Gloria Rodríguez

Irene García Cano

Ms. Anna Muesmann

Daniel Sola

Teresa Guraya

Paloma Fernández Sánchez

Dept. Física de Materiales, Fac. Ciencias Físicas, Universidad Complutense

Juan José de Damborenea

Anna Zervaki

Rodrigo Moreno

Prof. Dr. Antonio Salinas Sánchez (ES)

Dr. Faith Nightingale (UK)

Prof. Dr. Christof Sommitsch (AU)

Dr.-Ing. Dirk Lehmhus (DE)

Prof. Dr. Sandra Carvalho (PT)

Prof. Dr.-Ing. Thomas Niendorf (DE)

Prof. Dr. Joanna Wojewoda-Budka (PO)

Prof. Dr. Greg Haidemenopoulos (GR)

Prof. Dr. Francesco Baldi (IT)

Prof. Dr. Donatella Giuranno (IT)

Dr. David Mercier (FR)

Dr. David MERCIER completed his PhD in material science and engineering at the University of Grenoble (France) in 2012, specializing in the design of thin films tailored for applications in microelectronics. His journey then led him to enriching experiences through impactful postdoctoral research projects conducted in Germany (MPIE) and Belgium (CRM Group) between 2013 and 2018. During this period, his focus shifted to the realm of metallurgy, where he dedicated his efforts to multiscale modeling and the characterization of mechanical properties using cutting-edge techniques like nanoindentation. Notably, David played an active role in advancing nanoindentation data processing routines, showcasing his contributions on his GitHub page (https://github.com/DavidMercier). In 2018, David joined the UK company Granta Design, where he spearheaded collaborative initiatives with academics on materials education. After the acquisition of Granta Design by Ansys Inc., David transitioned into a pivotal role at the Office of the CTO as a Senior Collaborative R&D Project Manager. He has been at the forefront of leading European-funded projects, focusing on the development of innovative software solutions, particularly in the field of Integrated Computational Materials Engineering (ICME) and Material Informatics.

Prof. Dr. Gesa Beck (DE)

Prof. dr. ir. Annabel Braem (BE)

Prof. Dr. Theodora Kyratsi (CY)

Prof. Dr. Arnaldo Moreno (ES)

Prof. Dr. Francisca G. Caballero (ES)

Prof. Ms. Francisca G. Caballero is Research Professor at the Spanish National Centre for Metals Research (CENIM-CSIC) since 2018. She obtained her Ph.D. in Physics from the Complutense University of Madrid in 1999 for studying solid-solid phase transformations in steels during reheating. From 1997 to 2000, she worked as a research associate at the University of Cambridge in UK on the design of carbide-free bainitic steels. She has held a visiting scientist position at the Oak Ridge National Laboratory in Oak Ridge-TN-USA since 2004. Additionally, between 2013 and 2014 she has been the Deputy Director of Science at CENIM, and Vice-Rector for Postgraduate Studies and Research at Menendez Pelayo International University between 2014 and 2018. From 2018 to 2021 she has worked for Elsevier Inc as Editor-in-Chief of the Encyclopedia of Materials: Metals and Alloys published in 2021. Prof. Caballero’s current research objective is to understand the relationship among the steel processing, its structure and its mechanical properties. In this regard, she investigates the transformation mechanisms, characterize the structure of the material from the micro to the nano-scale describing the physics and chemistry that govern the processes of transformation of steel and its properties under real conditions of use.

A. FUNCTIONAL MATERIALS

Area

A: Functional Materials

Area CoordinatorS


  • Prof Dr. Theodora Kyratsi
    University of Cyprus

  • Prof Dr. Francesco Baldi
    University of Brescia

A1 – 2D materials

Scope

The symposium will cover the most recent advances in 2D materials research starting from materials synthesis, characterization, theoretical modelling and study of properties to applications. The scope of this interdisciplinary symposium is to bring together a diverse set of researchers to capture the latest developments on advanced synthesis routes and fabrication, structural, morphological and physico-chemical characterization, evaluation and fundamental understanding of structure-properties relationships and modelling, and interactions and/or incorporation with other nanomaterials. The topic is not limited to chemical and physical aspects of materials but also extends to potential applications including catalytic, energy, environmental, magnetic, electronic, optical, composite construction, bio-related and medical applications.

