Your search keyword '"La Cognata, Sonia"' showing total 7 results

1. Molecular Hosts for the Sensing and Separation of 99TcO4−.

Author

La Cognata, Sonia, Marie, Cécile, Guilbaud, Philippe, Poggi, Antonio, and Amendola, Valeria

Subjects

*POLLUTION, *RADIOACTIVE contamination, *WASTE management, *NUCLEAR fuels, *IONIC strength, *PLUTONIUM, *MOLECULAR recognition, *NUCLEAR energy, *BINDING energy

Abstract

In recent years, European Union member states have hastened energy policy deliberations to address supply and sustainability concerns, placing a significant emphasis on nuclear energy as a means to achieve decarbonization goals. However, despite its significant role in power generation, nuclear energy faces significant challenges linked to fuel reprocessing and waste disposal, that hinder its broader expansion. In this context, the separation of technetium represents a concerning issue. Indeed, technetium's catalytic activity can impede the extraction of uranium, neptunium, and plutonium, affecting waste reprocessing efficiency. Additionally, the stable form of technetium in aerobic conditions, pertechnetate (TcO4−), poses risks of groundwater contamination due to its mobility and solubility. Hence, sensing and separation of TcO4− is imperative for both nuclear fuel processing and minimising radioactive contamination in the environment. However, the binding of TcO4− and its separation from contaminated solutions present challenges due to the acidic (or basic) waste components and the high ionic strength in real matrices. Supramolecular chemists have addressed these issues by designing receptors inspired by molecular recognition principles. This article explores recent advancements and future directions in TcO4− sensing and separation (using extraction and sorption) with a focus on molecular hosts. Metal‐organic receptors will also be discussed. [ABSTRACT FROM AUTHOR]

Published

2024

2. Molecular Hosts for the Sensing and Separation of 99TcO4−.

Author

La Cognata, Sonia, Marie, Cécile, Guilbaud, Philippe, Poggi, Antonio, and Amendola, Valeria

Subjects

POLLUTION, RADIOACTIVE contamination, WASTE management, NUCLEAR fuels, IONIC strength, PLUTONIUM, MOLECULAR recognition, NUCLEAR energy, BINDING energy

Abstract

In recent years, European Union member states have hastened energy policy deliberations to address supply and sustainability concerns, placing a significant emphasis on nuclear energy as a means to achieve decarbonization goals. However, despite its significant role in power generation, nuclear energy faces significant challenges linked to fuel reprocessing and waste disposal, that hinder its broader expansion. In this context, the separation of technetium represents a concerning issue. Indeed, technetium's catalytic activity can impede the extraction of uranium, neptunium, and plutonium, affecting waste reprocessing efficiency. Additionally, the stable form of technetium in aerobic conditions, pertechnetate (TcO4−), poses risks of groundwater contamination due to its mobility and solubility. Hence, sensing and separation of TcO4− is imperative for both nuclear fuel processing and minimising radioactive contamination in the environment. However, the binding of TcO4− and its separation from contaminated solutions present challenges due to the acidic (or basic) waste components and the high ionic strength in real matrices. Supramolecular chemists have addressed these issues by designing receptors inspired by molecular recognition principles. This article explores recent advancements and future directions in TcO4− sensing and separation (using extraction and sorption) with a focus on molecular hosts. Metal‐organic receptors will also be discussed. [ABSTRACT FROM AUTHOR]

Published

2024

3. Gas Permeation through Mechanically Resistant Self‐Standing Membranes of a Neat Amorphous Organic Cage

Author

Mobili, Riccardo, primary, La Cognata, Sonia, additional, Monteleone, Marcello, additional, Longo, Mariagiulia, additional, Fuoco, Alessio, additional, Serapian, Stefano A., additional, Vigani, Barbara, additional, Milanese, Chiara, additional, Armentano, Donatella, additional, Jansen, Johannes C., additional, and Amendola, Valeria, additional

Published

2023

4. Front Cover: CO2 Separation by Imide/Imine Organic Cages (Chem. Eur. J. 49/2022)

Author

La Cognata, Sonia, primary, Mobili, Riccardo, additional, Milanese, Chiara, additional, Boiocchi, Massimo, additional, Gaboardi, Mattia, additional, Armentano, Donatella, additional, Jansen, Johannes C., additional, Monteleone, Marcello, additional, Antonangelo, Ariana R., additional, Carta, Mariolino, additional, and Amendola, Valeria, additional

Published

2022

5. CO 2 Separation by Imide/Imine Organic Cages

Author

La Cognata, Sonia, primary, Mobili, Riccardo, additional, Milanese, Chiara, additional, Boiocchi, Massimo, additional, Gaboardi, Mattia, additional, Armentano, Donatella, additional, Jansen, Johannes Carolus, additional, Monteleone, Marcello, additional, Antonangelo, Ariana R., additional, Carta, Mariolino, additional, and Amendola, Valeria, additional

Published

2022

6. CO2 Separation by Imide/Imine Organic Cages.

Author

La Cognata, Sonia, Mobili, Riccardo, Milanese, Chiara, Boiocchi, Massimo, Gaboardi, Mattia, Armentano, Donatella, Jansen, Johannes C., Monteleone, Marcello, Antonangelo, Ariana R., Carta, Mariolino, and Amendola, Valeria

Subjects

*GAS absorption & adsorption, *POLYMERIC membranes, *MEMBRANE separation, *POROUS materials, *CARBON dioxide

Abstract

Two novel imide/imine‐based organic cages have been prepared and studied as materials for the selective separation of CO2 from N2 and CH4 under vacuum swing adsorption conditions. Gas adsorption on the new compounds showed selectivity for CO2 over N2 and CH4. The cages were also tested as fillers in mixed‐matrix membranes for gas separation. Dense and robust membranes were obtained by loading the cages in either Matrimid® or PEEK‐WC polymers. Improved gas‐transport properties and selectivity for CO2 were achieved compared to the neat polymer membranes. [ABSTRACT FROM AUTHOR]

Published

2022

7. Cover Feature: Gas Permeation through Mechanically Resistant Self‐Standing Membranes of a Neat Amorphous Organic Cage (Chem. Eur. J. 56/2023).

Author

Mobili, Riccardo, La Cognata, Sonia, Monteleone, Marcello, Longo, Mariagiulia, Fuoco, Alessio, Serapian, Stefano A., Vigani, Barbara, Milanese, Chiara, Armentano, Donatella, Jansen, Johannes C., and Amendola, Valeria

Subjects

*MICROPOROSITY, *ORGANIC thin films, *GASES

Abstract

Cover Feature: Gas Permeation through Mechanically Resistant Self-Standing Membranes of a Neat Amorphous Organic Cage (Chem. Eur. J. 56/2023) Keywords: gas transport; membranes; molecular materials; organic cages; thin films EN gas transport membranes molecular materials organic cages thin films 1 1 1 10/12/23 20231009 NES 231009 B Gas separation b : A novel organic cage with excellent film-forming tendencies was processed into transparent, mechanically robust, self-standing membranes of controllable thickness. Gas transport, membranes, molecular materials, organic cages, thin films. [Extracted from the article]

Published

2023