battery – Progress in Research

More efficient perovskite-based solar cells thanks to supramolecular chemistry

Posted on 24/03/202206/08/2024 by Erik Franco

Supramolecular chemistry (which deals with multimolecular systems), and in particular halogen bonding, i.e., the intermolecular interaction involving halogen atoms (I, Br and Cl) in organic molecules, can help improve the performance of perovskite-based solar cells, enabling them to achieve high levels of efficiency and high stability.

This is the conclusion of researchers at the Politecnico di Milano who have published in the prestigious Angewandte Chemie International Edition.

Organic-inorganic hybrid perovskites – ionic compounds consisting of small organic cations and metal halides – have been known about since the 19th century, but they have only recently been used in optoelectronics for the construction of lasers, diodes, photodetectors and solar cells. In particular, the first perovskite-based photovoltaic cell was produced in 2009 and since then there has been intensive research into achieving an efficiency of more than 25%, which would surpass even the silicon that currently dominates the photovoltaic market.

The low cost and excellent performance of perovskites make them very attractive for photovoltaic applications, but there are still a number of problems that prevent these materials from entering the market. First of all, there is their low stability when it comes to air and humidity. In addition, the presence of defects, i.e., imperfections in the crystal lattice, can generate ‘trap states’ that interfere with the movement of charge carriers (electrons and holes) generated by light within the material, trapping them and causing electrical energy losses. Generally, these trap states are unbound halide ions that can move under the effect of an electric field and recombine with holes.

The study conducted at the Politecnico showed that the use of additives capable of forming halogen bonds with the halide ions present in perovskites provides significant advantages for the development of solar cells with better crystallinity and greater stability. Halogen bonding enables fluorinated molecules to be introduced, which passivate the surface halides to produce hydrophobic and water-repellent perovskites. In this way, trap states are blocked and efficiency is increased.

In addition, the surface modification of perovskite with bifunctional molecules capable of forming halogen bonds enables better integration of the perovskite within the solar cell, facilitating the generation of electrical current.

From the data reported, it appears that halogen bonding has considerable potential for the development of a new generation of solar cells based on perovskites. However, a better atomic/molecular understanding of these materials is needed to fully exploit the advantages of halogen bonding.

The paper was written by Gabriella Cavallo, Giancarlo Terraneo and Pierangelo Metrangolo of the Department of Chemistry, Materials and Chemical Engineering ‘Giulio Natta’ of the Politecnico di Milano in collaboration with Laura Canil and Antonio Abate (an alumnus of the Politecnico di Milano) of the Helmholtz Zentrum Berlin fur Materialen und Energie.

Read the paper on Angewandte Chemie International Edition

Sinergy: the metal-polysulfide flow cell battery

Posted on 03/03/202206/08/2024 by Erik Franco

Sinergy is a patent developed by the Department of Chemistry, Materials and Chemical Engineering.

It consists of a metal-polysulfide flow cell battery that uses inexpensive, abundant and non-toxic materials.

These characteristics are crucial for application of the technology for storing stationary-type energy that can support the intermittent production of renewable energy. Another advantage is the possibility of making use of sulphur-rich waste, creating a virtuous circle of circular economy.

The inventors are Luca Magagnin, Gabriele Panzeri, Eugenio Gilbertini, Alessandra Accogli, Matteo Salerno, Luca Bertoli.

Sinergy won the Intellectual Property Award (IPA) in the “alternative energy” sector, as announced at the Italian Pavilion of Expo Dubai. It is the competition for Italian technological patents resulting from public research organised by the Ministry of Economic Development in collaboration with Netval (Network for Research Valorisation).

A total of 217 innovative patents developed by Universities, Research Centres and Scientific Hospitalisation and Treatment Institutions were considered for the competition; and 35 of these were selected for the final stage in Dubai.

At the end of the process, the award-winning projects were those able to propose innovations with the greatest economic and social impact in 7 technological areas of reference for the global ecological and digital transition: agritech and agrifood, cybersecurity, green tech, life science, future mobility, aerospace, and alternative energy.

Agreement with a2a

Posted on 09/02/202206/08/2024 by Erik Franco

The A2A Life Company Group and Politecnico di Milano have started up collaboration for the development of innovation, research and training initiatives in the Energy & Utility sector, to support Italy’s ecological transition. The recently signed partnership model is based on two agreements with a total value of 8 million euros and a duration of 5 years.

In particular, the agreement provides for the establishment of a Joint Research Centre to implement multidisciplinary experimental projects on specific issues such as sustainable mobility, the development of renewable energy and hydrogen, battery recycling, the study of new technologies for waste treatment and the recovery of materials and energy, for a total of 5 million.

At the same time, the partnership will give rise to a Joint Research and Innovation Centre inside the Innovation District, which Politecnico di Milano is developing at the former Bovisa gasometer park and in which A2A will take part with a total investment of 3 million euros. The Joint Centre will be entirely dedicated to innovation in the following thematic macro-areas: “Technologies for the environment and energy” and “Technologies for sustainable mobility”, also touching on the themes of energy transition and the circular economy.

The JRC – Joint Research Center has proven to be one of the most valid tools for strengthening the understanding between universities and business.

The agreement was signed by the Rector of the Politecnico, Ferruccio Resta, and by Renato Mazzoncini, CEO of A2A, in the presence of the President of A2A, Marco Patuano, the Mayor of Milan Giuseppe Sala and the President of Regione Lombardia, Attilio Fontana.

The JRC – Joint Research Center has proven to be one of the most valid tools for strengthening the understanding between universities and business. For activating an ever closer synergy on topics of common interest and to meet the challenges that the NRRP poses to Italy: from energy transition, to sustainable mobility, and renewable energy. These are some of the objectives of the agreement which sees Politecnico di Milano working alongside A2A. One of the companies most actively encouraging this path of shared growth. Ready to support joint research from an open supply chain perspective. This agreement in fact represents a shared desire to create a real ecosystem of innovation that goes beyond applied research projects to the development of a flagship project on which the Politecnico will focus in the coming years.
Ferruccio Resta, rector of the Politecnico di Milano

Super fast quantum battery

Posted on 19/01/202206/08/2024 by Erik Franco

Researchers from the Physics Department of the Politecnico di Milano and the Institute of Photonics and Nanotechnologies of the Cnr have built a battery which, following the laws of quantum physics, has a recharge time that is inversely related to the battery capacity.

Tersilla Virgili (Institute of Photonics and Nanotechnologies of the National Research Council Cnr-Ifn) and Giulio Cerullo (Physics Department of the Politecnico di Milano) have shown that it is possible to manufacture a type of quantum battery where the charging power increases faster by increasing the battery capacity.

The fabricated device is a microcavity in which the active material consists of organic molecules dispersed in an inert matrix.

Each molecule represents a unit that can exist in a quantum superposition state of two energy levels (fundamental and excited), similar to the way a qubit, the basic unit of quantum information, can be both 0 and 1 simultaneously in quantum computers. By constructing the quantum battery in a way that units can exist in superposition, the total system can behave collectively. This behaviour, known as quantum coherence, allows the units to act cooperatively, giving rise to a hyper-fast charge that depends on the number of molecule-units.
Prof. Giulio Cerullo

This new technology could find possible applications in devices such as wireless chargers, solar cells and cameras.

Superabsorption in an organic microcavity: towards a quantum battery.