Description

Over the last two decades great advances have been achieved in the field of two-dimensional materials as a result of the ongoing progress in nanotechnology that provides efficient chemical approaches and advanced methods for the design, development and study of simple or hybrid nanostructured materials for targeted applications. Layered clays or other 2D silica materials, metal hydroxides like Layered Double or Singe Hydroxides(LDHs or LSHs), 2D transition metal (mono-, di- and tri- ) chalcogenides (TMMs, TMDs, and TMTs), inorganic 2D materials, graphene family and its analogues, MXenes, monoelemental 2D materials (Xenes of groups 13, 14, 15 and 16), 2D phosphates and phosphonates, metal halides, 2D metal oxides including perovskites, as well as, their van der Waals heterostructures, composite or hybrid derivatives are only few examples of this burgeoning field of materials. These materials have been extensively studied, both theoretically and experimentally, due to their interesting mechanical, chemical, optoelectronic, catalytic, (di)electric and bio-related properties. The symposium will provide a platform for interactive discussions on the broad aspects of research, development and application of these materials. It will further focus on recent progress of novel devices enabled by 2D materials, particularly with recent developments in viable approaches for large scale synthesis and integration, testing and device evaluation.

Targeted topics

List of topics and subtopics (no more than 15)

  • New Discoveries in 2D Materials
  • Synthesis and growth of 2D materials
  • Advanced characterization of 2D materials
  • Modelling and theoretical calculation in 2D materials
  • Modification and functionalization of 2D materials
  • Hybrids and nanocomposites based on 2D materials
  • Large scale production of 2D materials
  • Application of 2D materials in novel electronics, optics, photonics, spintronics and optoelectronics
  • Application of 2D materials in Sensors, Detectors, Actuators and Energy Storage
  • Biomedical and other bio-related applications of 2D materials
  • 2D materials for Quantum Computing and other related technologies
  • 2D materials in energy and environmental applications
  • Other 2D materials-based devices
  • Fundamental Physical Properties in 2D materials and van der Waals heterostructures
  • Recent Advances in 2D Magnetism, Ferroelectrics and Multiferroics

OrganizerS


  • Prof. Dimitris Gournis
    Technical University of Crete (GR)

  • Prof. Petra Rudolf
    Groningen (NL)

  • Prof. Francesco Zerbetto
    Università di Bologna (IT)

A2 – Nanomaterials, nanoparticles and nano-structuring

Scope

This symposium brings together contributions presenting experimental, theoretical, and numerical advances in the fields of nanomaterials, nanoparticles and nano-structuring. It will showcase recent progress in these fields with a focus on state-of-the-art advances. Innovative research lines, with contributions from a plethora of disciplines, such as materials science, chemistry, physics, biological sciences, and engineering shall form the content of the symposium. This diverse scientific audience will ensure an excellent environment for fostering innovative ideas and enhancing interdisciplinary research in this area.

Description

Nanomaterials and nanoparticles have been widely used in almost all sorts of applications, predominately due to their unique properties they possess, as compared to their bulk form. Since their initial stages of exploitation, they have found applications in all fields, including nanoelectronics, catalysis, magnetics, pharmaceuticals, to mention but a few. Research in nanomaterials covers all sectors, from designed synthesis, sophisticated characterization approaches, as well as applications in all fields. Furthermore, research groups have successfully utilized diverse techniques for the manipulation and structuring of a wide range of nanomaterials, including nanoparticle assembly approaches, among others.

Though nanomaterials have been widely exploited for decades, their versatility, extraordinary properties and tailor-made applications still form a substantial portion of current scientific research, on a global scale. Growth of new forms of nanomaterials, manipulation and nanostructuring, dedicated characterization and new, emerging applications hold well within cutting edge research directions.

