Use of deep eutectic solvents in environmentally-friendly 
dye-sensitized solar cells and their physicochemical 

properties: A brief review

Journal: RSC Advances

Manuscript ID RA-REV-03-2024-001610.R2

Article Type: Review Article

Date Submitted by the 
Author: n/a

Complete List of Authors: Pishro, Khatereh A.; UNESP IBILCE, Chemistry and Environmental 
Science
Gonzalez, Mario; UNESP, Chemistry and Environmental Science

Subject area & keyword: Electrochemistry for energy < Energy chemistry

 

RSC Advances



Use of deep eutectic solvents in environmentally-friendly dye-sensitized solar 
cells and their physicochemical properties: A brief review

Khatereh A. Pishroa, Mario Henrique Gonzaleza*

a São Paulo State University (UNESP), National Institute for Alternative Technologies of 

Detection, Toxicological Evaluation and Removal of Micropollutants and Radioactives (INCT-

DATREM), Department of Chemistry and Environmental Science, São José do Rio Preto, SP, 

15054-000, Brazil

*Corresponding author. Tel./Fax: +55 17 32212512 

E-mail address: mario.gonzalez@unesp.br (M. H. Gonzalez)

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Abstract

A novel way to mitigate the greenhouse effect is to use dye-sensitized solar cells (DSSCs) to 

convert carbon dioxide from the air into useful products, such as hydrocarbons, which can also 

store energy from the sun, a plentiful, clean, and safe resource. The conversion of CO2 can help 

reduce the impacts of greenhouse gas emissions that contribute to global warming. However, there 

is a major obstacle in using DSSCs, since many solar devices operate with organic electrolytes, 

producing pollutants including toxic substances. Therefore, a key research area is to find new eco-

friendly electrolytes that can effectively dissolve carbon dioxide. One option is to use deep eutectic 

solvents (DESs), which are potential substitutes for ionic liquids (ILs) and have similar advantages, 

such as being customizable, economical, and environmentally friendly. DESs are composed of 

low-cost materials and have very low toxicity and high biodegradability, making them suitable for 

use as electrolytes in DSSCs, within the framework of green chemistry. The purpose of this brief 

review is to explore the existing knowledge about how CO2 dissolves in DESs and how these 

solvents can be used as electrolytes in solar devices, especially in DSSCs. The physical and 

chemical properties of the DESs are described, and areas are suggested where further research 

should be focused.

Keywords: Green solvents, solubility of CO2, renewable technologies, electrolyte, dye-

sensitized solar cells.

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List of Abbreviations:

ILs-Ionic liquids

DES-Deep Eutectic Solvents 

HBD-Hydrogen Bond Donor 

HBA-Hydrogen Bond Acceptor

DSSCs-dye-sensitized solar cells

EC-Electrochemical Cell 

PCEs-Power Conversion Efficiencies 

VOCs-Volatile Organic Compounds 

ChCl-Choline Chloride 

EG-Ethylene Glycol 

EmimI-1-ethyl-3-methylimidazolium 

Reline-choline chloride and urea 

Isc-short circuit current 

Voc- open circuit Voltage values 

PSCs-Perovskite Solar Cells 

I−/I3
−-iodide/triiodide 

TiO2-Titanium dioxide

NADES-Natural Deep Eutectic Solvents 

ECs-Electrochemical Capacitors 

F.E.-Faradaic Efficiencies 

MEAHCl-monoethanolamine hydrochloride

MDEA-methyldiethanolamine

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DMF-dimethyl formamide 

IM-incorporating imidazole 

FTO-Fluorine-doped tin oxide

FF-Fill Factor 

LUMO-lowest unoccupied molecular orbital 

HOMO-highest occupied molecular orbital 

Eg-band gap 

[PMIM]I- 1-propyl-3-methylimidazolium iodide 

IPCE-Incident Photon-to-Current Conversion Efficiency 

ACN-acetonitrile 

EMIM-1-Ethyl-3-Methylimidazolium iodide 

MEA.Cl- Ethylamine hydrochloride 

DBN- 1,5-Diazabicyclo[4.3.0]-non-5-ene

DBU- 1,8-diazabicyclo- [5.4.0]undec-7-ene

    TBAB -Tetrabutylammonium Bromide

    MTPPBr- Methyltriphenylphosphonium Bromide

    BMIMCl -1-Butyl-3-methylimidazolium Chloride

    MEA-Monoethanolamine

   MDEA-Methyldiethanolamine

   [bmim][tf2N]- 1-Butyl-3-methylimidazolium bis(trifluoromethylsulfonyl)imide

   KI-Potassium iodide 

   LiI-Lithium iodide 

   NaI-Sodium iodide 

   Fr-Fructose 

   Glu-Glucose 

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   MA-Malonic acid 

   Gly-Glycerol 

   VOC-Volatile Organic Compound 

1. Introduction

One of the most important challenges in recent years concerns the design of alternative 

renewable energy technologies that can replace fossil fuels and reduce their environmental damage 
1, 2. According to the Paris Agreement, urgent actions are needed to lower the emissions of CO2 

into the atmosphere, as they cause serious effects in the environment 3. One promising solution is 

to use solar cells to convert CO2 into valuable products such as hydrocarbons, which can also store 

solar energy, a plentiful, clean, and safe resource 4. The conversion of CO2 can help reduce 

greenhouse gas levels, while at the same time absorbing sunlight, contributing to mitigating global 

warming 5.

Artificial photosynthetic systems are devices that use sunlight as an energy source and 

water as an electron source to convert CO2 into useful chemicals (fuels or carbohydrates). This can 

be achieved by combining a photovoltaic (PV) cell that generates electrons and holes with an 

electrochemical cell (EC) that oxidizes water at the anode and reduces CO2 at the cathode 6-8. An 

electrolyte is a vital component in these devices, as it enables charge transport between the 

electrodes. Most of the electrolytes used are non-aqueous, including polar organic solvents 

(acetonitrile, valeronitrile, and others) and green solvents (ILs and DESs) 9, 10. Ionic liquids (ILs) 

and deep eutectic solvents (DESs) have been proposed for various industrial processes and 

applications, such as chemical synthesis 11, absorption 12, biomass pretreatment 13, extraction 14, 

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electrolytes for electrochemistry (fuel cells and lithium batteries)15, and dye-sensitized solar cells 

(DSSCs) 16-18. Scheme 1 provides an overview of DES applications, based on their hydrophilic 

and hydrophobic characteristics19.

Scheme 1.  DES applications according to their individual hydrophilic and hydrophobic 

characteristics19. 

Among the various technologies for converting solar energy, DSSCs offer the greatest 

potential for improving their properties, in terms of both environmental sustainability and energy 

conversion performance. DSSCs are a type of thin-film solar cell that has been widely studied for 

more than two decades, due to their simple preparation methodology, low toxicity, and low cost 

of preparation, and ease of production 20-24. 

DSSCs are based on a photoactive anode with an n-type semiconductor layer (usually TiO2) 

sensitized by an organometallic dye, a counter electrode, and a liquid electrolyte that completes 

the circuit and regenerates the dye. Liquid electrolytes 25 have achieved a record efficiency of 

14.7% and liquid DSSCs are low-cost solar cells with high power conversion efficiencies (PCEs). 

However, acetonitrile-based electrolytes and some other organic components used for DSSCs are 

harmful, while their volatility limits their performance and stability. To overcome this problem, 

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https://link.springer.com/article/10.1186/s11671-018-2760-6
https://link.springer.com/article/10.1186/s11671-018-2760-6


the use of DESs has been suggested as an attractive way to improve liquid electrolytes, with the 

advantages of low toxicity, biodegradability, high thermal stability, non-flammability, no vapor 

pressure, and low production costs 18, 26-28 . 

The primary objective of this review is to examine a range of deep eutectic solvents (DESs) 

for their potential as innovative electrolytes in solar cells29, focusing on the synthesis and 

properties of DESs, with particular attention given to their physicochemical attributes that facilitate 

the conversion of CO2 into value-added chemicals. The mechanism of these solar cells emulates 

the natural photosynthesis process and is termed “artificial photosynthesis” 30, 31. The review also 

outlines prospective avenues for future research within this area.

2. Deep eutectic solvents (DESs)

2.1. DESs as green solvents

Green and sustainable solvents have influenced the recent development of the chemical 

industry. Volatile organic compounds (VOCs) are still widely used as solvents in industries, even 

though they are often toxic and highly flammable 32, 33. Ionic liquids (ILs) are considered green 

solvents, due to their very low vapor pressure and high thermal stability, making them suitable for 

many processes. However, ILs have some drawbacks, such as high viscosity, high cost, and 

difficult synthesis 34. Deep eutectic solvents (DESs) 35, 36 are new types of green solvents, usually 

composed of Lewis or Brønsted acids and bases, with a strong hydrogen bond network, where the 

interactions act to reduce the lattice energy. A simple preparation pathway for DESs using HBD 

and HBA is shown in Scheme 2 37 .A DES is a binary or ternary mixture of safe and cheap 

components that include at least one hydrogen bond donor (HBD) and one hydrogen bond acceptor 

(HBA), mixed in a specific molar ratio to form a eutectic mixture with a melting point much lower 

than that of any of the individual components 38. The term “deep” should only be used for those 

mixtures with a eutectic point temperature much lower than that of an ideal liquid mixture, which 

explains the decreased melting point, compared to those of the individual components 39, 40.

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Scheme 2. A DES preparation pathway composed of HBD and HBA, with strong hydrogen bonds 

to reduce the lattice energy 37.

Binary DESs are mixtures of one kind of HBA and one kind of HBD, while ternary DESs 

are mixtures of three components, which have also been reported in the literature 41. Some HBDs 

and HBAs used for the preparation of DESs introduced in this review are shown in Scheme 3. 

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Scheme 3. Some Hydrogen bond acceptors (HBAs) and hydrogen bond donors (HBDs) used in 

preparation of the DESs described in this review.

The electrolytes commonly used in DSSCs are non-aqueous polar solvents containing 

organic compounds (such as acetonitrile). However, these solvents are volatile and toxic, which 

poses environmental and safety risks. Therefore, there is a need to develop new “green solvents” 

that have similar physicochemical properties, but are eco-friendly and more sustainable. Among 

the candidates for green solvents are DESs, which are HBA and HBD combinations that form 

eutectic mixtures with low melting points. The physicochemical properties of DESs depend on the 

type and ratio of HBA and HBD, resulting in different interactions (such as hydrogen bonding, π-π 

bonding, or anion exchange) 51. These interactions affect the density, viscosity, melting/freezing 

point, and conductivity of DESs, which are important factors influencing their performance as 

electrolytes in DSSCs. In addition, other properties such as thermal stability, toxicity, and 

biodegradability affect the application potential of DESs. 

The various uses of DESs in scientific and industrial fields are determined by their 

performance, which is directly influenced by their physicochemical properties.  The relationships 

between physicochemical properties, solvent performance, and applications of deep eutectic 

solvents are depicted in Scheme 4, where temperature and moisture expand the liquid range of 

DESs 42. 

