Maria Forsyth scite author profile

Ionic liquids offer a unique suite of properties that make them important candidates for a number of energy related applications. Cation-anion combinations that exhibit low volatility coupled with high electrochemical and thermal stability, as well as ionic conductivity, create the possibility of designing ideal electrolytes for batteries, super-capacitors, actuators, dye sensitised solar cells and thermoelectrochemical cells. In the field of water splitting to produce hydrogen they have been used to synthesize some of the best performing water oxidation catalysts and some members of the protic ionic liquid family co-catalyse an unusual, very high energy efficiency water oxidation process. As fuel cell electrolytes, the high proton conductivity of some of the protic ionic liquid family offers the potential of fuel cells operating in the optimum temperature region above 100 C. Beyond electrochemical applications, the low vapour pressure of these liquids, along with their ability to offer tuneable functionality, also makes them ideal as CO 2 absorbents for post-combustion CO 2 capture. Similarly, the tuneable phase properties of the many members of this large family of salts are also allowing the creation of phase-change thermal energy storage materials having melting points tuned to the application. This perspective article provides an overview of these developing energy related applications of ionic liquids and offers some thoughts on the emerging challenges and opportunities.

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Pyrrolidinium Imides: A New Family of Molten Salts and Conductive Plastic Crystal Phases

MacFarlane

et al. 1999

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A new family of molten salts is reported, based on the N-alkyl, N-alkyl pyrrolidinium cation and the bis-(trifluoromethane sulfonyl)imide anion. Some of the members of the family are molten at room temperature, while the smaller and more symmetrical members have melting points around 100°C. Of the room-temperature molten salt examples, the methyl butyl derivative exhibits the highest conductivity; at 2 × 10 -3 S/cm this is the highest molten salt conductivity observed to date at room temperature among the ammonium salts. This highly conductive behavior is rationalized in terms of the role of cation planarity. The salts also exhibit multiple crystalline phase behavior below their melting points and exhibit significant conductivity in at least their higher temperature crystal phase. For example, the methyl propyl derivative (mp ) 12°C) shows ion conductivity of 1 × 10 -6 S/cm at 0°C in its higher temperature crystalline phase.

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On the concept of ionicity in ionic liquids

MacFarlane

Forsyth

Izgorodina

et al. 2009

Phys. Chem. Chem. Phys.

669

695

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Ionic liquids are liquids comprised totally of ions. However, not all of the ions present appear to be available to participate in conduction processes, to a degree that is dependent on the nature of the ionic liquid and its structure. There is much interest in quantifying and understanding this 'degree of ionicity' phenomenon. In this paper we present transport data for a range of ionic liquids and evaluate the data firstly in terms of the Walden plot as an approximate and readily accessible approach to estimating ionicity. An adjusted Walden plot that makes explicit allowance for differences in ion sizes is shown to be an improvement to this approach for the series of ionic liquids described. In some cases, where diffusion measurements are possible, it is feasible to directly quantify ionicity via the Nernst-Einstein equation, confirming the validity of the adjusted Walden plot approach. Some of the ionic liquids studied exhibit ionicity values very close to ideal; this is discussed in terms of a model of a highly associated liquid in which the ion correlations have similar impact on both the diffusive and conductive motions. Ionicity, as defined, is thus a useful measure of adherence to the Nernst-Einstein equation, but is not necessarily a measure of ion availability in the chemical sense.

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Use of Ionic Liquids for π-Conjugated Polymer Electrochemical Devices

Li¹,

Fadeev²,

Qi³

et al. 2002

Science

1,144

690

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pi-Conjugated polymers that are electrochemically cycled in ionic liquids have enhanced lifetimes without failure (up to 1 million cycles) and fast cycle switching speeds (100 ms). We report results for electrochemical mechanical actuators, electrochromic windows, and numeric displays made from three types of pi-conjugated polymers: polyaniline, polypyrrole, and polythiophene. Experiments were performed under ambient conditions, yet the polymers showed negligible loss in electroactivity. These performance advantages were obtained by using environmentally stable, room-temperature ionic liquids composed of 1-butyl-3-methyl imidazolium cations together with anions such as tetrafluoroborate or hexafluorophosphate.

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Lithium-doped plastic crystal electrolytes exhibiting fast ion conduction for secondary batteries

MacFarlane¹,

Huang²,

Forsyth

1999

Nature

584

550

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Ionic Liquids in Electrochemical Devices and Processes: Managing Interfacial Electrochemistry

et al. 2007

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Many ionic liquids offer a range of properties that make them attractive to the field of electrochemistry; indeed it was electrochemical research and applications that ushered in the modern era of interest in ionic liquids. In parallel with this, a variety of electrochemical devices including solar cells, high energy density batteries, fuel cells, and supercapacitors have become of intense interest as part of various proposed solutions to improve sustainability of energy supply in our societies. Much of our work over the last ten years has been motivated by such applications. Here we summarize the role of ionic liquids in these devices and the insights that the research provides for the broader field of interest of these fascinating liquids.

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Low viscosity ionic liquids based on organic salts of the dicyanamide anion

MacFarlane¹,

Golding²,

Forsyth³

et al. 2001

Chem. Commun.

505

418

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Protein solubilising and stabilising ionic liquids

2005

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Maria Forsyth

Energy applications of ionic liquids

Pyrrolidinium Imides: A New Family of Molten Salts and Conductive Plastic Crystal Phases

On the concept of ionicity in ionic liquids

Use of Ionic Liquids for π-Conjugated Polymer Electrochemical Devices

Lithium-doped plastic crystal electrolytes exhibiting fast ion conduction for secondary batteries

Ionic Liquids in Electrochemical Devices and Processes: Managing Interfacial Electrochemistry

Low viscosity ionic liquids based on organic salts of the dicyanamide anion

Protein solubilising and stabilising ionic liquids

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