Butanol recovery using ionic liquids as green solvents

Motghare, Kalyani A.; Shende, Diwakar Z.; Wasewar, Kailas L.

doi:10.1002/jctb.6970

Cited by 12 publications

(2 citation statements)

References 69 publications

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Section: Introductionmentioning

confidence: 99%

“…[3] These properties coupled with adjustable structure and functionality allow ILs to evolve from unique liquid mediums to the solvents/electrolytes widely used across multiple disciplines in science and engineering. [4][5][6][7][8][9] The incorporation of ILs and advanced energy storage and conversion technology seems to be a nice strategy to meet the increasing demand for clean and sustainable energy. [10] However, traditional ILs based on ammonium, alkylpyridinium, dialkylimidazolium, and phosphonium cations, are generally expensive, nonbiodegradable, and toxicities, which are unfavorable to achieving the aforementioned goals.…”

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The Novel Ionic Liquid and Its Related Self‐Assembly in the Areas of Energy Storage and Conversion

et al. 2022

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ILs unique properties such as ionic conductivity, low volatility, noninflammability, high chemical and electrochemical stability, and so on. [3] These properties coupled with adjustable structure and functionality allow ILs to evolve from unique liquid mediums to the solvents/electrolytes widely used across multiple disciplines in science and engineering. [4][5][6][7][8][9] The incorporation of ILs and advanced energy storage and conversion technology seems to be a nice strategy to meet the increasing demand for clean and sustainable energy. [10] However, traditional ILs based on ammonium, alkylpyridinium, dialkylimidazolium, and phosphonium cations, are generally expensive, nonbiodegradable, and toxicities, which are unfavorable to achieving the aforementioned goals. [11] Thus, numerous efforts have been devoted to exploring the advanced ILsderived materials, which retain most of the characteristics of ILs and are endowed with new features. Novel ILs, including deep eutectic solvents (DESs), [12,13] poly(ionic liquid)s (PILs), [14][15][16] ionic liquid crystals (ILCs), [17,18] and redox-active ionic liquids (RAILs), [19,20] have been synthesized and have been proved to be promising materials to compensate for the inadequacies of the traditional ILs.In general, those four types of novel ILs exhibit unique features and advantages in the fields of energy storage and conversion, respectively. For example, DESs are inexpensive, biodegradable, and nontoxic, they have great advantages in building environmental-friendliness energy storage devices. [21,22] The PILs have a polymeric structure while maintaining ionic conductivity. This means they are excellent potential materials for preparing binder, membranes, and solid-state electrolyte. [23] They are also a kind of building blocks for self-assembly. ILCs with enhanced ordered structure and unique phase behavior are able to achieve the efficient and directional conduction of species, which are excellent properties to construct high-performance energy storage devices. [24] Besides, RAILs are a liquid material with ionic conductivity and redox centers and have exhibited promising potentiality for use as redox additives and electroactive electrolytes. [25] In this review, we focus on the intrinsic properties of novel ILs and their related self-assembly behavior for constructing highperformance energy storage and conversion devices. In the following four chapters, we discuss the unique properties,

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Section: Introductionmentioning

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The Novel Ionic Liquid and Its Related Self‐Assembly in the Areas of Energy Storage and Conversion

et al. 2022

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Recovery of Biobutanol Using Ionic Liquids

Motghare,

Shende,

Pal

et al. 2023

Handbook of Ionic Liquids

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Biobutanol extraction and dehydration with eucalyptus oil yielding linear and cyclic biofuel blends

Tan,

Huang,

et al. 2024

AIChE Journal

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The biobutanol‐based biofuel fermentation is hindered by the challenge of inadequate fermentation broth concentration and the azeotropic systems of water. The application of eucalyptus oil in diesel fuel makes it a promising extractant for biobutanol extraction and dehydration, thus resulting in product recovery and the development of fuel blend technology. Eucalyptus oil‐derived 1,8‐cineole was applied to acetone‐butanol‐ethanol (ABE) and isobutanol systems to enhance the butanol recovery and dehydration. The recovery of n‐butanol and isobutanol reached 92% and 95%, respectively, while the water removal in a 2% butanol system exceeded 99%. These results demonstrated that 1,8‐cineole exhibited a high selectivity toward butanol, thus providing a robust theoretical foundation for the fermentation‐based biofuel recovery and the elimination of azeotropic systems. The introduction of high‐density diesel‐fuel‐like eucalyptus oil into low‐energy‐density biobutanol will increase the energy density of fermentation‐based alcohols, yielding linear and cyclic biofuel blends.

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Butanol recovery using ionic liquids as green solvents

Cited by 12 publications

References 69 publications

The Novel Ionic Liquid and Its Related Self‐Assembly in the Areas of Energy Storage and Conversion

The Novel Ionic Liquid and Its Related Self‐Assembly in the Areas of Energy Storage and Conversion

Recovery of Biobutanol Using Ionic Liquids

Biobutanol extraction and dehydration with eucalyptus oil yielding linear and cyclic biofuel blends

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