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  • 2020-2024
  • Open Access
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  • ENEA Open Archive
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  • image/svg+xml art designer at PLoS, modified by Wikipedia users Nina, Beao, JakobVoss, and AnonMoos Open Access logo, converted into svg, designed by PLoS. This version with transparent background. http://commons.wikimedia.org/wiki/File:Open_Access_logo_PLoS_white.svg art designer at PLoS, modified by Wikipedia users Nina, Beao, JakobVoss, and AnonMoos http://www.plos.org/
    Authors: Murra, D.; Aquilini, M.; Bollanti, S.; Di Lazzaro, P.; +4 Authors

    Le lunghezze d’onda comprese tra 200 e 280 nanometri, intervallo spettrale denominato UV-C, sono particolarmente adatte a debellare batteri e virus in quanto tale radiazione spezza i legami proteici e può danneggiare in modo irreversibile le catene del DNA/RNA. Sino a poco tempo fa, le sorgenti UV-C disponibili in commercio erano lampade a gas, basate tipicamente su deuterio, xenon, vapori di mercurio, o eccimeri. Queste lampade funzionano a tensioni piuttosto elevate, sono fragili e hanno tempi di accensione di diversi minuti prima di arrivare a regime ed emettere la potenza nominale. La disponibilità di LED (Light Emitting Diodes, dispositivi a stato solido) che emettono radiazione nell’intervallo dell’UV-C consente oggi di realizzare una “lampada”, basata su una matrice di tali sorgenti, che utilizza un alimentatore a bassa tensione, può essere disegnata in configurazioni geometriche adattabili ad ogni esigenza, si accende istantaneamente ed è meccanicamente molto robusta. In questo Rapporto Tecnico sono illustrati il progetto, la realizzazione e la caratterizzazione di una lampada a LED UV-C e del relativo alimentatore. È inoltre brevemente descritto un esperimento, a scopo fitosanitario, in cui tale lampada è stata utilizzata. Optical radiation with wavelengths between 200 and 280 nanometers, in the UV-C range, is particularly suitable for eradicating bacteria and viruses, as this radiation breaks protein bonds and can irreversibly damage DNA/RNA chains. Until recently, the commercial UV-C sources were gas lamps, typically based on deuterium, xenon, mercury vapor, or excimers. All of these lamps operate at quite high voltages, are fragile and require several minutes of warming up before working at full power. The availability of solid-state LEDs (Light Emitting Diodes) that emit radiation in the UV-C range allows a “lamp” to be made by assembling an array of such light sources, which uses a low-voltage power supply, can be designed in geometric configurations adaptable to any need, turns on/off instantly and is robust. This Technical Report illustrates the work done at ENEA Frascati on the design and assembly of a UVC LED lamp and of its power supply, its characterization and application to a phytosanitary experiment.

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      image/svg+xml art designer at PLoS, modified by Wikipedia users Nina, Beao, JakobVoss, and AnonMoos Open Access logo, converted into svg, designed by PLoS. This version with transparent background. http://commons.wikimedia.org/wiki/File:Open_Access_logo_PLoS_white.svg art designer at PLoS, modified by Wikipedia users Nina, Beao, JakobVoss, and AnonMoos http://www.plos.org/ ENEA Open Archivearrow_drop_down
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    Authors: Monteleone, F.; Anello, F.; Bommarito, C.; Cinelli, G.; +9 Authors

    Il presente rapporto descrive l’Osservatorio ENEA delle Madonie situato in località Piano Battaglia all’interno del Parco regionale delle Madonie nel territorio di Petralia Sottana (PA). L’Osservatorio è costituito da una stazione meteo, installata nel giugno 2016, con lo scopo di misurare i principali parametri meteorologici e da una cabina prefabbricata all’interno della quale è presente un sistema di prelievo di campioni di aria in flasks per la successiva determinazione, nei laboratori ENEA di Lampedusa, della concentrazione di alcuni gas-serra (CO2 e CH4) secondo standard internazionali. Il report, pur riportando in forma grafica i dati delle misure settimanali di anidride carbonica e metano a partire dal 2005, analizza i dati delle osservazioni meteorologiche in forma grafica e tabellare dal 1° luglio 2016 al 31 dicembre 2022. L’alta quota, la posizione geografica, l’assenza di contaminazioni locali e l’accuratezza delle misure rendono la stazione di “Madonie - Piano Battaglia”, un punto di eccellenza per il monitoraggio e lo studio dei complessi meccanismi legati al cambiamento climatico a scala regionale e globale; per tali specificità l’Organizzazione Meteorologica Mondiale (OMM) nel 2021 ha conferito all’Osservatorio ENEA delle Madonie il riconoscimento ufficiale di stazione regionale, rappresentativa per tutta l’area del Mediterraneo centrale, nell’ambito del Global Atmosphere Watch (GAW), la rete mondiale per lo studio del clima globale (https://gawsis.meteoswiss.ch/GAWSIS/#/search/station/stationReportDetails/ 0-380-0-MDN ). This report describes the ENEA Climate Observatory located in Piano Battaglia within the Madonie Regional Park in the territory of Petralia Sottana (PA). The Observatory consists of a weather station installed in June 2016 with the aim of measuring the main meteorological parameters and a prefabricated cabin hosting is a system for collecting air samples in flasks for the subsequent determination, in the ENEA laboratories of Lampedusa, of the concentration of some greenhouse gases (CO2 and CH4) according to international standards. The report, while reporting in graphical form the data of weekly measurements of carbon dioxide and methane starting from 2005, analyzes the meteorological parameters in graphical and tabular form from 1 July 2016 to 31 December 2022. The high altitude, the geographical position, the absence of local contamination and the accuracy of the measurements make the “Madonie-Piano Battaglia” station a point of excellence for monitoring and studying the complex mechanisms of climate change at regional and global scale; for these specificities, in 2021 the World Meteorological Organization (WMO) awarded the ENEA Madonie Observatory the official recognition of regional station, representative for the entire central Mediterranean area, within the Global Atmosphere Watch (GAW), the global network for the study of the global climate (https://gawsis.meteoswiss.ch/GAWSIS/#/search/station/stationReportDetails/0-380-0-MDN).

