advanced devices

THE ADVANCED DEVICES AREA FOCUSES ON MATERIALS ENGIGNEERED AT THE NANOSCALE AND THEIR IMPLEMENTATION IN NEW GENERATION MULTIFUNCTIONAL DEVICES WITH APPLICATION IN THE FIELDS OF ENERGY PRODUCTION, ENERGY STORAGE AND ENERGY SAVING.

CONTACT PERSONS

Vincenzo Maiorano, Luisa De Marco, Aurora Rizzo, Rosanna Mastria, Salvatore Gambino

KEYWORDS

Perovskite Solar Cell (PSC), Sustainable Batteries, Multifunctional devices for energy saving, Wearable Printed Electronics, Functional Materials, Electrical and Photoelectrical characterization

Specifically, the use of advanced bottom-up and top-down approaches allows to design and manufacture devices based on organic, inorganic and hybrid materials, on rigid and flexible substrates with innovative features compared to the state of art at high Technology Readiness Level (TRL).
These innovations in nanotechnologies, at the forefront of material science and advanced devices, are pivotal in designing and engineering eco-friendly hybrid organic/inorganic materials, as well as their precise implementation into micro/nanostructured active optoelectronic devices with low energy consumption.

The research lines of the Advanced Devices area are listed below:

    1. Perovskite Solar Cells
    2. Sustainable Batteries
    3. Multifunctional devices for energy saving
    4. Wearable electronics
    5. Perovskites for optoelectronic and photonic devices
    6. Electrical and Photoelectrical characterization of optoelectronic devices

Perovskite Solar Cells

The latest generation of photovoltaic cells based on metal halide perovskites has achieved power conversion efficiency of over 26% in a few years, which holds great promise for revolutionising photovoltaic technology.

Contact Persons

Aurora Rizzo

Keywords

Perovskite Solar Cell (PSC),  Smart Windows

In this context, we are focusing our activity on the development of metal halide material for solar cells, and in particular on controlling the growth conditions of the polycrystalline films to obtain high efficiency and stable devices.

We are currently exploring the potential of semi-transparent solar cells for use in building-integrated photovoltaic devices, as well as wide band gap solar cells for integration into tandem technology.

Furthermore, we are exploring the potential of alternative materials to indium tin oxide (ITO) as transparent electrodes based on graphene and lead-free perovskite materials, with the aim of enhancing the sustainability of the technology.

People

Aurora Rizzo, Antonella Giuri, Rosanna Mastria, Silvia Colella, Nadir Vanni, Lucia Mercurio, Dawar Ali, Mario Calora, Liya Anthony, Sonia Carallo, Sara Covella, Vincenza Armenise, Andrea Listorti, Francesca Russo

Sustainable Batteries

Batteries are playing a key role in the clean energy transition, enabling the use of renewable sources and electric mobility. Currently, Lithium-ion Batteries (LiB) dominate the market but are based on critical raw materials (such as Cobalt), whose low natural abundance, high cost and toxicity urges the search for alternative materials.

Contact Persons

Luisa De Marco

Keywords

Organic batteries, Hybrid organic-inorganic nanostructured cathodes, Zn-air batteries, Biomass-derived materials

In the framework of the ERC Consolidator project ‘HYNANOSTORE’ we re-think the concept of battery’s electrode based on lithium insertion and develop new environment-friendly systems for energy storage based on organic redox materials, which can reversibly uptake and release electrons and cations (including Sodium or other cations), replacing critical raw materials. Organic redox materials are ubiquitous in nature or can be produced from biomass by green processes, therefore the battery can be produced from naturally abundant materials and at the end of its life can be easily recycled, so the environmental footprint of its life cycle is minimized, leading to a new generation of “green batteries”.

People

Luisa De Marco, Sabrina Di Masi, Francesco Biscaglia, Simone Bruno, Martina Scaramuzzo, Giuseppe Mianulli, Francesco Ruighi, Sonia Carallo

Multifunctional devices for energy saving

Chromogenic and multifunctional solid state devices are able to modulate the amount of solar radiation passing through them selectively and independently in the visible and infrared range through the application of an external stimulus (voltage, temperature, light) and using an appropriate active material, are included in the class of “green” nanotechnology for “Building Integration” and energy saving applications.