Scheme 4. The relationships between physicochemical properties, solvent performance, 

and applications of deep eutectic solvents 42. 

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https://link.springer.com/article/10.1007/s11356-021-14485-2
https://link.springer.com/article/10.1007/s11356-021-14485-2
https://link.springer.com/article/10.1007/s11356-021-14485-2
https://link.springer.com/article/10.1007/s11356-021-14485-2


In the following subsections, the basic physicochemical properties of DESs for use as 

effective electrolytes in DSSCs will be discussed and compared.

2.2. Properties and characteristics of DESs 

2.2.1. Melting point/freezing point

The melting point (mp) or freezing point (ΔTf) of deep eutectic solvents is the property 

that defines the temperature at which the solid and liquid phases of the mixture are in equilibrium, 

which is much lower than those of their individual components, so they can form liquid mixtures 

at room temperature or below. The mp or ΔTf of a DES is related to the strength of the interactions 

between the HBA and HBD structures and the medium that they are mixed with, such as water 
43-47, and depends on the type and ratio of the HBA and HBD components, as well as the 

interactions between them. The stronger the interactions, such as hydrogen bonds or Van der Waals 

forces, the lower the melting/freezing point of the DES. It is also possible to use a phase diagram 

to show the relationship between the composition and the melting/freezing point of a binary 

mixture of HBA and HBD. The lowest melting/freezing point is achieved at the eutectic point, 

where the HBA and HBD are mixed in a specific molar ratio that maximizes the interactions 

between them 48. Scheme 5 shows the theoretical phase diagram for binary HBD and HBA 

mixtures, which illustrates how the mp or ΔTf of the DESs varies depending on the composition 

and ratio of the HBD and HBA. 

Scheme 5. Eutectic point in a two-component (HBA and HBD) phase diagram 39. 

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The DES melting point influences the performance and stability of solar cells, as it affects 

the operating temperature range and the thermal degradation of the material 49. The melting point 

of the DES, as well as the polarity, viscosity, and density of the solvent, all have an impact on the 

solubility of CO2 in DESs. The CO2 solubility in a DES is inversely proportional to the melting 

point of the DES. To obtain the correct melting point and solubility of CO2 in DESs for solar cell 

applications, it is important to select a suitable mix and proportion of HBD and HBA. The DES 

melting point also affects the physical and chemical properties of the perovskite materials used in 

common types of solar cells. Perovskite materials have a crystal structure analogous to that of the 

mineral perovskite, composed of calcium, titanium, and oxygen (CaTiO3). Increase of the heat 

treatment temperature can cause the absorption edge to present a red shift, the band gap to decrease, 

and the defect density of the perovskite material to increase. These changes can reduce the 

efficiency and stability of the solar cell. However, an appropriate heat treatment time and 

temperature can also passivate the defects and improve the solar cell performance 49. It is important 

to adjust the melting point and the heat treatment conditions of the DES to optimize the properties 

of the perovskite material for solar cell applications.

2.2.2. Viscosity

Viscosity is a measure of the resistance of a fluid to flow. It is a property that determines 

the extent to which a fluid resists changing its shape or flowing. A fluid with high viscosity flows 

more slowly than a fluid with low viscosity, depending on its temperature, pressure, 

and composition.

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https://www.britannica.com/science/viscosity
https://www.britannica.com/science/viscosity
https://www.britannica.com/science/viscosity


The viscosity of DESs depends on the type and ratio of the HBD and HBA components, as 

well as the interactions between them. The stronger the interactions, such as hydrogen bonds or 

Van der Waals forces, the higher the viscosity of the DES. The viscosity of DESs affects their 

performance and applications in various fields, such as solar cells 50, electrochemistry 51, catalysis 
52, and biotechnology 53. For example, the viscosity of DESs affects the solubility of CO2 in them, 

which is an important factor for the conversion of solar energy and CO2 to useful products such as 

hydrocarbons. The solubility of CO2 in DESs decreases as the viscosity increases. Therefore, 

selecting the best mix and proportion of the HBD and HBA parts is important for achieving suitable 

CO2 solubility and viscosity in DESs for solar cell uses.

The temperature and the ionic species in the DES electrolyte mixtures affect their viscosity, 

which is an indicator of the fluidity of the electrolyte. Dokohani et al. 54 used a DES based on 

choline chloride and ethylene glycol (ChCl-EG), adding different iodide salts to obtain electrolytes 

for dye-sensitized solar cells (DSSCs). Measurements were made of the viscosity of these 

electrolytes with added KI, 1-ethyl-3-methylimidazolium (EmimI), or KI−EmimI, at 293−365 K, 

which showed that the viscosity decreased at higher temperatures, improving DSSC performance 

under solar irradiation. In addition, the viscosity varied with the composition of the iodide salt, 

where the electrolytes with smaller cations had higher viscosity. The molecular weight of the ionic 

species also influenced the viscosity of the electrolytes. The simulated viscosity of the KI-

containing electrolyte was 27.71 mPa.s., which was close to the experimental value of 26.76 mPa.s. 

at 298 K. It was also found that the KI used in DES preparation enhanced the DSSC performance, 

but also increased the viscosity of the solution.

2.2.3. Density

The density (ρ) of a substance is a measure of the amount of mass (m) per unit volume 

(V). The density of a DES is an important physical property that affects its solvation ability, 

viscosity, thermal conductivity, and mass transfer. The density of a DES depends on several 

factors, such as the type and ratio of the components, the temperature, the water content, and the 

presence of other additives. The density of a DES influences its thermal conductivity, which is a 

measure of how well a material can transfer heat. A higher density means a higher thermal 

conductivity, as the molecules are closer together and can transfer heat more easily. However, 

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density is not the only factor affecting the thermal conductivity of a DES. The hydrogen bonding 

between the components and the interactions with other molecules, such as CO2, also play a 

role.  In some DESs, the addition of a salt or hydrogen bond donor enhances the thermal 

conductivity, which may be attributed to the fact that the effect of density is stronger than that of 

hydrogen bonds 55. For example, at lower pressure, the ethylene glycol and CO2 interaction 

dominates, while at a higher pressure, the chloride and CO2 interaction is most important. 

Therefore, DESs offer the same advantages as the CO2 absorbent in ionic liquids, while also 

exploiting a hydrogen bond donor 56. The density of a DES affects its viscosity, which is a measure 

of how resistant a fluid is to flow. Higher density is associated with higher viscosity, as the 

molecules are more tightly packed and have more friction. However, the viscosity of a DES also 

depends on the temperature, the water content, and the hydrogen bonding between the components. 

For example, increasing the temperature or adding water can reduce the viscosity of a DES, as the 

thermal energy or the water molecules can disrupt the hydrogen bonds and increase the 

fluidity. The viscosity of a DES is an important factor for its application, because it determines the 

mixing and diffusion rates, the mass transfer coefficients, and the energy consumption 57.

The density of a DES determines its solubility properties, which are crucial for its use as a 

solvent for various organic reactions. Higher density results in higher solubility of polar and ionic 

compounds, because the molecules can form stronger interactions with the solute. However, 

density is not the only factor that affects the solubilization capacity of a DES. The solvation 

behavior is also influenced by the polarity, hydrogen bonding, molecular size, and shape of the 

components, as well as the nature of the solute. For instance, in organic oxidation reactions, DESs 

can break down both lipophilic and hydrophilic organic species, making the oxidation of organic 

compounds by hydrogen peroxide more effective 58. 

DESs have been used as electrolytes for DSSCs, a type of low-cost and environmentally 

friendly photovoltaic device that uses a dye to absorb light and generate electricity. The density of 

a DES is one of the physical properties that affect its performance in this application. Different 

studies have investigated the effect of density on the performance of DSSCs with DES-based 

electrolytes. For example, one study used a DES composed of choline chloride and urea (Reline) 
59 as an electrolyte for carbon-based electrochemical capacitors. The study found that the specific 

capacitance increased from 100 to 157 F g−1 at a 1 A g−1 current load, by adding 1 wt.% water to 

the DES system, due to the decrease in viscosity and the increase in ionic conductivity 59.

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https://www.mdpi.com/1420-3049/26/19/5779
https://www.mdpi.com/1420-3049/26/19/5779
https://www.mdpi.com/1420-3049/26/19/5779
https://link.springer.com/article/10.1007/s10311-021-01225-8
https://link.springer.com/article/10.1007/s10311-021-01225-8
https://pubs.rsc.org/en/content/articlelanding/2022/ee/d1ee02920g
https://pubs.rsc.org/en/content/articlelanding/2022/ee/d1ee02920g
https://pubs.rsc.org/en/content/articlelanding/2022/ee/d1ee02920g


Another study used two DESs composed of choline chloride and ethylene glycol or urea 

as electrolytes for DSSCs. The devise using choline chloride and ethylene glycol showed an 

increase in the short circuit current (Isc) in opposite, the devices using choline chloride and urea 

electrolyte exhibited improved open circuit voltage values (Voc). 60, due to the different molecular 

structures and the ways that the DES parts interacted with the dye and the redox mediator.

2.2.4. Conductivity

DESs carry electric charges due to their conductivity, which is an important property for 

their application as electrolytes in solar cells, since it influences the performance and speed of the 

electrochemical reaction that occurs in the solar cell. Factors including the type and ratio of the 

components, temperature, water content, and the presence of other additives affect the conductivity 

of a DES. The viscosity, polarity, hydrogen bonding, and ionic strength of the liquid can also affect 

the conductivity of a DES. For example, the conductivity of some DESs can be increased by adding 

water or salts, resulting in lower viscosity and increase of the number of charge carriers 61.

Various studies have explored how conductivity affects solar cells with electrolytes based 

on DESs. For instance, one study used a choline chloride and ethylene glycol DES as an electrolyte 

for DSSCs and found that the DSSCs with the DES electrolyte exhibited higher power conversion 

efficiency, compared to DSSCs with a traditional liquid electrolyte, because the DES had higher 

conductivity and a lower recombination rate 62. Investigation was made of perovskite solar cells 

(PSCs), a new and efficient type of photovoltaic device that uses a perovskite material to absorb 

light and transport charge, using a DES composed of choline chloride and urea as the electrolyte. 

It was found that PSCs with the DES electrolyte had better open-circuit voltage and fill factor, 

compared to PSCs with a usual solid-state electrolyte, because the DES provided higher 

conductivity and a smoother interface 62.

The conductivity of DESs is affected by temperature, the alkyl chain length of the cation, 

the HBD to HBA molar ratio, and viscosity. For instance, adding a 33% mole fraction of choline 

chloride to a DES based on choline chloride and glycerol increased its conductivity from 1.047 to 

more than 1 mS/cm 63, with the DES conductivity being slightly affected by the cation alkyl chain 

length. In addition, the conductivity of DESs increases with temperature, because the hydrogen 

bond network breaks and the ionic mobility increases 64.