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    Authors: Zona, R.; Rosi, G.; Santagata, A.;

    Il Reattore Sorgente Veloce Taratura Pila Rapida a potenza zero (R.S.V. TAPIRO) fu concepito agli inizi degli anni ’60 dai ricercatori del Comitato Nazionale per l’Energia Nucleare (CNEN), come strumento di supporto al programma italiano sui reattori veloci. Dall’approvazione del progetto nel 1965, dopo solo 5 anni e mezzo, il 2 aprile del 1971 il TAPIRO produsse il suo primo flusso stabile di neutroni rag- giungendo la sua prima criticità. Da allora, il reattore nucleare di ricerca TAPIRO è stato utilizzato come sorgente di neutroni veloci per diverse attività di ricerca nell’ambito dell’aerospazio, della fusione nu- cleare, del bruciamento degli attinidi minori, degli acceleratori di particelle, della misura di sezioni d’urto, del danneggiamento biologico... Questo documento raccoglie la storia delle prime fasi di pro- gettazione e realizzazione dell’impianto e le principali attività effettuate nei successivi 50 anni. A com- pletare il documento c’è un elenco della documentazione tecnica prodotta nella fase di progettazione e delle pubblicazioni realizzate sulla base dei risultati sperimentali ottenuti con i neutroni prodotti dal TAPIRO. The zero-power fast research reactor TAPIRO was conceived in the early 1960s by the researchers of the Italian National Committee for Nuclear Energy (CNEN) to assist the Italian program on fast nuclear reactors. After the approval of the project in 1965, only 5 and a half years later, on April 2, 1971, TAPIRO provided its first stable neutron flux reaching its first criticality. Since then, the TAPIRO nuclear research reactor has been used as a source of fast neutrons for several research activities in the fields of aero-space, nuclear fusion, burning of mino years. To complete the document there is a list of the technical documentation produced in the design phase and actinides, particle accelerators, neutron cross sections measu- rement, biological damage.This document collects the history of the first phases of design and construction of the installation and the main activities carried out in the following 50 of the publications cresis of the experimental results obtained with the neutrons produced by TAPIRO.

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    ENEA Open Archive
    Other ORP type . 2021
    Data sources: ENEA Open Archive
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    Authors: Campiotti, C. A.; Gatti, L.; Giagnacovo, G.; Latini, A.; +16 Authors

    Il Rapporto Tecnico riporta alcuni risultati dell’attività di ricerca, sulla tematica “Sistemi verdi per la rigenerazione ecologica delle città”, condotta dal gruppo afferente al Laboratorio DUEE-SIST-NORD nell’ambito del Programma italiano “Ricerca di Sistema Elettrico” (RdS). La sperimentazione si è svolta principalmente sull’edificio F92 denominato “Scuola delle Energie” presso il CR ENEA Casaccia, nel quale sono stati implementati dei prototipi di “sistemi verdi” quali tetto, parete e serra bioclimatica “verdi”. Il Rapporto Tecnico è strutturato nelle due seguenti parti. Nella prima parte, viene trattato il contributo del verde per l’efficientamento energetico degli edifici. Sono inclusi un capitolo sulla metodologia dell’analisi del ciclo di vita (LCA) orientata all’aumento della sostenibilità ambientale attraverso tali infrastrutture verdi in città; un capitolo sulle tecniche di Remote Sensing & Geographic Information System (GIS) per valutarne l’efficienza ambientale, ed un capitolo sugli strumenti normativi cogenti e volontari per la loro implementazione a livello nazionale ed Europeo. Nella seconda parte, vengono trattati alcuni tra i più importanti benefici per l’ambiente, e quindi per la società, riconosciuti ai sistemi verdi in città, dovuti alle proprietà fisiologiche delle piante. Nei diversi capitoli vengono argomentati i numerosi servizi ecosistemici (SE), incluse le potenzialità di tali sistemi di mitigare l’effetto isola di calore in città, migliorando il clima locale, e di attenuare l’inquinamento dell’aria ambiente, migliorando la qualità dell’aria che si respira in città. Si sottolinea anche il ruolo del verde nella connessione ecologica tra le aree naturali volte a garantire la conservazione della biodiversità. The Technical Report reports some results of the research activity, on “greenery systems for the urban ecological regeneration”, carried out by the DUEE-SIST-NORD Laboratory group within the Italian Program " Electric System Research" (RdS). The experimentation took place mainly on the so-called “School of Energy” F92 building, at ENEA Casaccia RC, where of "green systems" prototypes for a green roof, wall and bioclimatic greenhouse have been implemented. This Technical Report is structured into two sections. In the first section, the contribution of greenery to the increase of energy efficiency in buildings is discussed. A chapter on the life cycle analysis (LCA) methodology, aimed at increasing environmental sustainability through green infrastructures in the city, and a chapter on Remote Sensing & Geographic Information System (GIS) techniques, for assessing assess their environmental efficiency, have been included here. Furthermore, a chapter is dedicated to the existing regulatory tools, either mandatory as voluntary, which sustain the implementation of these plant systems in cities at both the national and the European levels. In the second section, some of the most important benefits provided by the green systems in cities to the environment and to the people are discussed. In the various chapters, the numerous ecosystem services (ES) are discussed, including the potential of these green systems to mitigate the urban heat island effect thus improving the local climate, and to mitigate ambient air pollution thus improving the air quality in cities. In addition, the key role played by urban greenery systems in the ecological connections among natural areas for ensuring the conservation of biodiversity is also emphasized.

