Mechanochemistry: an efficient and versatile toolbox for synthesis, transformation, and functionalization of porous metal-organic frameworks

Mechanochemistry is nowadays recognized as a green approach to chemical synthesis, but the full scope of the accompanying solid-state reactivity is just beginning to be unravelled. This is especially true for the preparation of porous metal-organic frameworks, whose synthesis by the use of mechanica...

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Published inCrystEngComm Vol. 22; no. 27; pp. 4511 - 4525
Main Authors Stolar, Tomislav, U arevi, Krunoslav
Format Journal Article
LanguageEnglish
Published Cambridge Royal Society of Chemistry 01.01.2020
Subjects
Amorphization
Chemical synthesis
Metal-organic frameworks
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Abstract Mechanochemistry is nowadays recognized as a green approach to chemical synthesis, but the full scope of the accompanying solid-state reactivity is just beginning to be unravelled. This is especially true for the preparation of porous metal-organic frameworks, whose synthesis by the use of mechanical force lagged behind that of other relevant classes of materials. Nevertheless, mechanochemical procedures have rapidly evolved from a mere synthetic curiosity towards efficient methods for obtaining high-quality MOFs on different scales. This Highlight is dedicated to the functional approach of using mechanochemistry for the preparation of catalytically active MOF composites and mixed-metal and mixed-ligand MOFs with synergistic properties as well as fine-tuning of the MOF performance via defect engineering and amorphization. Multiple ways in which the synergy of mechanochemistry and MOFs advances the field of materials chemistry are presented here.
AbstractList Mechanochemistry is nowadays recognized as a green approach to chemical synthesis, but the full scope of the accompanying solid-state reactivity is just beginning to be unravelled. This is especially true for the preparation of porous metal–organic frameworks, whose synthesis by the use of mechanical force lagged behind that of other relevant classes of materials. Nevertheless, mechanochemical procedures have rapidly evolved from a mere synthetic curiosity towards efficient methods for obtaining high-quality MOFs on different scales. This Highlight is dedicated to the functional approach of using mechanochemistry for the preparation of catalytically active MOF composites and mixed-metal and mixed-ligand MOFs with synergistic properties as well as fine-tuning of the MOF performance via defect engineering and amorphization.
Mechanochemistry is nowadays recognized as a green approach to chemical synthesis, but the full scope of the accompanying solid-state reactivity is just beginning to be unravelled. This is especially true for the preparation of porous metal-organic frameworks, whose synthesis by the use of mechanical force lagged behind that of other relevant classes of materials. Nevertheless, mechanochemical procedures have rapidly evolved from a mere synthetic curiosity towards efficient methods for obtaining high-quality MOFs on different scales. This Highlight is dedicated to the functional approach of using mechanochemistry for the preparation of catalytically active MOF composites and mixed-metal and mixed-ligand MOFs with synergistic properties as well as fine-tuning of the MOF performance via defect engineering and amorphization. Multiple ways in which the synergy of mechanochemistry and MOFs advances the field of materials chemistry are presented here.
Mechanochemistry is nowadays recognized as a green approach to chemical synthesis, but the full scope of the accompanying solid-state reactivity is just beginning to be unravelled. This is especially true for the preparation of porous metal–organic frameworks, whose synthesis by the use of mechanical force lagged behind that of other relevant classes of materials. Nevertheless, mechanochemical procedures have rapidly evolved from a mere synthetic curiosity towards efficient methods for obtaining high-quality MOFs on different scales. This Highlight is dedicated to the functional approach of using mechanochemistry for the preparation of catalytically active MOF composites and mixed-metal and mixed-ligand MOFs with synergistic properties as well as fine-tuning of the MOF performance via defect engineering and amorphization.
Author U arevi, Krunoslav
Stolar, Tomislav
AuthorAffiliation Ru er Boškovi Institute
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  givenname: Krunoslav
  surname: U arevi
  fullname: U arevi, Krunoslav
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Notes Krunoslav U arevi graduated in 2009 at the University of Zagreb in the field of structural and inorganic chemistry. After a Marie-Curie Newfelpro Fellowship with Prof. Tomislav Friš i at McGill University in Montreal, he started working as a Head of Laboratory for Green Synthesis at Ru er Boškovi Institute in Zagreb in 2016. His main scientific focus is on developing mechanochemical and solvent-free procedures for the synthesis and transformation of various classes of functional materials, from supramolecular receptors and organic compounds to porous metal-organic frameworks (MOFs). A particular part of his research involves designing new milling reactors and developing new methodologies for
monitoring of milling and aging reactions.
Tomislav Stolar is a PhD candidate at Ru er Boškovi Institute in Zagreb, Croatia under the supervision of Dr. Krunoslav U arevi . He started his scientific career as an undergraduate volunteer at the same institution in 2013. His research interest spans solid-state chemistry, crystal engineering, prebiotic chemistry, mechanochemistry and MOFs.
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Snippet Mechanochemistry is nowadays recognized as a green approach to chemical synthesis, but the full scope of the accompanying solid-state reactivity is just...
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SubjectTerms Amorphization
Chemical synthesis
Metal-organic frameworks
Title Mechanochemistry: an efficient and versatile toolbox for synthesis, transformation, and functionalization of porous metal-organic frameworks
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