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https://pubs.rsc.org/en/content/articlepdf/2021/ra/d1ra03273a


Viscosity affects the conductivity of DESs, with higher viscosity leading to lower 

conductivity, and for some electrochemistry applications, the conductivity of DESs should not be 

too low (lower than 1 mS cm−1 at ambient temperature) 65. Hence, DESs are a good choice for 

electrochemical applications, including as electrolytes for solar cells, because they have low 

viscosity and high conductivity 63, 66. 

2.2.5. Acidity

Acidity is an important parameter affecting the characteristics of new solvents. The 

Brønsted acidity of DESs can be determined by measuring the pH or the Hammett acidity function, 

while the Lewis acidity can be evaluated by FT-IR analysis 67, 69. The acidity of a DES is a property 

that affects its ability to act as an electrolyte in solar cells, since it can influence the electrochemical 

reactions that occur in the cell, as well as the stability and performance of the device. If the acidity 

level changes, it can change the redox potential of the mediator, which in DSSCs is usually 

iodide/triiodide (I−/I3
−). The redox potential of the mediator determines the open-circuit voltage of 

the DSSC, which is a measure of the maximum voltage that the device can produce. A higher 

redox potential result in a higher open-circuit voltage and higher power conversion efficiency. 

The acidity of the DES can affect the redox potential of the mediator by changing the 

equilibrium between I− and I3
−. Higher acidity, with lower pH, favors the formation of I3

− and 

increases the redox potential 59. Another way that acidity affects the DES electrolyte is by 

influencing the stability and corrosion of the electrode materials and the dye sensitizer. The 

electrode materials are usually titanium dioxide (TiO2) for the photoanode and platinum (Pt) for 

the counter electrode. The dye sensitizer is usually a ruthenium complex that absorbs light and 

injects electrons into the TiO2. The acidity of the DES can affect the stability and corrosion of 

these materials by changing the chemical reactions that occur on their surfaces. At higher acidity, 

there is a higher concentration of protons (H+) available to react with the electrode materials and 

the dye sensitizer, leading to degradation or dissolution. For example, higher acidity can cause the 

oxidation of Pt to PtO or PtO2, which reduces the catalytic activity of the counter 

electrode 69.Higher acidity can also break down the ruthenium dye, which makes the photoanode 

less effective in absorbing light and injecting electrons 69. Furthermore, higher acidity can cause 

hydrolysis of the ruthenium dye, which reduces light absorption and the electron injection 

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https://chem.libretexts.org/Bookshelves/Inorganic_Chemistry/Inorganic_Chemistry_%28LibreTexts%29/06%3A_Acid-Base_and_Donor-Acceptor_Chemistry/6.03%3A_Brnsted-Lowry_Concept/6.3.04%3A_Brnsted-Lowry_Superacids_and_the_Hammett_Acidity_Function
https://www.wikiwand.com/en/Hammett_acidity_function
https://pubs.rsc.org/en/content/articlelanding/2022/ee/d1ee02920g
https://pubs.rsc.org/en/content/articlelanding/2022/ee/d1ee02920g
https://link.springer.com/article/10.1007/s12200-011-0208-z
https://link.springer.com/article/10.1007/s12200-011-0208-z
https://link.springer.com/article/10.1007/s12200-011-0208-z
https://pubs.rsc.org/en/content/articlelanding/2017/cs/c6cs00752j
https://pubs.rsc.org/en/content/articlelanding/2017/cs/c6cs00752j


efficiency of the photoanode 70. Therefore, the acidity of the DES electrolyte is an important factor 

affecting the performance and durability of the solar cell. The optimal acidity of the DES 

electrolyte depends on the type and composition of the DES, the type and concentration of the 

mediator, and the type and structure of the electrode materials and the dye sensitizer. The acidity 

of the DES electrolyte can be adjusted by changing the ratio of the hydrogen bond donor (HBD) 

and the hydrogen bond acceptor (HBA) in the DES, or by adding water or other additives to the 

DES 71, 72.

2.2.6. Hydrophobicity and hydrophilicity 

The hydrophobicity and hydrophilicity of DESs are important factors that affect their 

performance as electrolytes in solar cells. Hydrophilic DESs are water-miscible and can be used 

to improve the thermophysical properties of the electrolyte solution. The hydrophobicity and 

hydrophilicity of DESs depend on the components and the molar ratio of the hydrogen bond donor 

and acceptor. For example, tetrabutylammonium chloride and decanoic acid form a hydrophobic 

DES, while choline chloride and urea form a hydrophilic DES. Molecular dynamics simulations 

can be used to study the interfacial properties of hydrophobic DESs with water, including 

interfacial tension, solubility, and hydrogen bonding 72. The hydrophobicity and hydrophilicity of 

DESs can also affect the processing of functional composite resins, such as epoxy, phenolic, 

acrylic, polyester, and imprinted resins, by modifying their properties, enhancing their 

recyclability, and endowing them with functionality 73. Various methods such as contact angle and 

surface tension measurements, partition coefficient determination, and fluorescence spectroscopy 

can be used to evaluate the hydrophobicity and hydrophilicity of DESs 74. These methods can help 

in the design and optimization of DESs for specific applications in solar cells and other fields. A 

variety of DSSC devices can be obtained using either hydrophilic or hydrophobic DESs 16, 47. An 

aqueous choline chloride-based DES solution was utilized as an efficient electrolyte in DSCCs 60, 

leading to enhancements of the cell parameters and increasing the overall power conversion 

efficiency (PCE) to nearly 2%. Such performance is on a par with the PCEs of mid-to-high-tier 

water-based DSSCs.

2.2.7. Volatility

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https://www.mdpi.com/2073-4352/10/10/864
https://www.mdpi.com/2073-4352/10/10/864
https://www.mdpi.com/2073-4352/10/10/864


Volatility is a property that measures the tendency of a substance to evaporate. The 

volatility of the electrolytes used in solar cells can affect performance and durability, since it can 

cause leakage, corrosion, degradation, and efficiency loss. When used as electrolytes, DESs have 

the advantages of low volatility, high conductivity, good solubility of CO2, and low toxicity. Such 

DESs can be obtained using hydrogen bond donor and acceptor mixtures such as choline chloride 

and urea, or choline chloride and ethylene glycol, for application as electrolytes in low-cost and 

high-efficiency DSSC photovoltaic devices. DESs can improve the electrochemical properties of 

DSSCs, such as the open circuit voltage, the short circuit current, and the impedance, in addition 

to being environmentally friendly, biodegradable, and easy to prepare 59, 60, 75, 76. 

2.2.8. Surface tension

Surface tension is a property that measures the force that acts on the surface of a liquid, 

making it behave like an elastic membrane. The surface tension of the electrolytes used in solar 

cells can affect the formation and stability of the interface between the electrolyte and the 

electrodes, as well as charge transfer and electron recombination. In addition to high conductivity, 

good solubility of CO2, and low toxicity, DESs have low surface tension, contributing to 

improvement of the electrochemical properties of DSSCs, such as the open circuit voltage, the 

short circuit current, and the impedance 59, 77, 78.

3.  Preparation of DESs     

3.1. Selection of HBDs and HBAs             

The main methods described in the literature for synthesis of DES are based on stirring and 

heating, freeze drying, evaporation, and microwave-assisted synthesis 79. The most popular method 

involves mixing and heating two or three components, until a homogeneous liquid is formed 80 

Among the different components used in the mixture, attention is increasingly being focused on 

those suitable for the synthesis of hydrophobic DESs that are stable in the aquatic environment 43, 

46. The DES type Cat+X− + zRZ, such as ChCl+urea, is especially popular due to its hydrophobicity 

Page 18 of 89RSC Advances



and stability in aqueous mixtures43. The ultrasound-assisted and microwave-assisted DES 

synthesis techniques are faster and more efficient than the use of stirring and heating at 50 °C. 

However, the stirring and heating synthesis method has the advantages of simplicity and the ability 

to produce larger volumes of solvents 81. The formation of a eutectic solvent occurs due to 

hydrogen bonding of the precursors, together with intermolecular interactions involving Van der 

Waals and electrostatic forces between HBDs and HBAs. The NMR and FTIR spectra of the 

synthesized DES show bands typical of the functional groups of the precursors that were used.

The selection of HBDs and HBAs is based on the desired properties of the DESs, including 

aspects such as solubility, conductivity, viscosity, surface tension, volatility, toxicity, and 

biodegradability. Certain HBDs and HBAs are mixed together in a fixed molar ratio to make 

Natural Deep Eutectic Solvents (NADES), which are a type of eutectic mixture. These solvents 

are considered “natural” because their constituents are naturally found in plants. The main 

components of NADES include sugars, organic acids, bases, and amino acids79,86 .The introduction 

of ultrasound and microwave-assisted synthesis methods 81resulted in a faster and more efficient 

process, while the stirring and heating methods enabled the production of larger volumes of 

solvents. Infrared spectroscopy (ATR-FTIR) and thermogravimetric analysis (TGA) were used to 

characterize the prepared NADES and identify intermolecular interactions 81. Hydrogen bonds 

were observed between the precursor molecules, regardless of the synthesis method, and they 

revealed interactions between the precursor components and decomposition temperatures 

exceeding 150 °C 81.

The scheme 6 demonstrates that various synthesis methods can yield NADES with 

consistent properties, despite differences in efficiency and equipment requirements. Researchers 

can choose the most suitable method based on their specific needs and constraints, and all synthesis 

methods yield NADES with similar physicochemical characteristics81. 

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Scheme 6. The synthesis of NADES using different methods81. 

Examples of HBAs are choline chloride, ethylamine hydrochloride, tetramethylammonium 

chloride, tetrabutyammounium chloride, N, N-diethyl 1-2 hydroxy ethanamidium chloride, and 

methyltriphenylphosphonium bromide , while examples of HBDs are malonic acid, citric acid, 

acetic acid, Urea, thiourea, glycerol, ethylene glycol, acetamide, fructose, glucose,  benzamide and 

imidazole. Some of the HBDs and HBAs structures presented in this review are depicted in Scheme 

2. The choice of the HBDs and the HBAs also depends on the application of the DESs, for example, 

as catalysts, solvents, electrolytes, or extraction agents82-84, in addition to the nature of the analyte 

to be evaluated or determined. 

3.2. Biodegradability and low toxicity of DESs

DESs are a class of alternative electrolytes that have low toxicity and high biodegradability, 

which makes them suitable for use as electrolytes in solar cells. DESs are formed by mixing a 

hydrogen bond donor and acceptor, usually derived from biological sources such as carboxylic 

acids, alcohols, amines, amides, and ammonium salts. The toxicological properties of DESs 

depend on the components used, so the choice of benign materials can produce solvents with low 

toxicity. In addition, microorganisms easily biodegrade DESs, reducing the environmental impact 

of the waste generated. DESs can improve the performance and durability of solar cells, as they 

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offer a stable electrochemical window, good solubility of CO2, low surface tension, and high 

conductivity 59, 85. 

