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What is FUNCTIONAL NANOMATERIALS all about?

  • Developing next-generation batteries for stationary, portable and mobile applications. 
  • Valorising biomass and waste into chemicals and fuels through electrocatalysis. 
  • Accelerating materials discovery through AI-driven high-throughput workflows

Functional nanomaterials

The Functional Nanomaterials department engineers nanomaterials with precisely tailored composition, structure and properties, and integrates them into working energy devices. Its research combines fundamental studies of nanoparticle nucleation and growth with advanced bottom-up processing, producing materials ranging from porous aerogels to high-resolution printed microstructures. Working across batteries, electrocatalysis and thermoelectrics, the department connects the nanoscale with real-world energy applications, accelerated by AI-driven autonomous discovery workflows. 

Nanomaterials design and synthesis 

Fundamental studies of how composition, size, shape and surface chemistry define nanoparticle properties — from plasmonic and magnetic behaviour to catalytic activity — build the knowledge needed to engineer materials that perform precisely in energy conversion and storage applications. 

Advanced batteries 

Targeted catalyst design, novel cell architectures and operando characterisation address the key challenges of next-generation battery chemistries — polysulfide shuttling, slow kinetics, limited cycle life and safety — guiding the development of durable, high-performing cells. 

Electrocatalysis and biomass valorisation 

Electrocatalysts engineered for selective oxidation reactions couple biomass-derived waste streams with hydrogen evolution, converting discarded feedstocks into value-added chemicals and fuels while supporting a circular, low-carbon chemical and energy economy. 

Bottom-up processing and 3D printing 

Nanoparticle building blocks are translated into functional components — films, dense composites and three-dimensional architectures — using a proprietary electrostatic jet-deflection platform that prints at sub-micrometre resolution, bridging nanoscale design and scalable manufacture. 

Our activity at a glance

The department brings together a multidisciplinary team of researchers and specialists working across its core research areas. Our work combines fundamental research, technology development and applied validation, engaging with academic institutions, industry partners and public bodies to generate knowledge and solutions with real-world impact.

A department expert team

Donut chart and data table showing the composition of 35 total members by professional category and gender.
Data table illustrating the distribution of 35 team members by professional role and gender.

Our research lines

Conceptual map of the "Functional Nanomaterials" research lines.

Research lines

  • Nanomaterials design and synthesis
  • Advanced batteries
  • Electrocatalysis and biomass valorisation
  • Bottom-up processing and 3D printing
  • AI-driven materials discovery

Nanoparticles and nanocomposites are synthesised using solution-based and flow-reactor approaches, achieving precise control over composition, particle morphology and surface chemistry. Studies of nucleation and growth mechanisms in high-entropy and multinary systems provide the knowledge base needed to engineer materials with target functional properties. 

Scientist checking pressure in a laboratory setup, representing the synthesis and characterization of nanoparticles and nanocomposites using controlled experimental conditions and flow-reactor systems.
Scientist transferring liquid between laboratory containers, representing solution-based synthesis and flow-reactor processes for nanoparticle and nanocomposite fabrication with controlled composition and morphology.

Electrode materials, electrolytes and cell architectures for metal-air, metal-sulfur, sodium-ion, zinc-ion and solid-state battery technologies are developed and tested. High-entropy catalyst design and operando characterisation guide progress from coin-cell prototypes to pouch-cell demonstrators targeting improved energy density, cycle life and safety.

Scientist analyzing computer screen with graphs and data visualizations, representing research on advanced battery materials, electrochemical systems and energy storage performance optimization.
Laboratory container with green liquid, representing electrolyte solutions used in battery research and development of advanced energy storage systems.

Selective and stable electrocatalysts are engineered to couple the oxidation of biomass-derived alcohols and aldehydes with hydrogen evolution, converting waste streams into value-added chemicals and fuels. The work integrates catalyst design, reactor engineering and product separation, building towards pilot-scale demonstrators. 

Scientist handling and storing small laboratory vials, representing electrocatalyst development and experimental workflows for biomass conversion and hydrogen production research
Two laboratory containers filled with black and red liquids, representing catalytic processes and experimental studies in biomass conversion and energy-related chemical reactions.

Nanoparticle inks are processed into functional materials spanning porous scaffolds, dense nanocomposites, large-area thin films and high-resolution three-dimensional structures. A proprietary electrostatic jet-deflection printer achieves sub-micrometre feature sizes at 200 layers per second, enabling scalable fabrication of microdevices and electrodes. 

Scientist pouring liquid into a laboratory container, representing nanoparticle ink processing and advanced fabrication of functional materials for thin films, nanocomposites and microdevice manufacturing.
Assorted laboratory vials and equipment, representing nanoparticle ink processing and advanced material fabrication for thin films, nanocomposites and microdevice development.

The exploration of nanomaterial compositions is accelerated through autonomous workflows integrating AI-guided design, automated synthesis, high-throughput characterisation and computation in closed-loop cycles. This self-driving approach rapidly identifies promising candidates across the vast compositional space of high-entropy systems. 

Scientist working in a laboratory environment, representing autonomous nanomaterials research workflows integrating AI-guided design, automated synthesis and high-throughput characterization for advanced energy materials discovery
Liquid material inside a laboratory container, representing experimental nanomaterial synthesis and solution-based processing in advanced materials research

A skilled team dedicated to advancing the energy transition.

Competitive and industrial projects from lab to real-world scale.

Peer-reviewed outputs at the forefront of energy research.

Tech Transfer

The Functional Nanomaterials department translates fundamental research into practical energy technologies through collaboration with industrial and academic partners at national and international level. Transfer activities span battery cell demonstrators, electrocatalytic systems for biomass valorisation and high-resolution additive manufacturing. A key outcome is a proprietary electrostatic jet-deflection 3D printing platform protected by an international patent portfolio, which achieves sub-micrometre printing at high throughput and has attracted industrial interest in both the electronics and energy sectors. 

The department collaborates with ICN2, the Institute of Science and Technology Austria, and universities across Spain, Germany and China. Research is funded through European Commission, IDAE and Generalitat de Catalunya programmes. 

Facilities

Scientist working in a nanomaterials laboratory, representing integrated research infrastructure for synthesis, characterization and device fabrication, including battery testing, nanoparticle production and advanced material development.

Facilities

The department operates a full nanomaterials research infrastructure spanning synthesis, processing, characterisation and device fabrication. Solution-based and flow-reactor platforms enable scalable nanoparticle production with precise compositional control. A dedicated battery laboratory supports electrode fabrication, coin-cell and pouch-cell assembly, and electrochemical testing. The proprietary electrostatic jet-deflection printer enables sub-micrometre 3D fabrication of microdevices and electrodes. 

In situ and operando characterisation tools, combined with institute-wide shared platforms including TEM and XRD, complete an integrated environment for the full nanomaterials-to-device development pipeline. 

Scientist working in a nanomaterials laboratory, representing integrated research infrastructure for synthesis, characterization and device fabrication, including battery testing, nanoparticle production and advanced material development.

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