innovation2 – Progress in Research

Green deal: a pilot plant for turning biomass into clean hydrogen

Posted on 13/07/202106/08/2024 by Erik Franco

Tag: landfill, energy, hydrogen, animal waste, biomass, biogas, sustainable, green, methane, steam, decarbonization
Researcher: Giampaolo Manzolini
Department: DENG – Energy Department

The use of hydrogen as an energy source could reduce both pollution and the production of greenhouse gases. However, most of the hydrogen currently produced comes from natural gas, coal or oil, processing all of which creates carbon dioxide. Biomass, though, is an almost carbon-neutral renewable energy source. The anaerobic digestion process of residual biomass from various sources – animal waste, sewage treatment plants, industrial wastewater and landfills, for example – produces biogas, a mixture of methane and carbon dioxide. Politecnico di Milano has an important focus on this matter. One of the most promising technologies developed by our researchers comes from the European project BIONICO (BIOgas membrane reformer for deceNtralIzed hydrogen produCtiOn), funded with over 3 million euros under the Horizon 2020 scheme.

The team developed, assembled and is currently testing a pilot plant that converts biogas directly into hydrogen, with a novel reactor concept at its core. The plant is expected to produce 100 kg of hydrogen per day. It will be the first example of a biogas-to-hydrogen plant based on membrane reactor technology installed in a real biogas plant at this scale, with more than 100 membranes in a single fluidised bed membrane reactor. It aims at a hydrogen production efficiency of 70%, 10% over same-size conventional reactors. It works with biogas produced through biodigesters or from municipal waste, fed into the plant together with steam inside the reactor. The reaction is enhanced by a catalyst which circulates in the reactor through the same flow of biogas. Inside the reactor, palladium tubular membranes on ceramic support allow to selectively separate the hydrogen. The high efficiency obtained with the BIONICO reactor is guaranteed from the simultaneous production and separation of hydrogen in a single reactor. The use of a single reactor operating at temperatures limited (550 vs 800 ° C) also allows to simplify the system, with potential cost advantages over traditional systems.

The project shows the feasibility and cost-effectiveness of the solution and define the market potential for the new plant, while proving biogas-produced hydrogen to be a viable sustainable energy source, with potential environmental benefits that can come from using such plants in the long term.

The BIONICO consortium benefits from the cooperation of eight partners from seven different countries across the EU. Each partner has been involved in a different aspect of the mission, such as the design and testing of the reactor together with the main system components. The BIONICO project stems from the knowledge gained in years of research from three previous projects: ReforCELL, FERRET and FluidCELL.

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Information Hub for alternative financing options

Posted on 06/07/202106/08/2024 by Erik Franco

Tag: Finance, Information hub, alternative finance, knowledge exchange
Researcher: Chiara Franzoni
Department: DIG – Department of Management, Economics and Industrial Engineering

Innovation in leadership and finance had been one of the missions of Horizon 2020. The EU funded ALTFInator project Horizon 2020 addressed this with the goal of easing the access to risk finance for companies and supporting innovation of SMEs across Europe.

ALTFInator developed alternative forms of finance for innovative SMEs with a specific geographical location: countries in Southern, Central and Eastern Europe have less opportunities and know-how of alternative financing, this is true for small and medium enterprises. The rationale behind the project was to map the existing financing framework in the participating countries; to collect and make accessible resource material to entrepreneurs and investors, as well as creating a matching architecture of supply and demand, raising awareness of financing alternatives and best practices through workshops and seminars.

The project concluded in April 2020 with the creation of the dedicated web page: an information database of resource material, news, and available financial providers. Among the relevant outcomes, there are national workshops, international best practice workshops and public roundtables.

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A breakthrough for conductive structured catalysts may lead a step closer to the decarbonization of Europe

Posted on 17/06/202111/10/2021 by admin

Tag: decarbonization, CHP, hydrogen-fuel cells
Researcher: Enrico Tronconi
Department: DENG – Energy Department

European project INSTANT (effIcieNt Small-scale uniT for distributed heAt and hydrogeN generaTion), led by Prof. Enrico Tronconi of the Energy Department, aims to develop an efficient catalytic fuel processor as the key component of a compact unit to produce hydrogen. Based on hydrogen-fuel cells and fed by natural gas, air and water, researchers will develop units for combined heat and power (CHP) generation that may be used in small-scale applications, such as the cogeneration of heat and electricity for domestic residential use or refueling hydrogen-powered fuel cell vehicles. Sustainable on-site and on-demand hydrogen generation will reduce or eliminate the transport and storage costs associated with traditional production technologies, improving their energy efficiency and carbon footprint.