As petroleum resources are dwindling worldwide, future work should focus on exploring 

the potential of using DESs as new “green” media for solar devices, fully replacing the hazardous 

and toxic VOCs that are still widely used. As discussed, many components of DESs are from 

natural sources 86, 87, leading to the introduction of natural deep eutectic solvents (NADES) that 

present extremely low toxicity and high biodegradability.

Entropy plays a crucial role in NADES formation; when components are mixed in the right 

proportion, their molecular interactions lead to a decrease in entropy, resulting in an eutectic point. Heating 

is often employed during NADES preparation; it aids in dissolving the components and promotes molecular 

interactions and eutectic formation. As scheme 7 demonstrates, when entropy rises, the strength of 

intermolecular bonding decreases, which subsequently impacts the relevant physical parameters86.

Scheme 7. Kinetic energy models for a binary NADES (A. temperature administration and 

B. water content administration) 86. 

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 3.3. Adding water to DESs

The addition of water to DESs used as electrolytes in solar cells can affect their 

conductivity and stability. Water can increase ion mobility and enhance the conductivity of DES 

electrolytes, resulting in improved performance of the solar cell 59. The substance Reline, 

composed of choline chloride (HBA) and urea (HBD), serves as one example. Electrochemical 

capacitors can use Reline as a green electrolyte to store electrical energy. Adding 1 wt.% water to 

Reline can increase the specific capacitance from 100 to 157 F g−1 at a 1 A g−1 current load. This 

means that more charge can be stored per unit mass. The addition of water can strengthen the 

hydrogen bonds between the NH and OH groups of the HBD molecules, which can enhance the 

charge transfer process. Another example of a DES is the mixture of choline chloride and lactic 

acid, which can also be used as an electrolyte for electrochemical devices. Adding water to this 

DES does not affect the interactions between the HBA and HBD molecules, but instead forms 

solvated clusters of the DES. This may affect the diffusion and mobility of the ions in the 

electrolyte, as well as the stability of the electrode materials 88. However, excessive amounts of 

water can also cause phase separation and decrease the stability of the DES electrolyte, leading to 

reduced efficiency of the solar cell. Therefore, the effect of adding water to DESs used as solar 

cell electrolytes will depend on the type and composition of the DES, as well as the amount of 

water added. Water can modify the structure and dynamics of the DES molecules, which in turn 

can influence the performance and efficiency of the solar cell.

 3.4. Solubility of CO2 in DESs

The solubility of CO2 in DESs is an important factor for using them as electrolytes in solar 

cells, as it affects the conductivity, stability, and performance of the devices. CO2 is a greenhouse 

gas that solar cells can capture and utilize to produce electricity and reduce emissions. However, 

the solubility of CO2 in DESs depends on several factors, such as the type and composition of the 

DES, the temperature and pressure of the system, and the presence of water or other additives.

The PC-SAFT equation of state has been used to estimate the solubility of CO2 in 109 

different DESs, covering a wide range of temperatures and pressures 89. It was found that the PC-

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SAFT model could provide accurate and reliable predictions of CO2 solubility in DESs. It was also 

possible to propose generalized correlations to predict model parameters for new and upcoming 

DESs.

Amine-based DESs are a type of green and sustainable solvents that can be used as 

electrolytes for solar cells. Amine-based DESs consist of a hydrogen bond acceptor (HBA) that is 

typically an amine, together with a hydrogen bond donor (HBD) that is usually an organic acid or 

a salt. They have a low melting point, high solubility, and high conductivity, which are desirable 

properties for solar cell electrolytes. They can also capture and utilize CO2, a greenhouse gas, to 

produce electricity and reduce emissions. 

An amine-based DES used as a DSSC electrolyte was able to achieve a power conversion 

efficiency of 6.8%, comparable to that of a conventional ionic liquid electrolyte, with the additional 

advantages of high electrochemical stability and low viscosity, which are advantageous for DSSC 

performance 59. A mixture of choline chloride and urea is another example of an amine-based DES 

that can also serve as an electrolyte for electrochemical capacitors (ECs), which are devices that 

store electrical energy by accumulating charges on the electrodes. In another study, DESs 60 

increased the specific capacitance and the voltage window of the ECs, enabling them to store more 

energy per unit mass and operate at higher voltages. It was also shown that adding a small amount 

of water to the DES could further enhance the charge transfer process and the cycle stability of the 

ECs.

Water is an eco-friendly and renewable solvent, but many reactions are slow in water. CO2 

has low solubility in water (0.033 M) under ambient conditions, 90 which limits the efficiency of 

its adsorption and conversion in solar cells. A common technique for CO2 capture is using amine 

solvents, which have high selectivity and capacity, but also have drawbacks such as high 

corrosiveness 91 and high energy consumption 92, which hinders their use in solar cells 93, 94. 

DESs have attracted attention in both experimental and theoretical studies, due to their 

ability to efficiently capture CO2. In particular, a combination of ethanolamine hydrochloride 

(HBA) and tetraethylenepentamine (HBD) in a ratio of 1:9, referred to as EAHC-TEPA, showed 

remarkable CO2 solubility, among several DESs investigated 95. Haider and Kumar 96  developed 

amine-based DESs with bulky structures that exhibited superior CO2 uptake, while maintaining 

minimal CH4 absorption, demonstrating a pronounced preference for CO2.

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Studies have explored the integration of CO2 sequestration and transformation using 

amine-based solvents that can absorb CO2 and serve as electrolytes for electrochemical conversion. 

Pérez-Gallent et al. 97 found that using both chemical and physical absorption solvents in 

combination led to high faradaic efficiencies (F.E.) of up to 50%, together with a 30% carbon 

conversion rate. An aqueous amine-based DES, [monoethanolamine 

hydrochloride][methyldiethanolamine] ([MEAHCl][MDEA]), achieved a high F.E. of 71% for 

production of CO at a potential of −1.1 V vs. RHE at an Ag electrode, which was 33% higher than 

for [MEAHCl][MEA]. Elsewhere, an innovative DES composed of choline chloride and ethylene 

glycol was utilized as an electrolyte in place of dimethyl formamide (DMF), enhancing the 

electrochemical CO2 reduction efficiency, due to its favorable CO2 solubility 98.  In a similar vein, 

[MEAHCl][MDEA], as a novel aqueous amine-based deep eutectic solvent, was formulated as an 

electrolyte for the reduction of CO2 to CO, showing a high faradaic efficiency of 71% for CO 

production at  −1.1 V vs. RHE at an Ag electrode, exceeding the performance of 

[MEAHCl][MEA] by 33% 99.

Building on these studies, other work developed a DES by combining choline 

chloride and ethylene glycol, for use as an electrolyte 100. This new formulation replaced 

dimethylformamide (DMF) and contributed to advancements in DSSC technology, showing 

improved efficiency in the electrochemical reduction of CO2, attributed to enhanced CO2 

solubility. Notably, the use of an Au electrode resulted in CO as the primary product, achieving a 

faradaic efficiency of 81.8%. Despite these findings, amine-based solvents remain the preferred 

choice for designing DESs with high CO2 solubility. 

In addition, imidazole and its derivatives have long been recognized as potent components 

in ionic liquids (ILs) and DESs for enhancing CO2 solubility 101, 102. In a study examining the 

effects of modifying the imidazole substituent groups, considering the compounds 2-

methylimidazole (2-MeIM), 2-ethyl-4-methylimidazole (2-Et-4-MeIM), and 1,2,4,5-

tetramethylimidazole (1,2,4,5-MeIM), the addition of 2 M 1-propyl-3-methylimidazolium iodide 

([PMIM]I) improved the capacity of the DESs to capture CO2 103. Boualavong and Gorski 104 

employed a chemical reaction equilibrium model to explore how variations in the substituent 

groups of imidazole affected CO2 capture efficiency and energy requirements. The authors 

proposed a method to reduce the energy consumption of electrochemical capture technologies by 

doubling the number of CO2 molecules captured per electron transferred. 

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Future research should address the existing gaps in assessment of the efficiency and energy 

requirements for solar cells incorporating imidazole (IM) or its derivatives such as 2-MeIM, 2-Et-

4-MeIM, and 1,2,4,5-MeIM into the formulated DESs composed of hydrogen bond donors and 

acceptors. Table 1 shows some of the reported DESs prepared using different HBDs and HBAs, 

together with their solubilities at various temperatures and pressures.

Table 1. DESs prepared using different HBDs and HBAs, with their solubilities at different 

temperatures and pressures.

DES components and absorption conditions

ILs/HBA    HBD Molar ratio    Solubility

(mol.mol-1)

T (K) P (bar) Reference

ChCl Urea 1:1.5 0.201 313.15 118.4 105

ChCl Ethanolamine 1:6 0.0347 298 10 106

ChCl EG 1:2 0.5396l 303.15 58.6 107

ChCl Urea 1:2 0.6 303.15 60 108

ChCl TEG 4:1 0.0667 293 5 109

ChCl Lactic acid 1:2 0.0248 348 19.27 110

ChCl Glycerol+DBN 1:2:6 0.111 Ambient Ambient 111

ChCl Urea+water 50%  0.111 313 7.8 112

TBAB Ethanolamine 1:6 0.0407 298 10 106

MTPPBr Ethanolamine 1:6 0.0518 298 10 106

BMIMCl MEA 1:4 0.214 Ambient Ambient 102

MEA.Cl EDA 1:3 0.2698 Ambient Ambient 113

TBAB MDEA 1:4 0.29 303.15 10 114

[DETA][IM] EG 1:2:2 0.2235 298.15 1.0 115

[bmim][tf2N] DBU 1:1 1.0 298 1.0 116

ChCl 1,4-Butanediol 1:3 0.0164 298 5.14 117

ChCl 2,3-Butanediol 1:4 0.0188 298 5.08 117

ChCl Glycerol 1:2 0.8589 303 58 118

TEG DBU 1:1 1.04 298 1.0 119

As shown in Table 1, the solubility of CO2 in DESs is influenced by both temperature and 

pressure. Generally, the solubility of a gas such as CO2 decreases with increase in temperature and 

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decrease in pressure 120. This is because higher temperatures provide more kinetic energy to the 

gas molecules, making them more likely to escape from the solvent. DESs, which are a type of 

ionic liquid, have been found to have good solubility for gases, including CO2, which can be 

advantageous for applications such as in solar cells. The solubility is typically expressed as the 

mass of the gas per unit mass of solvent, at a given temperature and partial pressure of the gas 121. 

For solar cells, specifically DSSCs, DESs can be used as electrolytes. Researchers have developed 

choline chloride-based DESs as effective electrolytes for these types of solar cells. They offer 

benefits such as easy preparation, low cost, biodegradability, and non-toxicity, which are important 

for large-scale production and commercialization 60.