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    Authors: Pierro, N.; Giocoli, A.; De Bari, I.; Agostini, A.; +2 Authors

    Il Piano Nazionale Integrato per l’Energia e il Clima del 2019, assegna un ruolo prioritario al gas rinnovabile al fine del raggiungimento dei target di immissione al consumo di biocarburanti previsto dalla direttiva sulla promozione dell'uso dell'energia da fonti rinnovabili -RED II- in Unione Europea. In particolare si prevede nell’arco temporale 2021-2030 di applicazione del piano, nel settore trasporti, un utilizzo di biometano avanzato in forte crescita per arrivare nel 2030 a un consumo pari a 800 ktep annui (circa 1,1 miliardi di m3) rispetto ai 82 ktep di biometano avanzato immesso al consumo nel 2020 (Gestore Servizi Energetici s.p.a). Le stime di questo studio riguardano il potenziale teorico di biometano avanzato producibile in Italia da digestione anaerobica. Il potenziale determinato è teorico in quanto non tiene conto di un possibile uso alternativo dei substrati, quale ad esempio uso diretto (lasciato in campo, combustione o compostaggio), o di filiere di produzione di prodotti biobased(e.g. biopolimeri, biolubrificanti, biodiesel, altri intermediari di processi chimici, etc.) e/o di altri biocarburanti. La stima su base territoriale delle varie biomasse residuali fermentabili realizzata in questo studio, in termini quantitativi e di producibilità di biometano avanzato da upgrading del biogas, ha il grande vantaggio di contenere quel valore di allocazione geografica che permetterà una più corretta valutazione degli elementi di logistica ed integrazione delle reti energetiche con l’obiettivo di fornire agli stakeholders della filiera biogas-biometano avanzato una base dati su cui formulare studi di fattibilità di un sistema integrato di produzione. Il potenziale totale teorico calcolato con dati aggiornati al 2016 è valutato pari a circa 6,2 miliardi di m3 all’anno di biometano avanzato, ovvero un valore che ha lo stesso ordine di grandezza del gas naturale di origine fossile prodotta in Italia nel 2016 (6,0 miliardi di m3) e che è pari a circa l’8,7% dei consumi totali dello stesso anno (70,9 miliardi di m3). The Integrated National Plan for Energy and Climate (PNIEC) of 2019, assigns a priority role to renewable gas in order to achieve the targets for injection to the consumption of biofuels envisaged by the directive on the promotion of the use of energy from renewable sources (REDII) in the European Union, foreseeing in the 2021-2030 period of application of the plan, in the transport sector, the use of advanced biomethane in strong growth to reach a consumption of 800 ktoe per year in 2030 (about 1,1 billion m3) compared to 82 ktoe of advanced biomethane in 2020 (Gestore Servizi Energetici s.p.a). The estimates of this study concern the theoretical potential of advanced biomethane that can be produced in Italy by anaerobic digestion. The determined potential is theoretical as it doesn’t take into account a possible alternative use of the substrates, for example direct use (left in the field, combustion or composting), or of production chains of biomaterials and/or other biofuels (e.g. biopolymers, biolubricants, biodiesel, other intermediaries of chemical processes, etc.). The estimate on a territorial basis of the various residual fermentable biomasses carried out in this study, in terms of quantities and producibility of advanced biomethane from biogas upgrading, has the great advantage of containing that value of geographical allocation that will allow a more correct evaluation of the elements of logistics and integration of energy networks with the aim of providing stakeholders in the advanced biogasbiomethane chain with a database on which to formulate feasibility studies of an integrated production system. The total theoretical potential calculated with data updated to 2016 is estimated to be approximately 6,2 billion m3 per year of advanced biomethane, i.e. a value that has the same order of magnitude as natural gas of fossil origin produced in Italy in 2016 (6,0 billion of m3) and which is equal to approximately 8,7% of total consumption in the same year (70,9 billion m3).

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    ENEA Open Archive
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      ENEA Open Archive
      Other ORP type . 2021
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    Authors: Bacchetta, L.; Bernabei, L.; Bollanti, S.; Di Lazzaro, P.; +4 Authors

    Sono riportati in letteratura risultati di irraggiamenti di specie vegetali con radiazione ‘ultravioletta C’ (UV-C), che evidenziano una drastica riduzione della presenza di patogeni e di malattie pre- e postraccolta delle colture. Si tratta di una promettente tecnologia alternativa ai pesticidi, l’uso dei quali deve essere ridotto perché contribuisce all’inquinamento di suolo, acqua, e aria, e rappresenta un rischio per la salute di operatori e consumatori. I migliori effetti germicidi UV-C sono stati ottenuti usando lampade a mercurio a bassa pressione, che emettono radiazione alla lunghezza d’onda di 254 nm. Viceversa, i tentativi di ottenere effetti di ormesi usando lo stesso tipo di lampade hanno prodotto risultati incerti. Per ormesi intendiamo la stimolazione -tramite radiazione UV-C- di metaboliti in grado di aumentare le difese immunitarie naturali delle piante e quindi la resistenza ai patogeni. In questo Rapporto si descrive l'efficacia dei raggi UV-C alla lunghezza d’onda di 277 nm, emessi da matrici di Light Emitting Diodes (LED), per generare una risposta ormetica in piante di basilico, frutti di mele, fragole e limoni dopo irraggiamento ed esposizione ai patogeni fungini Botrytis cinerea e Pennicillium digitatum. I LED sono sorgenti di radiazione a stato solido che offrono diversi vantaggi rispetto alle lampade: sono più compatti, hanno maggiore resistenza agli urti, tempo di accensione immediato, possibilità di scegliere la lunghezza d’onda della radiazione UV-C tale da accordarsi sullo spettro di assorbimento dei patogeni senza generare ozono, ed un’alimentazione elettrica più semplice, a basso voltaggio. Excellent results have been reported on ultraviolet C (UV-C) radiation to limit pre- and post-harvest diseases of fruit and vegetable crops. UV-C radiation appears a promising and sustainable technological substitute for pesticides, the use of which must be reduced because it damages the environment, and the health of operators and consumers. The best germicidal effects have been obtained using lowpressure mercury lamps, which emit radiation at a wavelength of 254 nm. Conversely, attempts to obtain hormesis effects using mercury lamps have produced uncertain results. Here for hormesis we mean a stimulation -through UV-C electromagnetic radiation- designed to increase the natural immune defenses, and therefore, resistance to pathogens. We have explored the effectiveness of a different UV-C wavelength (277 nm) emitted by Light Emitting Diodes (LED) to stimulate hormesis in basil plants, apples, strawberries, and lemons, after irradiation and exposure to the fungal pathogen Botrytis cinerea and Pennicillium digitatum. The LED are solid-state UV-C radiation sources that offer several advantages vs. the lamps: LED are much more compact, have greater resistance to shocks, shorter ignition time, a simpler electrical circuitry with a low working voltage, and choice of the wavelength of UV-C radiation such as not to generate ozone.

