Obtaining Synthon Modularity in Ternary Cocrystals with Hydrogen Bonds and Halogen Bonds

Design of ternary cocrystals based on synthon modularity is described. The strategy is based on the idea of extending synthon modularity in binary cocrystals of 4-hydroxybenzamide:dicarboxylic acids and 4-bromobenzamide:dicarboxylic acids. If a system contains an amide group along with other functio...

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Veröffentlicht in:	Crystal growth & design 2014-10, Vol.14 (10), p.5293-5302
Hauptverfasser:	Tothadi, Srinu, Sanphui, Palash, Desiraju, Gautam R
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Sprache:	eng
Schlagworte:	Condensed matter: structure, mechanical and thermal properties Cross-disciplinary physics: materials science rheology Equations of state, phase equilibria, and phase transitions Exact sciences and technology Materials science Methods of crystal growth physics of crystal growth Organic compounds Physics Solubility, segregation, and mixing phase separation Structure of solids and liquids crystallography Structure of specific crystalline solids
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creator	Tothadi, Srinu Sanphui, Palash Desiraju, Gautam R
description	Design of ternary cocrystals based on synthon modularity is described. The strategy is based on the idea of extending synthon modularity in binary cocrystals of 4-hydroxybenzamide:dicarboxylic acids and 4-bromobenzamide:dicarboxylic acids. If a system contains an amide group along with other functional groups, one of which is a carboxylic acid group, the amide associates preferentially with the carboxylic acid group to form an acid–amide heterosynthon. If the amide and the acid groups are in different molecules, a higher multicomponent molecular crystal is obtained. This is a stable pattern that can be used to increase the number of components from two to three in a multicomponent system. Accordingly, noncovalent interactions are controlled in the design of ternary cocrystals in a more predictable manner. If a single component crystal with the amide–amide dimer is considered, modularity is retained even after formation of a binary cocrystal with acid–amide dimers. Similarly, when third component halogen atom containing molecules are introduced into these binary cocrystals, modularity is still retained. Here, we use acid–amide and Br/I···O2N supramolecular synthons to obtain modularity in nine ternary cocrystals. The acid–amide heterosynthon is robust to all the nine cocrystals. Heterosynthons may assist ternary cocrystal formation when there is a high solubility difference between the coformers. For a successful crystal engineering strategy for ternary cocrystals, one must consider the synthon itself and factors like shape and size of the component molecules, as well as the solubilities of the compounds.
doi_str_mv	10.1021/cg501115k
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The strategy is based on the idea of extending synthon modularity in binary cocrystals of 4-hydroxybenzamide:dicarboxylic acids and 4-bromobenzamide:dicarboxylic acids. If a system contains an amide group along with other functional groups, one of which is a carboxylic acid group, the amide associates preferentially with the carboxylic acid group to form an acid–amide heterosynthon. If the amide and the acid groups are in different molecules, a higher multicomponent molecular crystal is obtained. This is a stable pattern that can be used to increase the number of components from two to three in a multicomponent system. Accordingly, noncovalent interactions are controlled in the design of ternary cocrystals in a more predictable manner. If a single component crystal with the amide–amide dimer is considered, modularity is retained even after formation of a binary cocrystal with acid–amide dimers. Similarly, when third component halogen atom containing molecules are introduced into these binary cocrystals, modularity is still retained. Here, we use acid–amide and Br/I···O2N supramolecular synthons to obtain modularity in nine ternary cocrystals. The acid–amide heterosynthon is robust to all the nine cocrystals. Heterosynthons may assist ternary cocrystal formation when there is a high solubility difference between the coformers. 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Growth Des</addtitle><description>Design of ternary cocrystals based on synthon modularity is described. The strategy is based on the idea of extending synthon modularity in binary cocrystals of 4-hydroxybenzamide:dicarboxylic acids and 4-bromobenzamide:dicarboxylic acids. If a system contains an amide group along with other functional groups, one of which is a carboxylic acid group, the amide associates preferentially with the carboxylic acid group to form an acid–amide heterosynthon. If the amide and the acid groups are in different molecules, a higher multicomponent molecular crystal is obtained. This is a stable pattern that can be used to increase the number of components from two to three in a multicomponent system. Accordingly, noncovalent interactions are controlled in the design of ternary cocrystals in a more predictable manner. If a single component crystal with the amide–amide dimer is considered, modularity is retained even after formation of a binary cocrystal with acid–amide dimers. Similarly, when third component halogen atom containing molecules are introduced into these binary cocrystals, modularity is still retained. Here, we use acid–amide and Br/I···O2N supramolecular synthons to obtain modularity in nine ternary cocrystals. The acid–amide heterosynthon is robust to all the nine cocrystals. Heterosynthons may assist ternary cocrystal formation when there is a high solubility difference between the coformers. 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Growth Des</addtitle><date>2014-10-01</date><risdate>2014</risdate><volume>14</volume><issue>10</issue><spage>5293</spage><epage>5302</epage><pages>5293-5302</pages><issn>1528-7483</issn><eissn>1528-7505</eissn><abstract>Design of ternary cocrystals based on synthon modularity is described. The strategy is based on the idea of extending synthon modularity in binary cocrystals of 4-hydroxybenzamide:dicarboxylic acids and 4-bromobenzamide:dicarboxylic acids. If a system contains an amide group along with other functional groups, one of which is a carboxylic acid group, the amide associates preferentially with the carboxylic acid group to form an acid–amide heterosynthon. If the amide and the acid groups are in different molecules, a higher multicomponent molecular crystal is obtained. This is a stable pattern that can be used to increase the number of components from two to three in a multicomponent system. Accordingly, noncovalent interactions are controlled in the design of ternary cocrystals in a more predictable manner. If a single component crystal with the amide–amide dimer is considered, modularity is retained even after formation of a binary cocrystal with acid–amide dimers. Similarly, when third component halogen atom containing molecules are introduced into these binary cocrystals, modularity is still retained. Here, we use acid–amide and Br/I···O2N supramolecular synthons to obtain modularity in nine ternary cocrystals. The acid–amide heterosynthon is robust to all the nine cocrystals. Heterosynthons may assist ternary cocrystal formation when there is a high solubility difference between the coformers. 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subjects	Condensed matter: structure, mechanical and thermal properties Cross-disciplinary physics: materials science rheology Equations of state, phase equilibria, and phase transitions Exact sciences and technology Materials science Methods of crystal growth physics of crystal growth Organic compounds Physics Solubility, segregation, and mixing phase separation Structure of solids and liquids crystallography Structure of specific crystalline solids
title	Obtaining Synthon Modularity in Ternary Cocrystals with Hydrogen Bonds and Halogen Bonds
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