9, 2013.
http://www.educaempleo.com.ar/articuloPrint.php?id=415



 

Article (30)

Magnetic Actuation Methods in Bio/Soft Robotics
Editorial: Enzyme-Based Smart Materials
Enzyme Conformation Influences the Performance of Lipase-powered Nanomotors
(S)TEM methods contributions to improve the fabrication of InGaN thin films on Si
Unassisted Water Splitting with 9.3% Efficiency by a Single Quantum Nanostructure Photoelectrode
Vapor sensing and interface properties of reduced Graphene Oxide- poly(methyl methacrylate) nanocomposite
Disposable amperometric immunosensor for Saccharomyces cerevisiae based on carboxylated graphene oxide-modified electrodes
Functionalized carbon nanotubes decorated with fluorine-doped titanium dioxide nanoparticles on silicon substrate as template for titanium dioxide film photo-anode grown by chemical vapour deposition
Reduced graphene oxide–poly(methyl methacrylate) nanocomposite as a supercapacitor
Structural, optical and Carrier dynamics of self-assembled InGaN nanocolumns on Si(111)
Ultrafast Carrier dynamics of InxGa1-xN nanostructures grown directly on Si(111)
Comparative study of single InGaN layers grown on Si(111) and GaN(0001) templates: The role of surface wetting and epitaxial constraint
Epitaxial InN/InGaN quantum dots on Si: Cl− anion selectivity and pseudocapacitor behavior
Gold nanoparticles/silver-bipyridine hybrid nanobelts with tuned peroxidase-like activity
Electrocatalytic oxidation enhancement at the surface of InGaN films and nanostructures grown directly on Si(111)
InN/InGaN quantum dot photoelectrode: Efficient hydrogen generation by water splitting at zero voltage
Near-infrared emitting In-rich InGaN layers grown directly on Si: Towards the whole composition range
Stranski-Krastanov InN/InGaN quantum dots grown directly on Si(111)
Photoelectrochemical water splitting and hydrogen generation by a spontaneously formed InGaN nanowall network
A comprehensive diagram to grow (0001)InGaN alloys by molecular beam epitaxy.
An InN/InGaN Quantum Dot Electrochemical Biosensor for Clinical Diagnosis
First Demonstration of Direct Growth of Planar High-In-Composition InGaN Layers on Si.
High In Composition InGaN for InN Quantum Dot Intermediate Band Solar Cell
Highly Sensitive and Fast Anion-Selective InN Quantum Dot Electrochemical Sensors
Near-infrared InN quantum dots on high-In composition InGaN.
Spontaneous formation of InGaN nanowall network directly on Si
Uniform Low-to-High In Composition InGaN Layers Grown on Si
Highly Efficient Potentiometric Glucose Biosensor Based on Functionalized InN Quantum Dots
Formation of two-dimensional InAs quantum dot arrays by self-organized anisotropic strain engineering on InP (3 1 1)B substrates.
Asymmetric reversal of the hysteresis loop in exchange-biased nanodots

BookSection (2)

Plasmonic Photocatalysts for Water Splitting
Aptamer-Based Strategies for Diagnostics

ConferencePoster (5)

Mesoporous silica thin films for electrochemical analysis
Stranski-Krastanov InN Quantum Dots Grown on High In content in InGaN/p-type Si(111)
XRD analysis of InGaN uniform layers grown on Si(111) without any buffer layers and on Sapphire
Growth of InN quantum dots on InGaN with high In composition
High In composition InGaN for InN quantum dots intermediate band solar cell
37
Paul Soto

Postdoc

Institute of Biosciences and Biotechnologies (BIAM)

Aix-Marseille Univeristy

Saint-Paul-lez Durance, Francia

1
José Mejía

Profesor Titular

Física

PONTIFICIA UNIVERSIDAD CATÓLICA E CHILE

Santiago, Chile

1
Dora Altbir

Vicerrectora de Investigación e Innovación

Universidad Diego Portales

Santiago, Chile