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    Authors: Zimbardi, F.; Viola, E.; Arcieri, G.; Valerio, V.; +1 Authors

    Il pretrattamento di biomassa lignocellulosica per la sua trasformazione in biofuels e chemicals si basa su processi di trasformazione e separazione condotti a temperature relativamente elevate. Generalmente possono essere prodotte molecole aventi un effetto inibitorio rispetto ai successivi processi di fermentazione. Questi inibitori sono abbastanza facilmente allontanati mediante lavaggi con liquidi che però rimuovono anche i carboidrati solubili. Considerando che gli inibitori sono per lo più molecole a basso peso molecolare, è nata l’idea di provare ad allontanarli sfruttandone la volatilità. In questo lavoro è riportata una tecnica innovativa specificatamente messa a punto dagli autori per rimuovere gli inibitori formatisi nel pretrattamento di steam explosion di biomasse lignocellulosiche. Si è iniziato realizzando un proof of concept (TRL 2-3) con cui è stato dimostrato come fosse possibile detossificare un substrato lignocellulosico sfruttando la volatilità di alcune classi di inibitori. Il metodo è stato validato e perfezionato in laboratorio (TRL 4) e successivamente dimostrato e qualificato in un ambiente rilevante, anche sotto il profilo industriale, utilizzando una apparecchiatura commerciale operante a valle dell’impianto di pretrattamento steam explosion da 150 kg/h STELE installato nel Centro Ricerche ENEA della Trisaia (MT). É stato quindi raggiunto il TRL 8 in linea con quanto auspicato dal progetto PRIT (PRetrattamento Italiano), finanziato e realizzato nell’ambito del programma Industria 2015, nel cui contesto la ricerca è stata condotta. Sono stati ideati e dimostrate con successo 3 modalità operative: 1) Reattore a letto fisso consistente in un tubo di vetro incamiciato (termostatabile) all’interno del quale è confinato il materiale esploso contenente gli inibitori. 2) Reattore a letto fluidizzato consistente in un tubo di vetro simile al precedente ma oscillante. Infatti, contemporaneamente a un flusso di aria calda, il tubo è sottoposto a un’oscillazione verticale realizzata mediante aggancio con biella a un motore elettrico a numero di giri variabile. 3) Essiccatore pilota a letto fluidizzato. The pretreatment of lignocellulosic biomass for its transformation first into carbohydrates and then from these, through fermentation processes, into biofuels and chemicals, often involves the use of high-temperature techniques. This produces compounds derived from degradation processes which are called "inhibitors" because they hinder the microbial fermentation processes. Generally, inhibitors are low molecular weight molecules, therefore volatile. Inhibitors are commonly removed by washing with water; however water also removes the soluble carbohydrates. In this work, a specific and innovative removal technique of these inhibitors is reported. The substrate is biomass pretreated by steam explosion. We started by creating a proof of concept (TRL 2-3) with which it was demonstrated how it was possible to detoxify a lignocellulosic substrate by exploiting the volatility of some classes of inhibitors. The method was validated and perfected in the laboratory (TRL 4) and subsequently demonstrated and qualified in a relevant environment, also from an industrial point of view, using commercial equipment operating continuously downstream of the 150 kg / h steam explosion pretreatment plant STELE installed in the ENEA Research Center in Trisaia (MT). A TRL 8 was therefore achieved, in line with what was hoped for by the PRIT (PRetrattamento Italiano) project, funded and implemented under the 2015 Industry program and in the context of which the research was conducted. Overall, 3 types of equipment have been designed, realized and tested: 1) Fixed bed reactor consisting of a jacketed glass tube (thermostatable) inside which the exploded material containing the inhibitors is confined. 2) Fluidized bed reactor consisting in a glass tube similar to the previous one but oscillating. In fact, at the same time as a flow of hot air, the tube is subjected to a vertical oscillation achieved by coupling with a connecting rod to an electric motor with a variable number of revolutions. 3) Pilot fluidized bed dryer.

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    ENEA Open Archive
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    Authors: Violante, A. C.; Guidi, G.; Trinchieri, R.; Proposito, M.;