The use of DESs as electrolytes in solar cells can potentially improve the open-circuit 

voltage and short-circuit current, depending on their molecular structures. This makes them an 

interesting area of research for enhancing the efficiency and eco-friendliness of solar cell 

technologies 60. In particular, the CO2 solubility in DESs can have significant implications for their 

use as green and sustainable electrolytes in solar cells. Amine-based DESs are promising 

candidates for solar cell electrolytes, offering benefits such as low cost, high efficiency, high 

stability, and environmental friendliness. However, understanding the underlying mechanisms and 

optimizing the properties and performance of these DESs requires further experimental and 

theoretical studies.

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4. DESs as electrolytes in dye-sensitized solar cells (DSSCs)

4.1. Preparation of DSSCs and their advantages

DSSCs are devices that convert light into electrical energy by receiving photons from 

sunlight which excite the electrons of the dye molecule, and are then injected into the TiO2 layer.

A DSSC (as shown in Scheme 8) classically consists of the following components 78: (1) a 

photo-sensitized anode, usually made of a semiconductor material such as titanium dioxide (TiO2), 

which has dye molecules on top of it that absorb sunlight and generate electrons; (2) an electrolyte 

that may be liquid or solid, usually possessing an iodide (I-) and tri-iodide (I3
-) couple that assists 

in moving electrons from the dye to the cathode; (3) a counter electrode, typically composed of 

platinum or other conductive material, which collects electrons and returns them to the electrolyte.

The iodide and triiodide ions constitute the redox couple commonly used in DSSC 

electrolytes, playing a crucial role in the operation of these solar cells by facilitating the transport 

of charge and contributing to the overall efficiency of the device. The iodide ion (I-) acts as a 

charge carrier, while the triiodide ion (I3
-) helps the oxidized dye molecules to regenerate, 

completing the electrical circuit of the cell 122. This redox couple is widely adopted due to its 

favorable recombination kinetics and ability to improve the performance of the solar cell.

The operation of a DSSC involves the dye molecules absorbing photons from sunlight and 

becoming excited, with subsequent injection of electrons into the conduction band of the 

semiconductor anode. From there, the electrons flow through an external circuit to do work (such 

as powering a device), before returning to the counter electrode. The redox mediator in the 

electrolyte then completes the circuit by regenerating the dye molecules.

The fabrication of DSSCs is mostly performed according to a well-established protocol 123, 

to prevent metal contamination. The glass or Teflon containers are firstly cleaned with ethanol 

(EtOH) and a 10% hydrochloric acid (HCl) solution. Throughout the fabrication process, only 

plastic tools (such as spatulas and tweezers) are utilized. Fluorine-doped tin oxide (FTO) glass 

substrates are cleaned by immersion for 15 min in an ultrasonic bath with detergent, thorough 

rinsing with deionized water and EtOH, and exposure to a UV-O3 for 18 min. The UV-O3 method, 

which combines ultraviolet (UV) light and ozone (O3) for surface cleaning and treatment, is 

particularly effective for removing organic contaminants from surfaces, without damaging the 

sample. After cleaning, the substrates are soaked for 30 min in a 40 mM TiCl4 solution, at 70 °C, 

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https://pubs.rsc.org/en/content/articlelanding/2020/ta/d0ta07377f


followed by rinsing. A transparent layer of TiO2 (determined by measurement of an area of 0.20 

cm2) is applied onto the substrate using a screen-printing technique, with a 20 nm particle size 

paste. After applying the TiO2 layer, the material is submitted a series of drying and heat treatments 

at progressively higher temperatures. After sintering, the layer is treated again with TiCl4 and 

heated to 500 °C for 30 min. For the preparation of counter electrodes, a 1 mm hole is drilled into 

an FTO plate, followed by application of the same cleaning process used for the FTO glass 

substrates. A 10 μL H2PtCl6 solution in EtOH is deposited onto the plate, and then heat-treated at 

500 °C for 30 min. At the time a hot-melt ionomer resin spacer is inserted between the dye-coated 

TiO2 electrode and the counter electrode. Subsequent, the electrolyte solution is introduced into 

the cell through the drilled hole, using a vacuum backfilling method, and the hole is sealed. Light 

absorption is enhanced by attaching a reflective foil to the rear side of the counter electrode, 

directing any unabsorbed light back towards the photoanode.

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Scheme 8. Schematic illustration of the structure of a dye-sensitized solar cell device 78.

A survey of commonly used photocatalyst substances 124, 125 revealed that they fall into 

three main categories: semiconductor materials, graphene-based nanocatalysts, and organometallic 

complexes. The semiconductor group includes a diverse range of inorganic binary compounds, 

including (but not limited to) TiO2, ZnO, CdS, and SiC. The performance of these semiconductor 

photocatalysts depends on a few critical factors: (1) the band gap width of the semiconductor, 

which determines the photon absorption spectrum for generation of electron-hole pairs; (2) 

efficient separation and transport of the electron-hole pairs to the surface of the material; and (3) 

the number and accessibility of active sites that are available for the photocatalytic reactions to 

occur.

DSSCs offer several advantages that make them an attractive option for solar energy 

conversion, including: (1) low manufacturing cost, since DSSCs can be produced at a lower cost 

than traditional silicon-based solar cells 123 ; (2) absorption of fluorescent light, in addition to 

sunlight, which is beneficial for indoor applications 123 ; (3) flexibility in the design and application 

of the solar cells, as a result of the thin-film nature of DSSCs 126 ; (4) good performance under 

conditions of low light, making them useful in less sunny climates 127; (5) use of eco-friendly 

materials in the construction of DSSCs, contributing to a greener production process 128 ; (6) 

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versatility for use in a wide range of environments and ability to be integrated into various solar 

products 128. 

The unique properties of DSSCs make them an innovative solution for sustainable and 

adaptable energy generation. They are highly suitable for powering portable devices and are ideal 

for low-density power needs where conventional solar panels might be limited in terms of 

efficiency or cost-effectiveness. Standard roll-printing methods can facilitate the production of 

DSSCs, enhancing their appeal by features such as partial flexibility, translucency, and the use of 

economical materials.

Nonetheless, DSSCs still have some drawbacks, such as the requirement for expensive 

components including platinum and ruthenium, while the liquid electrolyte can cause problems 

that make them less durable and unable to function in all weather conditions. Despite these hurdles, 

DSSCs stand out as a viable and cost-effective alternative to traditional silicon-based photovoltaic 

cells, particularly for applications that demand flexibility and affordability.

4.2. Application of DSSCs in CO2 conversion

DSSCs have recognized potential in various applications, including the conversion of CO2 

to obtain useful products 129. The literature lacks specific details on the application of DSSCs in 

CO2 conversion, but nonetheless highlights the versatility and benefits of DSSCs for use in energy 

harvesting and low-carbon technologies. DSSCs can be integrated into systems that aim to reduce 

CO2 levels by converting the gas into valuable chemicals or fuels by photocatalytic processes. The 

ability of DSSCs to effectively harness solar energy makes them suitable for powering reactions 

that can transform CO2 into compounds such as formic acid, methanol, or other carbon-based 

products. This process not only helps in mitigating CO2 emissions, but also provides a sustainable 

pathway for chemical synthesis.

This process essentially mimics photosynthesis 78, using solar energy to convert CO2 into 

organic compounds. The efficiency and selectivity of the CO2 conversion depend on various 

factors, including the type of dye used, the semiconductor material, and the nature of the redox 

couple. Research is ongoing to optimize these aspects and improve the overall efficiency of the 

process. DSSCs offer a promising route for sustainable energy production and CO2 utilization, 

contributing to the reduction of greenhouse gases and the generation of renewable fuels.

Page 30 of 89RSC Advances

https://link.springer.com/article/10.1007/s11664-021-08854-3
https://link.springer.com/article/10.1007/s11664-021-08854-3
https://link.springer.com/article/10.1007/s11664-021-08854-3
https://link.springer.com/article/10.1186/s11671-018-2760-6
https://link.springer.com/article/10.1186/s11671-018-2760-6
https://link.springer.com/article/10.1186/s11671-018-2760-6


Improving the capability of solar cells to convert solar energy and CO2 into high-value 

products such as HCOOH, CO, CH2O, CH3OH, and CH4 is of paramount importance 130. The 

family of carboxylic acids is varied, including compounds such as formic acid, acetic acid, benzoic 

acid, acetylenic acid, amino acids, and lactic acid, which can be produced by different 

photocatalytic reaction pathways. Scheme 9 shows different chemical produces from CO2 

Any chemical transformation of CO2 requires energy, but there are distinct processes with 

varying energy requirements. Low-energy processes incorporate the entire CO2 molecule into an 

organic or inorganic substrate. For instance, consider the series: CO2 → HCOOH (formic acid) → 

CO → CH2O (formaldehyde) → CH3OH (methanol) → CH4 (methane). These reactions primarily 

yield products used in the chemical industry. In high-energy processes, the carbon atom’s 

oxidation state is reduced from +4 in CO2 to -4 in methane (CH4). These processes have the 

potential to produce fuel 130. If we focus solely on chemical synthesis, we’ll recycle limited 

amounts of CO2. However, if we prioritize fuel we could potentially recycle larger volumes of 

CO2. The ongoing processes developments relevant to the chemical industry, and reactions 

pertinent to the energy sector. Ultimately, finding sustainable energy solutions will be a key to 

unlocking the full potential of CO2 conversion130. 

Scheme 9.  Production of chemicals from CO2 at different energy level.

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However, the large-scale synthesis of carboxylic acids faces challenges, especially when it 

involves the conversion of lignocellulosic biomass, which requires hydrolysis and electrophilic 

attack by metal-organic reagents. These processes often have drawbacks such as high energy 

consumption, low efficiency, and poor product selectivity 134, 135. To address these issues, the 

adoption of green and efficient methods is crucial for the production of diverse carboxylic acids 

by CO2 reduction. Carboxylic acids are attractive products, with high commercial value and 

advantages including low toxicity, high energy density, and greater energy value per kilowatt-

hour, compared to other products. These acids are utilized in a wide range of industries, from 

rubber production to the manufacture of flavorings, cosmetics, pharmaceuticals, and pesticides.

4.3. Mechanism of CO2 conversion in DSSCs

In DSSCs, the conversion of CO2 is facilitated by a photoelectrochemical process, with the 

DSSC acting as a catalyst for the transformation of CO2 into useful substances. Sunlight is captured 

by the dye sensitizer, which then energizes the electrons of the dye. These energized electrons are 

propelled into the conduction band of the semiconductor (typically TiO2), which constitutes the 

anode. The electrons then traverse the external circuit and reach the cathode, where they participate 

in reduction reactions. At this stage, the electrons convert CO2 into a variety of carbon-based 

compounds, such as hydrocarbons or alcohols. Concurrently, the dye molecules, now oxidized, are 

regenerated by acquiring electrons from the redox couple of the electrolyte solution. Electrons 

flowing from the cathode replenish the redox couple, closing the electrical loop 123.

