The Copper Chemical Garden as a Low Cost and Efficient Material for Breaking Down Air Pollution by Gaseous Ammonia

Chemical garden (CG) from copper(II) sulfate, nitrate and chloride (CG CuSO4, CG Cu(NO3)2, CG CuCl2) were grown, and characterized from the structural and compositional point of view by using scanning electron microscopy, X‐ray powder diffraction, elemental analysis, thermogravimetric analysis coupl...

Full description

Saved in:
Bibliographic Details
Published inChemSystemsChem Vol. 4; no. 1
Main Authors Castellini, Elena, Bernini, Fabrizio, Sebastianelli, Lorenzo, Bighi, Beatrice, Ignacio Sainz‐Díaz, Claro, Mucci, Adele, Malferrari, Daniele, Ranieri, Antonio, Gorni, Giulio, Marini, Carlo, Franca Brigatti, Maria, Borsari, Marco
Format Journal Article
LanguageEnglish
Published Weinheim Wiley Subscription Services, Inc 01.01.2022
Subjects
Online AccessGet full text

Cover

Loading…
More Information
Summary:Chemical garden (CG) from copper(II) sulfate, nitrate and chloride (CG CuSO4, CG Cu(NO3)2, CG CuCl2) were grown, and characterized from the structural and compositional point of view by using scanning electron microscopy, X‐ray powder diffraction, elemental analysis, thermogravimetric analysis coupled with mass spectrometry, and DR (diffuse reflectance) UV‐Vis‐NIR spectroscopy. The main crystalline phases, controlled by the anion of the starting salt, were brochantite and kobyashevite for CG CuSO4, gerhardtite, rouaite and anthonyite for CG Cu(NO3)2, and atacamite for CG CuCl2. The materials were then exposed to ammonia vapors to test the effectiveness of their entrapping property. All materials proved to be very efficient and rapid in the uptake of ammonia, which invariably results in the formation of a Cu(II)/NH3 complex. However, after a few tens of minutes, CG Cu(NO3)2 and CG CuCl2 release water and get wet, thereby resulting unsuitable for applications. Only CG CuSO4 remains dry for at least 25 hours. This makes it a valid candidate for building devices for trapping ammonia, and possibly other gases capable of interacting with Cu(II). The entrapment of ammonia by this material was also characterized by 1H and 29Si MAS‐NMR XAS spectroscopies. Cleaning air from pollutant and smelling gases is a challenging target of current environmental research. Copper (II)‐based hollow self‐assembled biomimetic structures belong to the family of “chemical gardens” have been prepared and their gas‐adsorption properties tested, in particular the performance in entrapping ammonia from the gas phase. It is shown that the nature of the anion can both influence the surface properties and the entrapping capacity.
ISSN:2570-4206
2570-4206
DOI:10.1002/syst.202100034