    Questo Rapporto descrive le attività svolte durante la prima annualità del Piano Triennale di realizzazione 2019-2021 della Ricerca di Sistema Elettrico Nazionale, riguardanti la linea di attività 1.7 denominata “Tecnologie per la penetrazione efficiente del vettore elettrico negli usi finali”. Lo studio in oggetto è stato anzitutto indirizzato alla ricostruzione dell’assetto litologico-stratigrafico e idrogeologico dell’area del C.R. ENEA-Casaccia, attraverso il reperimento sistematico e la consultazione di tutti i dati di letteratura disponibili e delle stratigrafie dei sondaggi geognostici effettuati nel C.R. Casaccia. La valutazione geologica ha permesso inoltre di estrapolare il valore di conducibilità termica delle rocce presenti nell’area e di individuare il sito in cui insisterà il sistema di approvvigionamento del calore dal terreno, utilizzando sonde geotermiche verticali accoppiate a una pompa di calore (PdC) acqua-acqua. Successivamente, è stata condotta una simulazione dei carichi termici assumendo come target, per la sorgente terreno, la climatizzazione di un ufficio (con superficie di 140 m2 circa, situato nell’edificio F40 del C.R. Casaccia, adiacente al campo geosonde). Tramite un software dedicato è stato possibile dimensionare le sonde inserendo i valori dei carichi di picco invernali ed estivi. Si prevede di realizzare 4 pozzi, profondi rispettivamente 35 m, 50 m, 80 m e 100 m. Il campo geosonde sarà dotato di un sistema di controllo mediante fibre ottiche impiantate direttamente all’interno dei tubi in polietilene, al fine di monitorare costantemente i valori termometrici all’interno di ogni pozzo e quindi definire il campo termico, la sua evoluzione nell’arco delle stagioni, e non ultimo l’efficienza del sistema sonde-terreno nel tempo. Infine, è stato stimato il valore della potenza termica estratta durante l’inverno e stoccata in estate, il consumo energetico della pompa di calore e le emissioni di CO2 e NOX. This Report deals with the activities carried out during the first year of the 2019-2021 Three-Year Implementation Plan for National Electricity System Research, concerning line 1.7 “Tecnologie per la penetrazione efficiente del vettore elettrico negli usi finali”. First, this study was aimed at reconstructing the lithological-stratigraphic and hydrogeological structure of the area of the ENEA-Casaccia Research Centre, through the systematic retrieval and consultation of all the available literature data and the stratigraphies of the geognostic drillings carried out at the C.R. Casaccia. The geological assessment also allowed the extrapolation of the thermal conductivity value of the rocks in the area and to identify the site where the ground heat supply system will be installed, using vertical geothermal probes coupled with a water-water heat pump (HP). Subsequently, a simulation of thermal loads was conducted, assuming as the target, for the ground source, the air conditioning of an office (with a surface area of approximately 140 m2, located in building F40 of C.R. Casaccia, adjacent to the geothermal probe field). Using dedicated software, it was possible to size the probes by entering the winter and summer peak load values. Four boreholes are planned: 35 m, 50 m, 80 m and 100 m deep, respectively. The geothermal probe field will be equipped with a control system using optical fibres implanted directly inside the polyethylene pipes, to constantly monitor the thermometric values inside each well and thus define the thermal field, its evolution over the seasons, and not least the efficiency of the probe-soil system over time. Finally, the value of the thermal power extracted in winter and stored in summer, the energy consumption of the HP and CO2 and NOX emissions were estimated.

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    Authors: Zini, A.; Roberto, R.; Corrias, P.; Felici, B.;

    Il testo si propone come rassegna ragionata, corredata delle informazioni statistiche disponibili, circa il tema delle “materie prime critiche” (Critical Raw Materials, CRM), con particolare riferimento alla dimensione della transizione energetica. Si tratta di un gruppo di commodities che sono particolarmente richieste nell’ambito delle tecnologie energetiche a basse emissioni di carbonio, o sembrano in grado di contribuire a diminuire i consumi energetici nell’attuale, o nel più prossimo, assetto tecnologico, produttivo e commerciale. La scommessa dell’attuale fase storica sta anche nel garantire un adeguato sistema di approvvigionamento di metalli e minerali che in alcuni casi potrebbero rivelarsi disponibili in quantità minori rispetto alla potenziale domanda mondiale. La loro concentrazione geografica pone peraltro nuove questioni alla gestione delle negoziazioni politiche e commerciali tra i paesi, mentre laddove si esprime in aree geografiche turbolente, o caratterizzate dall’assenza di sistemi di tutela - dell’ambiente, della salute e della sicurezza dei lavoratori - richiede l’attenzione al rispetto degli standard minimi di accettabilità etica e sociale. Il volume intende quindi toccare alcuni aspetti di metodo del problema, quali la definizione stessa di “materia prima critica” e il confronto tra le diverse angolazioni - come espresse nelle analisi e classificazioni prodotte da alcuni organismi internazionali - per poi passare a trattare la richiesta di CRM da parte delle tecnologie per la transizione energetica. Segue una disamina della concentrazione geografica mondiale dei metalli e minerali e delle nuove politiche europee in risposta alle difficoltà riscontrate in tema di approvvigionamenti, relazioni industriali e scambi commerciali, senza trascurare alcune problematiche strettamente legate alla realtà italiana. The paper is a critical review of 'Critical Raw Materials' (CRMs), with particular reference to the energy transition dimension. Critical Raw Materials are a group of commodities that are particularly needed for low-carbon energy technologies, and in applications that can contribute to lower energy consumption in the current, or near future, technological, production and commercial set-up. The challenge of the current historical phase also lies in ensuring an adequate supply system of metals and minerals that in some cases may turn out to be available in smaller quantities than the potential world demand. Their geographical concentration also poses new questions to the management of political and trade negotiations between countries. In geographical areas that are turbulent or characterized by the absence of protection systems - for the environment, health and safety of workers - the supply of metals and minerals requires attention to compliance with minimum standards of ethical and social acceptability. The paper therefore intends to address some methodological aspects of the problem. Firstly, the definition of 'critical raw material' and the comparison between the different points of view expressed in the analyses and classifications produced by some international bodies. Next, the demand for CRM from energy transition technologies is analyzed. This is followed by an examination of the world geographical concentration of metals and minerals and the new European policies in response to the difficulties encountered in terms of supplies, industrial and trade exchanges, without neglecting some issues closely linked to the Italian reality.

