Abstract
Ionic liquids (ILs) are defined as organic salts with melting points below 100 °C. Such ionic compounds are typically formed using bulky cations and/or bulky anions in order to produce liquids or lower melting solids. ILs have been widely explored in several research areas including catalysis, remediation, solvents, separations, and many others. The utility of such compounds has also been recently broadened to include solid phase ionic materials. Thus, researchers have pushed the boundaries of ILs chemistry toward the solid state and have hypothesized that valuable properties of ILs can be preserved and fine-tuned to achieve comparable properties in the solid state. In addition, as with ILs, tunability of these solid-phase materials can be achieved through simple counterion metathesis reactions. These solid-state forms of ILs have been designated as a group of uniform materials based on organic salts (GUMBOS). In contrast to ILs, these materials have an expanded melting point range of 25 to 250 °C. In this chapter, we focus on recent developments and studies from the literature that provide for fine tuning and enhancing properties through transformation and recycling of diverse ionic compounds such as dyes, antibiotics, and others into solid state ionic materials of greater utility.
Highlights
In recent years, many different kinds of materials and techniques have been developed for improved analytical measurements [1–7]
We believe that when one does an exhaustive examination of the literature and considers the inherent properties identified above for improved analytical measurements, a logical conclusion is that Ionic liquids (ILs), GUMBOS, and nanomaterials derived from GUMBOS represent novel classes of materials that best satisfies all of the above properties
[C16Pyr][seco-Amx] and [C16Pyr][secoPen] were more effective against S. aureus ATCC 43,300 with relative decrease of inhibitory concentration (RDIC) higher than 1000 and 100, respectively. Another compound that was more effective than the commercial antibiotic was [N1112OH][seco-Pen] with RDIC larger than 5. These findings clearly demonstrate that [C16Pyr]+ cation played an important role in antimicrobial activity of synthesized active pharmaceutical ingredients (API)-ILs acting in a synergetic way along with API present in the compound [148]
Summary
Many different kinds of materials and techniques have been developed for improved analytical measurements [1–7]. Studies reveal that in general primary properties such as spectra, colorimetric response, and magnetism are size dependent and somewhat tunable Some of these materials, including carbon dots and silicon dots, exhibit very low cytotoxicities. We believe that when one does an exhaustive examination of the literature and considers the inherent properties identified above for improved analytical measurements, a logical conclusion is that ILs, GUMBOS, and nanomaterials derived from GUMBOS (nanoGUMBOS) represent novel classes of materials that best satisfies all of the above properties. Both ILs and GUMBOS are based on use of organic salts. We desire to discuss some of these applications in detail, as applied to the general area of analytical and environmental chemistry
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