INSTANT, funded with 150,000 € under the Horizon2020 program, is a Proof of Concept ERC project that stems from the AdG ERC INTENT project. INTENT developed and validated the concept for a new generation of catalytic reactors to produce energy carriers, with a revised design based on thermally conductive cellular structures packed with catalyst microparticles. With INSTANT, researchers aim to test this novel configuration of the fuel processor on a semi-industrial scale (TRL5). Indicators which will be evaluated during the test sessions include:

H2 productivity for a given catalyst load (target = +30%);
start-up time to full load (target = -30%);
response time to a load change (target = -30%).

Based on the experimental outcomes, INSTANT will also assess the potential for reducing the footprint of the CHP unit, the system volume being currently one of the main constraints for domestic CHP applications, as well as the overall production cost, including life-cycle costs.

If successful, INSTANT will pave the way to a new generation of CHP systems based on hydrogen fuel cells and explore the commercial and social potential of their research work.

A platform to assist law enforcement agencies in internet forensics

Posted on 10/06/202111/10/2021 by admin

Tag: malware, payments tracking, Internet Forensics
Researcher: Stefano Zanero
Department: DEIB

Crimes are as adaptive as any social behavior, and with technological progress, new threats and issues emerge as well. Offences such as theft and scams are very effective on the internet, and with a relatively low investment perpetrators can steal a great deal of personal information.

RAMSES, a Horizon 2020 project, has had the objective to help Law Enforcement Agencies (LEAs) with digital forensics investigations. Two real-life case studies have been taken into consideration: ransomware and banking Trojans. Researchers used big data technologies to extract, storage, link and interpret information extracted from the internet and to look for patterns of fraudulent behavior.

The project ended in August 2019 and has reached its three main goals: researchers have built guidelines and models shared and made available to LEAs by examining the current landscape of fraudulent activities on the surface and on the deep web as well as have completed a comprehensive examination of best practices around Europe in tackling cyber crime.

Through the use of big data, they were able to search for patterns of fraudulent behaviors and hidden information and were able to build models to track malware payments.

Lastly they have diffused the knowledge and best practices collected in the project at a European level involving all stakeholders and LEAs, by including the experience gathered through the pilot programs that have taken place in the project in three different EU countries (Portugal, Belgium and Spain).

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Visit Ramses2020 Website

Photo by Markus Spiske on Unsplash

A revolution in drug discovery: advanced computer-aided drug design

Posted on 08/06/202111/10/2021 by admin

Tag: Supercomputing, VirtualScreening, HPC, health, COVID-19
Researchers: Cristina Silvano, Gianluca Palermo
Department: DEIB – Department of Electronics, Information and Bioengineering

A drug has been found which is able to counter the SARS-CoV-2 virus, responsible for COVID-19. The drug in question is Raxilofene and it has been identified thanks to the European Exscalate4CoV project, supported by the European Horizon 2020 project for research and innovation, with the collaboration of Politecnico di Milano, Dompé Farmaceutici, Cineca and another 15 partners throughout Europe.

Exscalate4CoV uses the fastest pharmaceutical research platform in the world, created with the collaboration of professors Gianluca Palermo and Cristina Silvano from the Department of Electronics, Information and Bioengineering of Politecnico di Milano. From an archive of about 500 billion molecules, the EXSCALATE platform (EXaSCale smArt pLatform Against paThogEns) is able to select the molecules that meet certain compatibility requirements with the SARS-CoV-2 virus. Thanks to the CINECA supercomputers, researchers have analyzed over 10 million pharmaceutical molecules, identifying in Raxilofene the most promising molecule to inhibit the replication of coronavirus inside human cells. In vitro tests have confirmed the results processed by the platform. Raxilofene has been used for years against osteoporosis and is well-tolerated by the human body: this will make it possible to rapidly move forwards to the clinical test phase on patients affected by COVID-19. “One of the most computationally complex phases was the 3D modeling of the virus proteins, which was unknown until just a few months ago” comments Palermo. “Now we have a good model and the Exscalate platform is able to compare it with over 500 billion molecules in just a few weeks, identifying the molecules able to inhibit the virus from replicating”. With the start of the clinical study, the first phase of the project can now be considered over. Since the approval process to test the drug on people has been completed, the IRCSS Lazzaro Spallanzani in Rome and IRCSS Humanitas in Milan research hospitals have been carrying out trials on 450 patients since the end of October. During the second phase of the project, almost 500 billion molecules will be analyzed, many of these have never been used and are not present in nature. While the wait for the results continues, if one of these compounds proves to be interesting, moving forwards to the clinical phase will take time: tests to verify whether a molecule is toxic for humans can take between 5 and 10 years. This is why the project has prioritized the analysis of drugs already being used for other pathologies.