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    Authors: Rondino, F.; Reale, P.; Orsetti, V.; Santoni, A.; +3 Authors

    Nell’ambito dello studio di nuovi materiali anodici per migliorare le prestazioni delle batterie Li-ione, abbiamo cresciuto nanofili di silicio su substrato di carbon paper mediante Chemical Vapour Deposition (CVD), utilizzando come metallo catalizzatore nanoparticelle di rame. In questo rapporto verrà messo in evidenza come l’ottimizzazione dei parametri di crescita sia un passaggio cruciale per crescere nanofili con la morfologia idonea per il loro utilizzo come materiale anodico nelle batterie. In particolare, vengono mostrati i risultati ottenuti sulla morfologia e struttura dei nanofili variando opportunatamente parametri di flusso, pressione del gas precursore e durata della crescita. I campioni ottenuti sono stati analizzati mediante Scanning Electron Microscopy (SEM), Trasmission Electron Microscopy (TEM) e X-Ray Photoelectron Spectroscopy (XPS) ottenendo importanti informazioni morfologiche sulla dimensione dei nanofili e sulla loro struttura. I nanofili così ottenuti verranno poi caratterizzati elettrochimicamente per il loro utilizzo come anodi.. In the research field of new anodic materials for improving the Li-ion batteries performance, we have grown silicon nanowires on carbon paper substrate by Cu-catalysed Chemical Vapour Deposition (CVD) method. In this report, great effort is aimed at the optimization of the growth parameters to obtain nanowires with a morphology suitable for their application as anodes in lithium ion batteries. In particular, recent results on the morphology and structure of Si nanowires obtained changing the flux and pressure of the precursor gas and the growth time are shown. The samples are analysed by Scanning Electron Microscopy (SEM), Trasmission Electron Microscopy (TEM) and X-Ray Photoelectron Spectroscopy (XPS) in order to obtain fundamental information on the dimension and structure of nanowires. Then the samples will be electrochemically characterized for their use as anodes.

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  • image/svg+xml art designer at PLoS, modified by Wikipedia users Nina, Beao, JakobVoss, and AnonMoos Open Access logo, converted into svg, designed by PLoS. This version with transparent background. http://commons.wikimedia.org/wiki/File:Open_Access_logo_PLoS_white.svg art designer at PLoS, modified by Wikipedia users Nina, Beao, JakobVoss, and AnonMoos http://www.plos.org/
    Authors: Murra, D.; Aquilini, M.; Bollanti, S.; Di Lazzaro, P.; +4 Authors

    Le lunghezze d’onda comprese tra 200 e 280 nanometri, intervallo spettrale denominato UV-C, sono particolarmente adatte a debellare batteri e virus in quanto tale radiazione spezza i legami proteici e può danneggiare in modo irreversibile le catene del DNA/RNA. Sino a poco tempo fa, le sorgenti UV-C disponibili in commercio erano lampade a gas, basate tipicamente su deuterio, xenon, vapori di mercurio, o eccimeri. Queste lampade funzionano a tensioni piuttosto elevate, sono fragili e hanno tempi di accensione di diversi minuti prima di arrivare a regime ed emettere la potenza nominale. La disponibilità di LED (Light Emitting Diodes, dispositivi a stato solido) che emettono radiazione nell’intervallo dell’UV-C consente oggi di realizzare una “lampada”, basata su una matrice di tali sorgenti, che utilizza un alimentatore a bassa tensione, può essere disegnata in configurazioni geometriche adattabili ad ogni esigenza, si accende istantaneamente ed è meccanicamente molto robusta. In questo Rapporto Tecnico sono illustrati il progetto, la realizzazione e la caratterizzazione di una lampada a LED UV-C e del relativo alimentatore. È inoltre brevemente descritto un esperimento, a scopo fitosanitario, in cui tale lampada è stata utilizzata. Optical radiation with wavelengths between 200 and 280 nanometers, in the UV-C range, is particularly suitable for eradicating bacteria and viruses, as this radiation breaks protein bonds and can irreversibly damage DNA/RNA chains. Until recently, the commercial UV-C sources were gas lamps, typically based on deuterium, xenon, mercury vapor, or excimers. All of these lamps operate at quite high voltages, are fragile and require several minutes of warming up before working at full power. The availability of solid-state LEDs (Light Emitting Diodes) that emit radiation in the UV-C range allows a “lamp” to be made by assembling an array of such light sources, which uses a low-voltage power supply, can be designed in geometric configurations adaptable to any need, turns on/off instantly and is robust. This Technical Report illustrates the work done at ENEA Frascati on the design and assembly of a UVC LED lamp and of its power supply, its characterization and application to a phytosanitary experiment.

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  • image/svg+xml art designer at PLoS, modified by Wikipedia users Nina, Beao, JakobVoss, and AnonMoos Open Access logo, converted into svg, designed by PLoS. This version with transparent background. http://commons.wikimedia.org/wiki/File:Open_Access_logo_PLoS_white.svg art designer at PLoS, modified by Wikipedia users Nina, Beao, JakobVoss, and AnonMoos http://www.plos.org/
    Authors: Monteleone, F.; Anello, F.; Bommarito, C.; Cinelli, G.; +9 Authors