Enhancing the efficiency of solar cells is crucial for optimizing the conversion of solar 

energy and CO2 into valuable products such as HCOOH, CO, CH2O, CH3OH, and CH4 130. 

Among these products, carboxylic acids, especially formic acid (HCOOH) 133, are of particular 

interest, due to their commercial significance and attractive characteristics including low 

toxicity, high energy density, and greater energy value per kWh, compared to other products. The 

versatility of formic acid enables its use in many industrial applications, including those mentioned 

above.

Carboxylic acids encompass a diverse array of compounds, including formic acid, acetic 

acid, benzoic acid, acetylenic acid, amino acid, and lactic acid. In photocatalytic processes, these 

acids can be synthesized according to various pathways (see Scheme 10). However, the industrial 

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production of carboxylic acids has been hindered by the fact that methods involving the breaking 

down of lignocellulosic biomass by hydrolysis and electrophilic attack with metal-organic reagents 

have high energy costs, low efficiency, and poor product selectivity 131, 132. To address these issues, 

there is an urgent need for sustainable and effective techniques to generate a range of carboxylic 

acids by CO2 reduction. Honda et al. accomplished the photocatalytic reduction of CO2 to 

hydrocarbons in 1970 134. Subsequent research has continued to advance the field of photocatalytic 

CO2 reduction 135-137.

Green methods for producing carboxylic acids offer several significant benefits: (1) they 

are environmentally sustainable, since these methods typically avoid the use of heavy metals and 

strong acids, reducing the environmental impact; (2) green techniques often require less energy, 

contributing to lower production costs and a smaller carbon footprint; (3) cost-effectiveness is 

improved by the absence of byproducts and the ability to recover and recycle solvents; (4) harmful 

emissions are reduced in processes that do not generate nitrogen oxides (NOx) or other greenhouse 

gases that have climate implications; (5) the use of renewable feedstocks contributes to the long-

term sustainable production of carboxylic acids. These advantages align with the global shift 

towards more sustainable and eco-friendly industrial processes 138.

The process of converting CO2 into carboxylic acids by photocatalysis, shown in Scheme 

10, begins when the catalysts, typically semiconductor materials, are subjected to light irradiation. 

This exposure causes electrons within the semiconductor to become excited, leaving behind 

positively charged vacancies known as holes. These photogenerated electron-hole pairs are crucial 

to the process, as they are separated and directed towards the active sites of the catalyst.

Once at the surface, the photogenerated electrons assist in the reduction of CO2, 

transforming it into various useful fuels (CO, CH4, CH3OH, and others). The presence of water 

(H2O) can influence the reaction, but is not always necessary. The number of electrons 

participating in the chemical reaction determines the specific products formed during this process. 

For instance, the formation of CO or formic acid (HCOOH) requires two electrons (2e-), while the 

production of methanol (CH3OH) necessitates six electrons (6e-), and methane (CH4) production 

requires eight electrons (8e-) 139, 140.

This photo-electrocatalytic process is a promising green technology for CO2 reduction, as 

it utilizes sunlight, a renewable energy source, and can potentially lead to the creation of valuable 

chemicals and fuels. The efficiency and selectivity of the process can be influenced by the choice 

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https://pubs.rsc.org/en/content/articlelanding/2020/gc/d0gc02627a
https://phys.org/news/2023-08-carboxylic-acids-environmentally-friendly-technique.html
https://phys.org/news/2023-08-carboxylic-acids-environmentally-friendly-technique.html
https://www.miragenews.com/green-method-employs-carboxylic-acid-production-1073173/
https://www.miragenews.com/green-method-employs-carboxylic-acid-production-1073173/
https://phys.org/news/2023-08-carboxylic-acids-environmentally-friendly-technique.html
https://phys.org/news/2023-08-carboxylic-acids-environmentally-friendly-technique.html
https://phys.org/news/2023-08-carboxylic-acids-environmentally-friendly-technique.html
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of semiconductor material, the design of the catalyst, and the reaction conditions. Studies continue 

to explore and optimize these factors to enhance the conversion rates and the yields of desired 

products 141.

Scheme 10. Different carboxylic acid reaction paths in solar cells 130.

4.4. DESs as electrolytes in DSSCs 

Deep eutectic solvents (DESs) are used as electrolytes in solar cells due to several 

compelling benefits. DESs are biodegradable and nontoxic, making them environmentally 

friendly, as well as cost-effective and able to enhance certain performance metrics of solar cells, 

such as the open-circuit voltage (Voc) and the short-circuit current (Isc), depending on their 

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molecular structure. They are inexpensive to produce and can be prepared on a large scale, which 

is advantageous for commercialization. Furthermore, they are stable and can contribute to the long-

term stability of solar cells, which is crucial for practical applications. In addition, DESs can 

dissolve a wide range of substances and their physicochemical properties can be tuned by including 

different hydrophilic or hydrophobic components. These properties make DESs suitable for use in 

DSSCs and other photovoltaic devices, aligning with the goals of producing low-cost and eco-

friendly materials for large-scale production 60, 141.

As discussed above, DSSCs consist of an anode made of a thin titanium dioxide (TiO2) 

layer that is sensitized by a suitable dye 142, 143. A cathode containing Pt nanoparticles and a liquid 

electrolyte solution with a redox couple facilitate dye regeneration and complete the electrical 

circuit. The affinity of the dye for water (hydrophilicity) or its repulsion of water (hydrophobicity), 

as well as the choice of metal for dye optimization, are critical factors in enhancing the efficiency 

of photochemical cells and have been the subject of extensive research 25, 144, 145. Volatile organic 

compounds (VOCs), such as acetonitrile or nitriles, are commonly used as solvents in electrolyte 

solutions for DSSCs. However, drawbacks of VOCs include flammability, volatility, and possible 

toxicity. This can hinder the wider adoption of DSSCs as environmentally sustainable sources of 

renewable energy. 

In the DSSC, the dye molecule becomes excited when exposed to light, transferring an 

electron to the TiO2 and a hole to the redox couple, for the process to work. This process resets the 

dye to its original state, allowing the device to continue functioning and prepare for the next cycle. 

The I−/I3
− redox couple is the one most used in DSSCs, although other redox couples such as 

CO2+/CO3+ or Cu+/Cu2+ have also been explored for their potential benefits 146, 147.

4.5. Efficiency of DSSCs (J/V curve) 

The efficiency of DSSCs is often represented by the J/V curve, which is a plot of the current 

density (J) vs. the voltage (V), under illumination. The J/V curve measurement is a crucial 

technique for characterizing solar cells, involving determination of the current density (J) 

generated by the cell as the applied voltage (V) is varied, under a solar light source. This curve, 

obtained under illumination, enables determination of all the key parameters of a photovoltaic (PV) 

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https://www.mdpi.com/1420-3049/27/3/709
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https://www.mdpi.com/1420-3049/27/3/709
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device, such as the power conversion efficiency (PCE) as a very important factor, the short-circuit 

current density (Jsc), the open-circuit voltage (Voc), and the fill factor (FF). The Jsc value represents 

the peak current output of the cell, observed at zero voltage, while the Voc represents the highest 

voltage achievable, measured when the current output is zero. FF is a measure of the power output 

efficiency of the cell, calculated as the ratio of the actual power output (Pout) to the theoretical 

maximum power (Jsc × Voc). PCE is defined as the ratio of the power output (Pout) to the power 

input (Pin), with the output power density being the product of Jsc, Voc, and FF. Therefore, PCE 

can be expressed by the following equation: 

(η) PEC      (1)=
Jsc ×  Voc ×  FF

Pin

Several strategies can be used to improve the efficiency of DSSCs, such as optimizing the 

dye molecules, using dyes with broader light absorption spectra (including the visible and near-

infrared ranges) to capture more sunlight, improving the redox mediator, or using solid-state hole 

transport materials (HTMs) for better charge transport and reduced recombination. Improvement 

of photoanodes can be achieved using nanostructured materials (such as TiO2) to increase the 

surface area available for dye adsorption and light harvesting. Counter electrodes composed of 

alternative carbon-based or platinum materials can present enhanced catalytic activity and 

stability. By focusing on these areas, studies aim to extend the limits of DSSC performance, 

making them more competitive with traditional silicon-based solar cells 78, 148, 149. 

The highest occupied molecular orbital (HOMO) and lowest unoccupied molecular orbital 

(LUMO) levels of the sensitizer play a pivotal role in DSSCs, and understanding the interplay 

between HOMO/LUMO levels, charge distribution, and the sensitizer’s mechanism is essential for 

designing efficient DSSCs to offer promise for clean, renewable energy production and contribute 

to sustainable development. The HOMO represents the energy level of the highest electron that 

can be excited, while the LUMO represents the lowest energy level of an unoccupied electron. The 

sensitizer enables electron injection into the semiconductor. Efficient sensitizers have a small 

energy gap between their HOMO and LUMO levels. The small distance between the two entities 

results in enhanced charge separation during the process of photo excitation 150. Sensitizers are 

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crucial because they absorb sunlight and generate excited electrons. They must have appropriate 

HOMO and LUMO levels to match the redox potentials of the semiconductor and the electrolyte. 

Sensitizers can be organic (metal-free) or inorganic (such as ruthenium-based dyes).  Organic 

sensitizers are chosen because they are not toxic, readily available, and cost-effective 151.

Theoretical studies, especially using Density Function Theory (DFT), provide valuable 

insights for advancing solar cell technology by considering HOMO/LUMO levels, charge 

distribution, and the sensitizer’s mechanisms. In the charge distribution mechanism, when sunlight 

hits the DSSC, the sensitizer (usually an organic dye) absorbs photons and gets excited. The 

excited sensitizer transfers an electron from its HOMO to its LUMO level. This electron then 

moves to the semiconductor (often titanium dioxide, TiO2) through the electrolyte. The difference 

in chemical potential between the electrolyte and the semiconductor drives this charge transfer.

Researchers employ DFT to investigate the electronic structure and properties of 

sensitizers. DFT calculations show that HOMO and LUMO are spread out in space at the interface. 

This helps excitation break apart and lines up the energy levels in a way that is good for charge 

transport. An investigation was conducted on graphene-based sensitizers using Density Functional 

Theory (DFT) and Time-Dependent Density Functional Theory (TD-DFT) in order to comprehend 

their influence on photophysical properties150. Additional research investigates potential 

sensitizers for DSSC, such as nanocomposites of graphene quantum dot hybrids and their Cu-

metallated macrocycles 151. Besides, other study examined the structural and electrical 

characteristics, as well as the absorption spectra, of supramolecular triads consisting of fullerene 

and porphyrine in DSSCs152. The HOMO and LUMO states of the C60-P-Mp triad are primarily 

located on the Mp unit, with the C60 cage unit acting as the donor and the C60 fullerene unit acting 

as the acceptor. This pattern is observed in the C60-P-ZnPDouble complex, C60-P-FeP, and C60-

P-ZnP complexes. When the position of porphyrine and ZnP changes, the HOMO density is mostly 

on the C60 fullerene and linkage groups. On the other hand, the LUMO density is mostly in the 

porphyrine moiety 152.