Contact Persons

Vincenzo Maiorano, Pierluigi Cossari

Keywords

Solid State Electrochromic (EC) Devices, Smart Windows, TADF

Combining the functionalities of energy production, lighting and controlled shielding, through the use of low consumption lighting sources (OLEDs, perovskite LEDs -PeLEDs), solid state chromogenic (dual-band electrochromic, thermocromic, photochromic) devices and organic and hybrid photovoltaic (PV) cells, “smart” and self-sustainable multifunctional devices can be implemented.

People

Vincenzo Maiorano, Fabrizio Mariano, Marco Pugliese, Antonio Maggiore, Sonia Carallo

Wearable electronics

Wearable optoelectronic devices have gained considerable interest in recent years due to their potential use in personal portable health monitoring, remote medical practices and improving safety conditions in the workplace.

Contact Persons

Vincenzo Maiorano

Keywords

Flexible optoelectronics, solution based electronics, large area production, chromogenic and light emitting fabrics, TADF

Thermally Activated Delayed Fluorescence (TADF) materials can be integrated into flexible or textile-based OLED displays, as well as into wearable optical sensors that can track multiple vital signs such as heart rate, blood pressure and oxygen levels. Other wearable applications include UV detection, measurement of pollutant levels and detection of explosives, both indoors and outdoors. Research activities focus on the realisation and characterisation of different types of optoelectronic devices on different substrates (e.g. fabrics) and their combination with other components to realise flexible, easily processable smart systems with enhanced functionalities. Thermochromic, photochromic and electrochromic systems have also been developed using innovative organic (carbon-based) semiconductors, hybrid systems incorporating both organic and inorganic materials (3D-2D perovskites), nanoparticle-based inks (e.g. colloidal 2D-TMDC, carbon nanotubes, graphene), processed by wet techniques (printing and coating methods) for large area production.

People

Vincenzo Maiorano, Fabrizio Mariano, Marco Pugliese, Antonio Maggiore, Sonia Carallo

Perovskites for optoelectronic and photonic devices

Metal halide perovskites are materials with remarkable optoelectronic properties, such as a high light absorption coefficient, strong oscillator strength, efficient ambipolar charge transport, high defect tolerance, and the ease of solution-based preparation.

Contact Persons

Rosanna Mastria, Aurora Rizzo, Luisa De Marco

Keywords

Perovskites engineering, Perovskite nanocomposites, Perovskite single-crystals

Our research focuses on understanding the fundamental properties of these materials and investigating their operating mechanisms in various devices, including solar cells, light-emitting diodes, and ionizing radiation detectors. We also explore various material development strategies to engineer the composition, as well as the optical and electronic properties of perovskites, to meet specific application requirements. The materials developed in our laboratories range from hybrid (organic-inorganic) perovskites to fully inorganic perovskites with different dimensionalities (2D and 3D).

People

Rosanna Mastria, Aurora Rizzo, Luisa De Marco, Ilenia Viola, Mario Calora, Amal Chandran Chekkallur, Simone Bruno, Francesco Saverio Difeo, Sonia Carallo, Pierluigi Cossari

Electrical and Photoelectrical Characterization of Optoelectronic Devices

A range of material properties can be extracted from photo-electrical experiments, such as charge generation and recombination, mobility, doping and charge trapping mechanisms, injection properties of the contacts and eventually ionic contribution.

Contact Persons

Salvatore Gambino

Keywords

Electro-Optical Characterization, Charge Transport, Mobility, Time of Flight (TOF), Charge Extraction by Linearly Increasing Voltage (CELIV), Thermally Stimulated Current (TSC), Space Charge Limited Current (SCLC)

As these parameters are entangled, only the combination of different measurement techniques that combine steady-state, transient, and frequency-domain experiments can give a reliable insight into device physics. We have developed different photoelectrical characterization techniques that can be used on organic, inorganic and hybrid semiconductors or into operationally working devices.

DC Measurements
With direct-current (DC) measurements we refer to the electrical steady-state characterization of semiconductors and devices. The measurement can be carried out with the device in dark conditions or under various illumination intensities, under controlled environmental conditions and temperatures.

    • Current-Voltage (J-V) and JV-Luminescence (J-V-L) measurements
    • 4-point probes resistivity measurements and Hall mobilities

Transient Measurements
The measurement of a transient entails the recording of the response of an electrical parameter (like current or voltage) over time after the application of a stress. The stress can be illumination, voltage bias, or a combination of the two.

    • Charge Extraction by Linearly Increasing Voltage (CELIV)
    • Time of Flight (TOF)
    • Thermally Stimulated Current (TSC)

People

Salvatore Gambino,  Adriano Cola