At the time of writing, researchers are carrying out the largest virtual molecule screening experiment in the world. The Politecnico di Milano team is at the forefront of this experiment, which will be developed using the two most powerful supercomputers in Europe: the ENI HPC5 and the CINECA Marconi-100 system. 70 billion molecules evaluated on 15 active sites of 12 SARS-CoV-2 proteins for a total of over one thousand billion evaluations. This number goes well beyond the “just” 2 billion evaluations carried out at the Oak Ridge National Lab in the United States on a single protein for the same reason, using the second most powerful supercomputer in the world, and the billion evaluations made by the same DOMPE-POLIMI-CINECA work group against the Zika virus, which at the time were considered unique experiments. “The EXSCALATE platform has the peculiar characteristic of being designed from the outset for situations like the one we are living through at the moment, where urgent calculations must be deployed at speeds that only supercomputers can achieve. At the moment, we are carrying out an experiment in only a few days which as little time ago as last year, would have taken tens of months” comments Palermo.

The project is coordinated by Dompè Farmaceutici alongside a multidisciplinary team and aims to continue to collaborate with Politecnico di Milano and CINECA during every phase to develop the EXSCALATE platform, thus accelerating the computational process in the search for new drugs and maximizing the efficiency of the new generation of supercomputers. “However, we are currently directly involved with just the computational challenge which we are really excited about thanks to its uniqueness, but no less important will be the next phase when the research carried out will be more than just an end in itself. The data produced by the simulation will be analyzed by Dompé Farmaceutici to identify interesting molecules that may be active on numerous proteins, and will also be made available to the scientific community”. Thanks to the recent investment decided by Italy and Europe, in October it was announced that a new supercomputer called Leonardo will be installed at CINECA next year, which should reach 250 thousand billion calculations per second (petaflop), 10 times more than the current rate. The Politecnico di Milano team is already geared up for this new challenge, also thanks to a new European project called LIGATE (LIgand Generator AT Exsascale), which will see the DOMPE – POLIMI – CINECA team working together for a further 3 years.

Building a European Fintech risk management platform

Posted on 04/06/202111/10/2021 by admin

Tag: Financial Technology, Risk management, Artificial Intelligence, Blockchain
Researcher: Emilio Barucci
Department: DMAT – Department of Mathematics

Financial Technology (Fin Tech) is financial innovation made possible by innovative technology.

Different countries in Europe have different regulatory landscapes: thus, the European Fin Tech sector has the potential of being more competitive through the establishment of a common regulatory field across all Europe.

The FIN-TECH project (A FINancial supervision and TECHnology compliance training programme), funded under EU’s Horizon2020 scheme, involves 24 universities as well as financial institutions and stakeholders from all 28 state members plus Switzerland. Politecnico di Milano will be a partner of FIN-TECH through the contribution of the Department of Mathematics.

The project has the goal of building a common fintech risk management platform. The platform aims at automatize the compliance of Fin-Tech companies (RegTech) as well as at increasing the efficiency of supervisory activities (SupTech). The exchange of information on risk models and management for fintech companies will lay the foundation of the common platform. The research will have three main sources in gathering information: fintech companies and hubs, regulatory institutes, and universities and research centers. Research on risk models will be also carried out through Big Data analytics, AI and Blockchain technologies.

The diffusion of the findings will also be a core activity of the project, aiming at achieving uniformity across Europe: this will be carried out through training and coding session as well as through the establishment of a dedicated website.

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Cover Photo by Danielle Rice on Unsplash