    Il presente rapporto descrive l’Osservatorio ENEA delle Madonie situato in località Piano Battaglia all’interno del Parco regionale delle Madonie nel territorio di Petralia Sottana (PA). L’Osservatorio è costituito da una stazione meteo, installata nel giugno 2016, con lo scopo di misurare i principali parametri meteorologici e da una cabina prefabbricata all’interno della quale è presente un sistema di prelievo di campioni di aria in flasks per la successiva determinazione, nei laboratori ENEA di Lampedusa, della concentrazione di alcuni gas-serra (CO2 e CH4) secondo standard internazionali. Il report, pur riportando in forma grafica i dati delle misure settimanali di anidride carbonica e metano a partire dal 2005, analizza i dati delle osservazioni meteorologiche in forma grafica e tabellare dal 1° luglio 2016 al 31 dicembre 2022. L’alta quota, la posizione geografica, l’assenza di contaminazioni locali e l’accuratezza delle misure rendono la stazione di “Madonie - Piano Battaglia”, un punto di eccellenza per il monitoraggio e lo studio dei complessi meccanismi legati al cambiamento climatico a scala regionale e globale; per tali specificità l’Organizzazione Meteorologica Mondiale (OMM) nel 2021 ha conferito all’Osservatorio ENEA delle Madonie il riconoscimento ufficiale di stazione regionale, rappresentativa per tutta l’area del Mediterraneo centrale, nell’ambito del Global Atmosphere Watch (GAW), la rete mondiale per lo studio del clima globale (https://gawsis.meteoswiss.ch/GAWSIS/#/search/station/stationReportDetails/ 0-380-0-MDN ). This report describes the ENEA Climate Observatory located in Piano Battaglia within the Madonie Regional Park in the territory of Petralia Sottana (PA). The Observatory consists of a weather station installed in June 2016 with the aim of measuring the main meteorological parameters and a prefabricated cabin hosting is a system for collecting air samples in flasks for the subsequent determination, in the ENEA laboratories of Lampedusa, of the concentration of some greenhouse gases (CO2 and CH4) according to international standards. The report, while reporting in graphical form the data of weekly measurements of carbon dioxide and methane starting from 2005, analyzes the meteorological parameters in graphical and tabular form from 1 July 2016 to 31 December 2022. The high altitude, the geographical position, the absence of local contamination and the accuracy of the measurements make the “Madonie-Piano Battaglia” station a point of excellence for monitoring and studying the complex mechanisms of climate change at regional and global scale; for these specificities, in 2021 the World Meteorological Organization (WMO) awarded the ENEA Madonie Observatory the official recognition of regional station, representative for the entire central Mediterranean area, within the Global Atmosphere Watch (GAW), the global network for the study of the global climate (https://gawsis.meteoswiss.ch/GAWSIS/#/search/station/stationReportDetails/0-380-0-MDN).

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  • image/svg+xml art designer at PLoS, modified by Wikipedia users Nina, Beao, JakobVoss, and AnonMoos Open Access logo, converted into svg, designed by PLoS. This version with transparent background. http://commons.wikimedia.org/wiki/File:Open_Access_logo_PLoS_white.svg art designer at PLoS, modified by Wikipedia users Nina, Beao, JakobVoss, and AnonMoos http://www.plos.org/
    Authors: Zona, R.; Rosi, G.; Santagata, A.;

    Il Reattore Sorgente Veloce Taratura Pila Rapida a potenza zero (R.S.V. TAPIRO) fu concepito agli inizi degli anni ’60 dai ricercatori del Comitato Nazionale per l’Energia Nucleare (CNEN), come strumento di supporto al programma italiano sui reattori veloci. Dall’approvazione del progetto nel 1965, dopo solo 5 anni e mezzo, il 2 aprile del 1971 il TAPIRO produsse il suo primo flusso stabile di neutroni rag- giungendo la sua prima criticità. Da allora, il reattore nucleare di ricerca TAPIRO è stato utilizzato come sorgente di neutroni veloci per diverse attività di ricerca nell’ambito dell’aerospazio, della fusione nu- cleare, del bruciamento degli attinidi minori, degli acceleratori di particelle, della misura di sezioni d’urto, del danneggiamento biologico... Questo documento raccoglie la storia delle prime fasi di pro- gettazione e realizzazione dell’impianto e le principali attività effettuate nei successivi 50 anni. A com- pletare il documento c’è un elenco della documentazione tecnica prodotta nella fase di progettazione e delle pubblicazioni realizzate sulla base dei risultati sperimentali ottenuti con i neutroni prodotti dal TAPIRO. The zero-power fast research reactor TAPIRO was conceived in the early 1960s by the researchers of the Italian National Committee for Nuclear Energy (CNEN) to assist the Italian program on fast nuclear reactors. After the approval of the project in 1965, only 5 and a half years later, on April 2, 1971, TAPIRO provided its first stable neutron flux reaching its first criticality. Since then, the TAPIRO nuclear research reactor has been used as a source of fast neutrons for several research activities in the fields of aero-space, nuclear fusion, burning of mino years. To complete the document there is a list of the technical documentation produced in the design phase and actinides, particle accelerators, neutron cross sections measu- rement, biological damage.This document collects the history of the first phases of design and construction of the installation and the main activities carried out in the following 50 of the publications cresis of the experimental results obtained with the neutrons produced by TAPIRO.

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    Authors: Campiotti, C. A.; Gatti, L.; Giagnacovo, G.; Latini, A.; +16 Authors