Targeted topics

Topics of interest include experimental, theoretical, and numerical advances in the following fields of interest, though not limited to:

  • New developments towards synthesis, dispersion and assembly of nanomaterials and nanoparticles
  • Growth and nano-structuring of thin films, particularly in nanoparticle form
  • Characterization of nanomaterials with microscopic or spectroscopy methods, with emphasis in operando/in-situ approaches
  • Integrated characterization approaches in nanomaterials research
  • Nanomaterials and nanoparticles for energy and environmental applications, such as catalysts, thermoelectric, semiconducting thin films and assemblies, smart materials etc.
  • Nanomaterials for engineering application of biopolymers, for recycling and upcycling of polymers, and for accelerated/controlled degradability of bio-based polymers
  • Processing of minerals in nanoparticle form, especially for CCUS applications

OrganizerS


  • Prof. Hung-Jue Sue
    Texas A&M University, College Station (US)

  • Prof. Sebastian Pfaller
    Friedrich-Alexander-Universität, Erlangen-Nürnberg (DE)

  • Dr. Andreas Delimitis
    University of Stavanger, Norway

A3 – Porous materials and metal organic frameworks

Scope

This symposium will serve as an excellent platform to promote discussion on emerging porous materials, novel characterization tools, innovative applications of porous materials in industrial and environmental processes, modeling of materials and processes, among others. 

Description

The symposium will cover all aspects related with the synthesis, characterization and application of porous materials. It will be devoted to all types of porous materials, from activated carbons, and zeolites, to metal-organic frameworks, and porous silicas, among others. Special emphasis will be placed on the industrial-scale applications of porous materials, including their crucial role in adsorption/separation processes, catalysis, biological and biomedical applications, etc. The program will integrate experimental studies with computational analyses to achieve a comprehensive understanding of processes occurring at nanometric scale. 

Targeted topics

  • Synthesis
  • Emerging porous materials
  • Characterization
  • Theory and Modeling
  • Structural Flexibility & Dynamics
  • Adsorption / Separation
  • Catalysis
  • Energy
  • Sensing
  • Biological and biomedical aspects
  • Environmental applications
  • Industrial applications

OrganizerS


  • Prof. Joaquin Silvestre
    University of Alicante (ES)

  • Prof. Jose Maria Pedrosa
    University Pablo de Olavide, Sevilla (ES)

A4 – Smart materials

Scope

Modern methodologies and studies on intelligent materials encompass a broad spectrum of subjects, including novel categories of intelligent materials, their tailoring for particular industrial uses, innovative technological methods for their production and processing, and effective mathematical models to characterize their reaction to external stimuli.

The purpose of this Symposium is to converge experts from several fields, including shape memory polymers, composites and alloys, stimuli-responsive materials, and 4D printed materials, to discuss the most recent developments in the field of smart materials.

Description

The purpose of this Symposium is to converge experts from several fields.

Areas of interest within this Symposium will include, but will be not limited to:

  • Shape memory polymers
  • Shape memory alloys
  • Shape memory composites
  • 3D printing of smart materials and 4D printing
  • Modelling of shape memory materials
  • Application of the shape memory effects in structures and devices.

Targeted topics

  • Topic 1- Shape memory polymers
    • Subtopic 1: – Novel shape memory polymers
    • Subtopic 2: – Modelling the response of shape memory polymers
    • Subtopic 3: – Application of shape memory polymers
  • Topic 2- 4D printing
    • Subtopic 1: – Novel approaches to 4D printing
    • Subtopic 2: – Modelling the response of 4D printed structures
    • Subtopic 3: – Application of 4D printed structures
    • Subtopic 4: – 4D textiles
  • Topic 3 – shape memory alloys
    • Subtopic 1: Materials and device design and functionality in 3D-printing
    • Subtopic 2: Rapid alloy design
    • Subtopic 3: Sustainability through 3D printing

OrganizerS


  • Prof. Stefano Pandini
    Università degli Studi di Brescia (IT)