Optimizing the band gap, maximizing JSC, and achieving an appropriate Voc are essential 

for enhancing the overall performance of DSSCs. Researchers continually explore new materials 

and sensitizers to improve these parameters and make solar energy conversion more efficient 152, 

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153. There is a difference in energy between the molecular orbitals that are most full (HOMO) and 

least full (LUMO) in the semiconductor material, which is usually titanium dioxide (TiO2). This 

is called the band gap (Eg). A smaller band gap allows the semiconductor to absorb a broader 

range of photons from sunlight.

As explained, when a photon with energy greater than the band gap is absorbed, an electron 

is excited from the valence band (HOMO) to the conduction band (LUMO). The band gap 

influences the efficiency of charge separation and electron injection into the semiconductor. Short-

Circuit Current Density (JSC) represents the maximum current density generated by the DSSC 

under short-circuit conditions (i.e., when no external load is connected), and it depends on the 

following factors: a) photon absorption: A larger band gap results in a lower JSC because fewer 

photons are absorbed. B) sensitizer efficiency: c) efficient sensitizers absorb more photons, 

generate more excited electrons, and f)charge transport: More electrons moving from the sensitizer 

to the semiconductor is what causes higher JSC. This is directly related to the amount of photons 

absorbed and how well charges are transferred. Furthermore, open-circuit voltage (Voc) is the 

voltage across the DSSC terminals when no current flows (i.e., under open-circuit conditions), and 

it is dependent upon the following factors: a) recombination losses: b) reducing charge 

recombination improves Voc, which is directly related to the energy alignment between the 

sensitizer and the redox couple; c) energy levels: d) the difference between the sensitizer's 

HOMO/LUMO levels and the electrolyte's redox potential; and e) electron injection efficiency: 

Higher Voc is the result of efficient electron injection 152.

The Light Harvesting Efficiency (LHE) of DSSCs is a key factor in their performance. 

LHE measures the efficiency of a DSSC in capturing and converting incoming solar energy into 

useful electrical energy. It denotes the proportion of photons that are absorbed and contribute to 

the production of photocurrent 153. A higher LHE results in improved utilization of sunshine, which 

in turn leads to an improvement in power conversion efficiency (PCE).

Effective light harvesting maximizes the utilization of the sensitizer's absorption spectrum. The 

sensitizer of choice determines the absorption spectrum. Sensitizers with a wide range of 

absorption spectra improve LHE. It is very important that electrons move efficiently from the 

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excited sensitizer to the semiconductor material, like TiO2. Maximizing LHE involves minimizing 

charge recombination and enhancing light trapping within the DSSCs 152.

In order to enhance LHE, it is necessary to fine-tune the sensitizing properties, developing 

sensitizers with ideal HOMO-LUMO energy levels and absorption characteristics 153. In addition, 

the integration of nanostructures such as nanowires and nanoparticles can be employed to improve 

the capture and absorption of light 154. Light harvesting can be made even more effective by using 

different sensitizers that have absorption spectra that work well with each other and by making the 

path length of photons longer inside the cell 155.

The calculated LHE for triad complexes using ZINDO/S method reported 152, the highest 

value of oscillatorstrength (13.8) is related to the C60-P-NiP in 545.1 nm wavelengths while lowest 

value (0.46) belongs to the C60-P-TiP in 478.5 nm.

The study on the same evaluation for Zn complexes 152 revealed that the oscillator strength value 

for C60-P-ZnP (5.20) is higher than C70-P-ZnP (3.95), when the position of porphyrine and ZnP 

changed in C60-P-ZnP complex and the LHE and oscillator strength was enhanced. The same 

trend is observed in doubly C60-P-ZnP complex. In this case the oscillator strength value is 8.20, 

and consequently the LHE increase sharply. In conclusion, the LHE was improved by increasing 

the conjugation, and it is exhibited that doubly complex with longer π conjugations showed 

oscillator strength and light harvesting efficiency, thus leading to higher triad efficiency, and 

stability. Similar estimation has also been carried out for the same triad and reported 152. 156.

ILs/DESs have been used as electrolytes in DSSCs since 2009 17, including a quaternary 

ammonium salt-derivative ionic liquid called G.CI, which is a eutectic mixture of glycerol (GLY) 

and choline iodide (CI), in a specific ratio, with 0.5 M of a mixture of N-methylbenzimidazole and 

1-propyl-3-methylimidazolium iodide ([PMIM]I). The high cell performance made the G.CI DES 

a strong candidate for use in the future development of DSSC electrolytes.

Other studies 157, 158 have investigated the development of novel eco-friendly DESs for use 

as electrolytes in DSSCs, such as DESs formulated from chlorine chloride (ChCl) and ethylamine 

hydrochloride (MEA.Cl) as hydrogen bond acceptors (HBAs), combined with hydrogen bond 

donors (HBDs) such as glycerol (Gly), ethylene glycol (EG), and imidazole (IM), in varying HBD 

to HBA molar ratios (1:1, 1:3, and 1:6). 

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The findings of the present review, considering the existing literature, indicate the need for 

further research to fully understand the processes involved in the use of these DESs, with a focus 

on the HBDs and HBAs illustrated in Table 2 summarizes the DESs used as electrolytes in DSSCs, 

reported in the literature.

Table 2. Overview of DSSCs using DESs as electrolytes (T = transparent layer, S = scattering 
layer). 

DESs Iodide 
source

Dye / other 
adsorbent

TiO2
thickness

Dilution                              
Remark

Advantages Ref.

Choline chloride 
+ glycerol

PMII 13:7 v/v 
3 M

D149 6 μm T +
5 μm S

15% w/w water Pioneering work that opened new 
possibilities for ionic liquid-based 
DESs in DSSCs.

Introduced a new type of DES for 
DSSCs, potentially enhancing 
electrolyte performance.

17

Aqueous choline 
chloride-based 
DESs

KI 2 M
PMII 2 M

PTZ-TEG /
GlcA 1:10

5 μm T
2.5 μm T

40% w/w water
Showcased the practicality of 
aqueous DES in real-world 
applications.

Demonstrated effective use of 
aqueous DES as an electrolyte 
solution in DSSCs.

16

Menthol-based 
hydrophobic 
eutectic solvent, 
DL-menthol
/AcOH

DMII 1.0 M PTZ-Glu /
GlcA 1:10

2.5 μm T
10% v/v EtOH Focused on sustainability and 

environmental friendliness.

Designed eco-sustainable DSSCs 
with improved electrolyte medium.

47

Sugar-based 
natural DESs;
choline chloride-
Gly, -Glu, -Sorb,
  -Fru, -Man

PMII 2 M PTZ-Glu /
GlcA 1:10

2.5 μm T
20% w/w water
30% w/w water
40% w/w water

Highlighted the performance 
benefits of using natural 
components.

Used eco-friendly DES for better 
electrolyte solutions in DSSCs, 
showing active role in performance 
increase.

159

Choline chloride 
+ ethylene glycol 
(EG)

KI 0.6 M
KI 0.3 M
EmimI 0.3 M
EmimI 0.6 M

N719 T 5% v/v water Offered a comprehensive 
understanding of DES behavior in 
DSSCs.

Provided insights from both 
experiment and simulation on DES 
in DSSCs.

54

Canonical choline 
chloride-based 
DESs

KI 0.5 M N719 T 30% w/w water Assessed the benchmark DES, 
setting a standard for comparison.

Evaluated the performance of 
canonical DES as DSSC 
electrolytes.

50

Alkali iodide 
DES;
LiI/EG 
NaI/EG 
KI/EG 

Used in 
prepared 
DESs

N719 10 μm T +
5 μm S

No diluting
agent

Investigated new DES formulations 
for potential improvements.

Explored alternative DES 
electrolytes for DSSCs.

160

Choline chloride 
+ urea

Coupled 
redox 
mediator 
(e.g., I−/I3

−)

N719 T No diluting
agent

Improved open circuit voltage (Voc). Simple preparation, biodegradable, 
low-cost.

60

Choline chloride 
+ ethylene glycol

Coupled 
redox 
mediator 
(e.g., I-/I3

-)

N719 T No diluting
agent

Increase in short circuit current (Isc). Nontoxic, available materials, 
comparative conversion efficiency.

60

Betaine + 
glycerol

Coupled 
redox 
mediator 
(e.g., I−/I3

−)

N719 T No diluting
agent

Comparable efficiency to 
conventional electrolytes.

Renewable, biodegradable, non-
corrosive.

60

Choline chloride 
+ phenol

Redox 
mediator 
(e.g., I−/I3

−)

N719 T No diluting
agent

Improved Voc values by 10-40 mV, 
higher short circuit current (Jsc) not 
observed with 4-TBP

Eco-friendly, low cost, simple 
synthesis, used new efficient and 
eco-friendly additives.

77

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The key parameters to assess in DSSC applications include the open-circuit voltage (Voc), 

the short-circuit current density (Jsc), the fill factor (FF), and the overall power conversion 

efficiency (η). Certain DESs are emerging as promising electrolytes for DSSC applications, due 

to their ability to achieve higher Voc values (up to 140 mV), maintain comparable FF, but exhibit 

lower Jsc, when compared to a standard electrolyte, under identical experimental conditions. The 

use of these DESs in DSSCs requires determination of their total energy efficiency and viability 

as sustainable electrolytes.

Another crucial metric is the external quantum efficiency of a DSSC, which quantifies the 

efficiency of conversion from incident photons to the current generated. This efficiency is known 

as the incident photon-to-current conversion efficiency (IPCE) and varies with the wavelength (λ). 

For this assessment, the photocurrent is measured under open-circuit conditions, during exposure 

of the cell to monochromatic light. The IPCE is calculated for each point by determining the ratio 

of the number of electrons harvested to the number of incident photons, at a specific wavelength 

(λ) 17, 161.

In the context of DSSCs, it is essential to consider the following aspects: robustness of the 

absorption coefficients and the capacity of the designed DESs to dissolve CO2; significant molar 

extinction coefficients; and toxicity and ecological consequences. Furthermore, it is essential to 

undertake a thorough analysis of the physicochemical characteristics of DESs, the underlying 

absorption mechanisms, and the influence of the molar quantities of hydrogen bond acceptors 

(HBAs) and hydrogen bond donors (HBDs) utilized in the formulation of DESs.

In a study by Nguyen et al. 18, a novel electrolyte for DSSCs was formulated by blending 

a choline chloride-phenol DES with acetonitrile (ACN), in varying proportions. The most 

favorable outcomes were obtained using an electrolyte composed of 20% DES in ACN, together 

with 0.03 M iodine, 0.6 M tetrabutylammonium iodide, 0.1 M guanidinium thiocyanate, and 0.5 

M 4-tert-butylpyridine. This specific composition was instrumental in enhancing the stability and 

photovoltaic efficiency of the DSSCs. The improvement was attributed to the interaction of the 

choline and phenol components of the DES with the TiO2 surface, which was more effective than 

in cells without DES.