    Il Rapporto Tecnico riporta alcuni risultati dell’attività di ricerca, sulla tematica “Sistemi verdi per la rigenerazione ecologica delle città”, condotta dal gruppo afferente al Laboratorio DUEE-SIST-NORD nell’ambito del Programma italiano “Ricerca di Sistema Elettrico” (RdS). La sperimentazione si è svolta principalmente sull’edificio F92 denominato “Scuola delle Energie” presso il CR ENEA Casaccia, nel quale sono stati implementati dei prototipi di “sistemi verdi” quali tetto, parete e serra bioclimatica “verdi”. Il Rapporto Tecnico è strutturato nelle due seguenti parti. Nella prima parte, viene trattato il contributo del verde per l’efficientamento energetico degli edifici. Sono inclusi un capitolo sulla metodologia dell’analisi del ciclo di vita (LCA) orientata all’aumento della sostenibilità ambientale attraverso tali infrastrutture verdi in città; un capitolo sulle tecniche di Remote Sensing & Geographic Information System (GIS) per valutarne l’efficienza ambientale, ed un capitolo sugli strumenti normativi cogenti e volontari per la loro implementazione a livello nazionale ed Europeo. Nella seconda parte, vengono trattati alcuni tra i più importanti benefici per l’ambiente, e quindi per la società, riconosciuti ai sistemi verdi in città, dovuti alle proprietà fisiologiche delle piante. Nei diversi capitoli vengono argomentati i numerosi servizi ecosistemici (SE), incluse le potenzialità di tali sistemi di mitigare l’effetto isola di calore in città, migliorando il clima locale, e di attenuare l’inquinamento dell’aria ambiente, migliorando la qualità dell’aria che si respira in città. Si sottolinea anche il ruolo del verde nella connessione ecologica tra le aree naturali volte a garantire la conservazione della biodiversità. The Technical Report reports some results of the research activity, on “greenery systems for the urban ecological regeneration”, carried out by the DUEE-SIST-NORD Laboratory group within the Italian Program " Electric System Research" (RdS). The experimentation took place mainly on the so-called “School of Energy” F92 building, at ENEA Casaccia RC, where of "green systems" prototypes for a green roof, wall and bioclimatic greenhouse have been implemented. This Technical Report is structured into two sections. In the first section, the contribution of greenery to the increase of energy efficiency in buildings is discussed. A chapter on the life cycle analysis (LCA) methodology, aimed at increasing environmental sustainability through green infrastructures in the city, and a chapter on Remote Sensing & Geographic Information System (GIS) techniques, for assessing assess their environmental efficiency, have been included here. Furthermore, a chapter is dedicated to the existing regulatory tools, either mandatory as voluntary, which sustain the implementation of these plant systems in cities at both the national and the European levels. In the second section, some of the most important benefits provided by the green systems in cities to the environment and to the people are discussed. In the various chapters, the numerous ecosystem services (ES) are discussed, including the potential of these green systems to mitigate the urban heat island effect thus improving the local climate, and to mitigate ambient air pollution thus improving the air quality in cities. In addition, the key role played by urban greenery systems in the ecological connections among natural areas for ensuring the conservation of biodiversity is also emphasized.

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    Authors: Pierro, N.; Giocoli, A.; De Bari, I.; Agostini, A.; +2 Authors

    Il Piano Nazionale Integrato per l’Energia e il Clima del 2019, assegna un ruolo prioritario al gas rinnovabile al fine del raggiungimento dei target di immissione al consumo di biocarburanti previsto dalla direttiva sulla promozione dell'uso dell'energia da fonti rinnovabili -RED II- in Unione Europea. In particolare si prevede nell’arco temporale 2021-2030 di applicazione del piano, nel settore trasporti, un utilizzo di biometano avanzato in forte crescita per arrivare nel 2030 a un consumo pari a 800 ktep annui (circa 1,1 miliardi di m3) rispetto ai 82 ktep di biometano avanzato immesso al consumo nel 2020 (Gestore Servizi Energetici s.p.a). Le stime di questo studio riguardano il potenziale teorico di biometano avanzato producibile in Italia da digestione anaerobica. Il potenziale determinato è teorico in quanto non tiene conto di un possibile uso alternativo dei substrati, quale ad esempio uso diretto (lasciato in campo, combustione o compostaggio), o di filiere di produzione di prodotti biobased(e.g. biopolimeri, biolubrificanti, biodiesel, altri intermediari di processi chimici, etc.) e/o di altri biocarburanti. La stima su base territoriale delle varie biomasse residuali fermentabili realizzata in questo studio, in termini quantitativi e di producibilità di biometano avanzato da upgrading del biogas, ha il grande vantaggio di contenere quel valore di allocazione geografica che permetterà una più corretta valutazione degli elementi di logistica ed integrazione delle reti energetiche con l’obiettivo di fornire agli stakeholders della filiera biogas-biometano avanzato una base dati su cui formulare studi di fattibilità di un sistema integrato di produzione. Il potenziale totale teorico calcolato con dati aggiornati al 2016 è valutato pari a circa 6,2 miliardi di m3 all’anno di biometano avanzato, ovvero un valore che ha lo stesso ordine di grandezza del gas naturale di origine fossile prodotta in Italia nel 2016 (6,0 miliardi di m3) e che è pari a circa l’8,7% dei consumi totali dello stesso anno (70,9 miliardi di m3). The Integrated National Plan for Energy and Climate (PNIEC) of 2019, assigns a priority role to renewable gas in order to achieve the targets for injection to the consumption of biofuels envisaged by the directive on the promotion of the use of energy from renewable sources (REDII) in the European Union, foreseeing in the 2021-2030 period of application of the plan, in the transport sector, the use of advanced biomethane in strong growth to reach a consumption of 800 ktoe per year in 2030 (about 1,1 billion m3) compared to 82 ktoe of advanced biomethane in 2020 (Gestore Servizi Energetici s.p.a). The estimates of this study concern the theoretical potential of advanced biomethane that can be produced in Italy by anaerobic digestion. The determined potential is theoretical as it doesn’t take into account a possible alternative use of the substrates, for example direct use (left in the field, combustion or composting), or of production chains of biomaterials and/or other biofuels (e.g. biopolymers, biolubricants, biodiesel, other intermediaries of chemical processes, etc.). The estimate on a territorial basis of the various residual fermentable biomasses carried out in this study, in terms of quantities and producibility of advanced biomethane from biogas upgrading, has the great advantage of containing that value of geographical allocation that will allow a more correct evaluation of the elements of logistics and integration of energy networks with the aim of providing stakeholders in the advanced biogasbiomethane chain with a database on which to formulate feasibility studies of an integrated production system. The total theoretical potential calculated with data updated to 2016 is estimated to be approximately 6,2 billion m3 per year of advanced biomethane, i.e. a value that has the same order of magnitude as natural gas of fossil origin produced in Italy in 2016 (6,0 billion of m3) and which is equal to approximately 8,7% of total consumption in the same year (70,9 billion m3).

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    ENEA Open Archive
    Other ORP type . 2021
    Data sources: ENEA Open Archive