  • Dr. Mahdi Bodaghi
    Nottingham Trent University, Nottingham (UK)

  • Prof. Mohammad Elahinia
    University of Toledo (US)

A5 – Functional soft materials

Scope

Naturally-derived and synthetic materials such as gels, foams, nanofibers and elastomers are considered as soft materials. They have intriguing features such as light-weight, low modulus, stretchability, biocompatibility, self-healing and can often respond to external stimuli such as temperature, chemical environment, light, electrical or magnetic fields. Their unique physical, chemical and mechanical properties make them suitable for cutting-edge applications in several fields, such as bioengineering, soft robotics, flexible electronics, etc. Therefore, this symposium will be focused on the current progress of soft materials, ranging from materials design, preparation, prediction and determination of mechanical and functional performance and applications.

Max 100 words

Description

Soft materials are attracting considerable attention, and many efforts are being made to develop functional soft materials with a wide variety of functionalities such as stretchability, biodegradability, self-healing properties, stimuli-responsiveness, ability to control the diffusion of different species. These make them of high interest for application in very different fields including biomedicine, environmental applications, sensing, energy, optoelectronics, etc. Innovative soft materials with tailored properties pose a challenge to their functional and mechanical characterization. Therefore, this symposium is focused on the research advancements in the design, preparation, and performance of soft materials. A special attention will be devoted to the structure-properties-performance correlation, and to the advanced methods of characterization for the determination of aforementioned materials.

Targeted topics

List of topics and subtopics (no more than 15)

  • Synthesis of multi-functional soft materials
  • Structure of multi-functional soft materials
  • Functional properties (e.g. optical, electrical, thermal, magnetic)
  • Rheology and mechanics of soft materials
  • Fracture of soft materials
  • Multi-scale modelling
  • Applications (bioengineering, environment, energy, electronics, robotics, etc.)

OrganizerS


  • Prof. Alicia Salazar
    Universidad Rey Juan Carlos, Madrid (ES)

  • Prof. Francesco Briatico-Vangosa
    Politecnico di Milano (IT)

  • Prof. Theodora Krasia
    University of Cyrpus (CY)

A6 – Energy materials

Scope

This symposium spotlights cutting-edge materials science for a sustainable energy future. It explores materials for energy generation (photovoltaics, thermoelectrics), storage (batteries, supercapacitors), and conversion (catalysts for green hydrogen, fuel cells). Additionally, it addresses materials for CO2 capture, radiative cooling, energy efficiency, smart grids, and sustainable material management. This event provides a platform for experts to discuss how advanced materials can tackle the global energy challenge and create a cleaner, more efficient energy landscape.

Description

This symposium will focus on the latest advancements in materials science aimed at addressing the growing global demand for sustainable and efficient energy solutions. The development of new materials is pivotal for enhancing energy generation, storage, and conversion technologies, contributing to the transition toward a more sustainable energy future. Key topics will include next-generation materials for photovoltaics, thermoelectrics, concentrating solar-thermal power technologies (CSP), high-performance batteries and fuel cells. The symposium will also cover advancements in catalytic materials for green hydrogen production and hydrogen storage, as well as carbon capture, aiming to reduce the carbon footprint of energy production. Thermal energy absorption and related storage materials are also included. All kinds of materials are concerned, inorganic and organic, such as but not limited to semiconductors, metal alloys, nanomaterials, solid-state electrolytes, advanced polymers, 2D materials, etc. Through a blend of technical presentations, case studies, and collaborative discussions, this event will provide a platform for researchers, industry leaders, and policymakers to explore how cutting-edge materials science can be harnessed to address the global energy challenge and contribute to a cleaner and more efficient energy landscape.