One of the pioneering studies to demonstrate the potential of DESs as solvents in DSSCs 

was the work of Jhong et al. 17, who employed an electrolyte solution consisting of 0.2 M iodine 

and 0.5 M N-methylbenzimidazole, mixed with 1-propyl-3-methylimidazolium iodide and a 

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choline iodide/glycerol DES. This solution was used in conjunction with the organic sensitizer 

D149. Building on this research, Boldrini et al. 16 introduced an aqueous electrolyte based on a 

choline chloride-glycerol DES, which included iodine, potassium iodide, or PMII, and additional 

compounds such as guanidinium thiocyanate, 4-picoline, or pyridine, paired with a phenothiazine-

based organic dye as the photosensitizer.

Many investigations have aimed at the development of highly efficient DSSCs. A binary 

solution of deep eutectic solvent (DES) with acetonitrile (ACN) showed the most promising 

results, among these studies 25, 162, 163. It was found that this mixture greatly improved the diffusion 

of the redox couple (I−/I3
−) and the electrochemical properties of the electrolyte solutions, resulting 

in satisfactory functioning of the device. Studies have also tested the use of additives including 

PMII, GuSCN, pyridine, 4-tBP, and ACN to further enhance the performance of DSSCs 16, 18. 

However, despite the promising results, potential toxicological issues and high volatility may limit 

the practical applications of these additives. Therefore, there is a need for safer and more efficient 

alternatives for large-scale practical applications. Continued research is necessary to identify and 

develop new additives that can improve the performance of DSSCs, without compromising safety 

or practicality. With further advancements in this field, DSSCs have the potential to become a 

highly efficient and sustainable source of renewable energy.

To better understand the movement of electron carriers in electrolyte solutions and their 

interactions with solvents and surfaces, molecular dynamics (MD) simulations have been utilized 

in conjunction with experimental methods to investigate the effects of electrolytes on DSSC 

efficiency 164-166. 

One area of focus was the behavior of DES composed of choline chloride and ethylene 

glycol (ChCl-EG), at a 1:2 molar ratio, as solvent in DSSC electrolytes. The aim was to examine 

the photovoltaic properties of a DES-based electrolyte for DSSCs. The ChCl-EG DES was chosen 

due to its relatively high ionic conductivity of 7.61 mS cm−1 at 298 K, attributed to its lower 

viscosity than other DESs that have been studied. Elsewhere, a 40% water content of a DES 

consisting of choline chloride and glycerol (ChCl/Gly, 1:2 mol/mol) was reported to provide an 

effective electrolyte solvent for DSSCs 16. This study found that the best DSSC performance was 

obtained using a 2 M concentration of 1-propyl-3-methylimidazolium iodide ([PMIM]I) and 0.1 

M of guanidinium thiocyanate (GuSCN) in a 40% aqueous solution of ChCl:Gly, resulting in a 

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power conversion efficiency (PCE) of 1.7%. Further research is necessary to explore the potential 

of DESs with other additives for improving DSSC performance in a safe and practical manner.

A recent study 161 investigated the use of different alkali metal iodide-based deep eutectic 

solvents (DESs) as electrolytes for DSSCs. These DESs included LiI:nEG, NaI:nEG, and KI:nEG, 

with varying amounts of iodine added to improve their performance. The results showed that the 

open-circuit voltage (Voc) under illumination increased with increasing cation radius from Li+ to 

K+. When compared to a reference electrolyte in the same experiment, the DESs had higher Voc 

(up to 140 mV), similar fill factor values, but lower current density values. After optimization, the 

DES electrolytes could be used in DSSCs as a promising alternative to electrolytes based on 

volatile organic compounds. A mixture of choline chloride (ChCl, 1 mol) and ethylene glycol (EG, 

2 mol) in combination with lithium iodide (LiI), 1-ethyl-3-methylimidazolium iodide (EMIM), 

MeCN, and iodine was used to develop a cost-effective and sustainable DES-based electrolyte 

solution for DSSCs with TiO2 and Pt electrodes. Different iodine amounts were added to the 

original DES electrolyte to improve its electrolytic performance. On illumination, Voc increased 

with increase of the cation radius from Li+ to K+. When compared to a reference electrolyte, under 

the same experimental conditions, these DESs presented higher Voc values (up to 140 mV) and 

similar FF values. However, they had lower current density values. Improvement of these DES 

electrolytes could enable their use in DSSCs as a viable alternative to VOC-based electrolytes. 

Subsequently, a cost-effective and sustainable DES electrolyte was successfully developed, 

consisting of a mixture of choline chloride (ChCl, 1 mol) and ethylene glycol (EG, 2 mol) in 

combination with lithium iodide, 1-ethyl-3-methylimidazolium iodide (EMIM), MeCN, and 

iodine, for use in a DSSC with TiO2 and Pt electrodes 161.  

4.6. Challenges, opportunities and future directions

The utilization of DESs in environmentally-friendly DSSCs presents both opportunities and 

challenges, such as: (1) traditional liquid electrolytes have drawbacks such as volatility and 

environmental hazards; on the other hand, DESs electrolytes face viscosity issues, and high 

viscosity in DES can hinder ionic diffusion of redox mediators, affecting conversion efficiency. 

(2) Finding suitable DES-based electrolytes remains a challenge for large-scale DSC production. 

(3) DES stability at elevated temperatures is crucial to study to prevent thermal degradation of 

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components. (4) Knowing when DES changes phases (solid, liquid, or gel) is important for getting 

the most out of their use in DSSCs. The density and viscosity of DES affect how they flow inside 

the solar cell. High ionic conductivity is desirable for efficient charge transfer. (5) The properties 

of surface tension and polarity influence DES wetting behavior on the TiO2-loaded dye-sensitized 

photoanode. The advantages included: (1) they can be synthesized from inexpensive, nontoxic 

starting materials, making them eco-friendly and offering a low-cost alternative to conventional 

ionic liquids. (2) DES-based solar cell devices exhibit competitive conversion efficiency compared 

to popular ionic liquids, which increase the efficiency of the cells. Because of the advantages of 

utilizing deep eutectic solvents (DES) in environmentally friendly DSSCs, researchers continue to 

explore DES properties and address challenges to enhance their performance 167, 168.

Addressing the mentioned challenges requires a combination of experimental investigations, 

computational modeling, and innovative thinking. Possible strategies that could be used to address 

these challenges are as follows: (1) Mixing DESs with ionic liquids with low viscosity or adding 

items (like salts or co-solvents) to make them less viscous or less conductive and more stable at 

high temperatures. (2) Selecting suitable HBDs and HBAs (e.g., choline chloride, urea) to achieve 

optimal ionic conductivity and viscosity and improved thermal stability by altering hydrogen bond 

interactions or introducing functional groups. (3) Using nanostructured materials (e.g., 

mesoporous TiO2) to accommodate DES phase changes. (4) Applying thin coatings (e.g., 

graphene, polymers) to improve DES adhesion and stability. (5) Modifying TiO2 electrodes with 

hydrophilic or DES-compatible functional groups to enhance wetting behavior. (5) Optimizing ion 

migration pathways within the cell to minimize DES viscosity effects. (6) Investigating DES 

recyclability and exploring methods for reusing or regenerating DES. (7) Engaging industry 

partners to bridge the gap between fundamental research and practical applications of DESs.

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The perspectives related to the use of DESs in DSSCs can be described as follows: (1) Combining 

DES with polymers to create hybrid materials. These blends could offer improved mechanical 

strength, thermal stability, and ion transport properties, or combine grapheme into DES to enhance 

electrical conductivity and provide a conductive network within the electrolyte. (2) Developing 

DES that responds to environmental cues (e.g., temperature, light) by altering its properties. This 

adaptability could enhance DSSCs performance under varying conditions. (3) Investigating DES 

for super-capacitor applications. Their unique properties may lead to high-capacity, 

environmentally friendly energy storage devices. (4) Utilizing DESs as thermoelectric materials 

for converting sun heat and CO2 into added-value products (5) Developing efficient methods to 

recycle DES after their useful life in DSSCs and promoting DES-based technologies beyond solar 

cells, such as in sustainable chemical processes or green manufacturing.

 The present review summarizes the use of various eutectic mixtures as strong electrolytes 

in DSSCs, considering the different factors affecting the performance of these solar cells. Deep 

eutectic solvents (DESs) are more viscous than volatile organic compound (VOC) electrolytes, but 

they have been shown to greatly improve cell efficiency in thin-film DES-DSSCs by raising the 

photovoltage. DESs could make a major contribution to the development of long-lasting and 

environmentally-friendly liquid DSSCs, due to their advantages in terms of performance metrics, 

providing higher voltage and lower recombination resistance. This would support a shift towards 

a more environmentally aware approach to industrial progress.

Page 45 of 89 RSC Advances



5. Conclusions

Solar devices based on deep eutectic solvents (DESs) are at the forefront of sustainable and 

environmentally friendly green technologies. These innovative systems have the potential to 

significantly enhance the availability of clean and renewable energy sources within both the 

scientific realm and the broader societal context over the coming years. However, this potential 

can only be achieved by a dedicated investment in fundamental research. A comprehensive 

understanding of the intricate role played by DESs is crucial, especially concerning their 

intermolecular interactions involving the diverse components of solar cell structures. Such 

knowledge is essential for harnessing their positive impact on charge transfer processes at the 

molecular level. The application of DESs across diverse scientific disciplines is an emerging and 

exciting area of technology, with great potential for large-scale industrial application. Contrary to 

initial assumptions, on an industrial level, the transformation of two solid substances into a liquid 

form presents certain complexities. DESs are highly adaptable mixtures, comprising a variety of 

hydrogen bond acceptors (HBAs) and hydrogen bond donors (HBDs)Consequently, for the 

transition of DESs into a tangible industrial entity, researchers have been concentrating on 

developing a variety of scalable preparation techniques.

As discussed in this review, the physicochemical properties of DESs have a major impact 

on their performance as electrolytes in dye-sensitized solar cells (DSSCs). DESs are known for 

their low volatility, strong solubilization capacity, and excellent ionic conductivity, which are 

crucial for the efficient operation of DSSCs. Their tunable nature allows the optimization of these 

properties to enhance the charge transport and stability of solar cells. In addition, the ability to 

tailor DESs by adjusting the HBA/HBD ratio provides a pathway for fine-tuning the polarity and 

viscosity of the solvent, further improving DSSC performance. In brief, the unique 

physicochemical properties of DESs offer a promising avenue for the development of high-

efficiency and stable DSSCs, making them a valuable component in the advancement of renewable 

energy technologies.

This review highlights the increasing allure of DESs as key elements in DSSCs. Recently, 

researchers have evaluated numerous DESs as electrolyte solvents for DSSCs, alongside other 

high-voltage