Targeted topics

  • Next-Generation Photovoltaic Materials: Advances in perovskites, organic photovoltaics, and tandem solar cells. Silicon-based photovoltaics and thin film technologies are also included.
  • Materials for Energy Storage: Materials for batteries and supercapacitors, solid and polymer electrolytes, electrodes, etc.
  • Energy Harvesting Materials: Thermoelectric, piezoelectric, triboelectric, and other materials for converting thermal or mechanical energy into electricity.
  • Catalytic Materials for Green Hydrogen Production: Advances in catalysts for water splitting and hydrogen generation.
  • Hydrogen Storage Materials: New materials for efficient hydrogen storage and transport in fuel cell applications.
  • Materials for CO2 Capture and Sequestration: Development in reactions and on porous materials, such as MOFs (Metal-Organic Frameworks) for carbon capture.
  • Materials for Thermal Energy Storage: Materials for sensible thermal storage such as molten salts, concrete blocks, rocks etc., and latent heat storage using phase change materials.
  • Materials for Radiative Cooling Technologies: Development with a focus on the design strategy including their intrinsic properties, structural formations, and performance improvement.
  • Materials for Energy Efficiency: Materials for improving insulation, heat transfer, and energy conservation in buildings and industrial processes.
  • Materials for Smart Grids: Materials for advanced sensors, power electronics, and energy management systems.
  • Materials Degradation and Recycling: Understanding and mitigating material degradation in energy systems, as well as developing efficient recycling and recovery processes.
  • Life Cycle Assessment and Sustainability: Evaluating the environmental impact and sustainability of energy materials throughout their life cycle.
  • Theory and Simulation: Computational approaches for the development of energy-related materials

OrganizerS


  • Prof. Marisol Martín González
    Micro & Nanotecnology Institute – IMN-CSIC (ES)

  • Dr. Martin Bellman
    SINTEF (NO)

  • Yijiang Xu
    SINTEF (NO)

  • Dr. Eleni Pavlopoulou
    SINTEF (NO)

A7 – Functional materials: Synthesis and applications

Scope

This symposium will focus on the synthesis, processing, and application of novel functional and multi-materials. Topics include the design, processing, characterization, and applications of functional polymers and composites, metals and ceramic materials. Emerging fields, such as shape-memory, metamaterials, sol-gel functional materials, will be highlighted alongside novel applications like soft actuators and stretchable electronics/sensors. Attendees will gain insights into the latest advancements and future trends in functional material design, offering broad opportunities for cross-disciplinary collaboration and innovation in cutting-edge technologies.

Description

This symposium will provide a comprehensive exploration of cutting-edge advancements in the synthesis and processing of novel functional materials, including multi-material systems. A key focus will be on shape memory materials, covering their processing, characterization, and diverse applications in industries ranging from healthcare to aerospace. The design, synthesis, and testing of metamaterials will also be highlighted.

This symposium aims to delve into the emerging realm of functional surfaces and sol-gel functional materials, discussing their unique properties and applications. Novel uses of functional materials, such as soft actuators and stretchable electronics and sensors, will be showcased, demonstrating their importance in wearable technologies, robotics, and beyond.

This symposium will not only address current trends in material design but also explore future directions in functional material innovation. By bringing together researchers, engineers, and industry professionals, it aims to foster interdisciplinary collaboration, spark discussions on novel processing techniques, and encourage the development of materials with enhanced functionalities. Through these diverse topics, the event will provide a rich platform for advancing knowledge and driving innovation in the field of functional and responsive materials.

Targeted topics

List of topics and subtopics

  • Synthesis of novel functional materials
  • Processing of functional (multi-)materials
  • Shape memory materials
    • Processing
    • Applications
    • Characterization
  • Metamaterials
    • Design
    • Processing
    • Testing
    • Applications
  • Functional surfaces
  • Emerging fields in functional material design
    • Sol-Gel functional materials
  • Novel applications of functional materials
    • Soft actuators
    • Stretchable electronics / sensors

OrganizerS


  • Prof. Marialaura Tocci
    Università degli Studi di Brescia (IT)

  • Dr. Annalisa Chiappone
    Università degli Studi di Brescia (IT)

  • Dr. Florian Arbeiter
    Montanuniverstät of Leoben (AT)