Your search keyword '"Kloo, Lars"' showing total 563 results

1. Closing Kok’s cycle of nature’s water oxidation catalysis

Author

Guo, Yu, He, Lanlan, Ding, Yunxuan, Kloo, Lars, Pantazis, Dimitrios A., Messinger, Johannes, and Sun, Licheng

Published

2024

2. Water-in-salt electrolytes made saltier by Gemini ionic liquids for highly efficient Li-ion batteries

Author

Tot, Aleksandar, Zhang, Leiting, Berg, Erik J., Svensson, Per H., and Kloo, Lars

Published

2023

3. Robotised screening and characterisation for accelerated discovery of novel Lithium-ion battery electrolytes: Building a platform and proof of principle studies

Author

Svensson, Per H., Yushmanov, Pavel, Tot, Aleksandar, Kloo, Lars, Berg, Erik, and Edström, Kristina

Published

2023

4. Spiro[fluorene-9,9′-xanthene]-Based Hole-Transporting Materials for Photovoltaics : Molecular Design, Structure-Property Relationship, and Applications

Author

Luo, Xin, Boschloo, Gerrit, Kloo, Lars, Sun, Licheng, Xu, Bo, Luo, Xin, Boschloo, Gerrit, Kloo, Lars, Sun, Licheng, and Xu, Bo

Abstract

Organic hole-transporting materials (HTMs) are of importance in the progress of new-generation photovoltaics, notably in perovskite solar cells (PSCs), solid-state dye-sensitized solar cells (sDSCs), and organic solar cells (OSCs). These materials play a vital role in hole collection and transportation, significantly impacting the power conversion efficiency (PCE) and overall stability of photovoltaic devices. The emergence of spiro(fluorene-9,9 '-xanthene) (SFX) as a novel building block for organic HTMs has gained considerable attention in the field of photovoltaics. Its facile one-pot synthetic approach, straightforward purification, and physiochemical properties over the prototype HTM spiro-OMeTAD have positioned SFX as a highly attractive alternative. In this Account, we present a comprehensive and in-depth summary of our research work, focusing on the advancements in SFX-based organic HTMs in photovoltaic devices with a particular emphasis on PSCs and sDSCs. Several key objectives of our research have been focused on exploring strategies to improve the properties of SFX-based HTMs. (i) One of the critical aspects we have addressed is the improvement of film quality. By carefully designing the molecular structure and employing suitable synthetic approaches, we have achieved HTMs with excellent film-forming ability, resulting in uniform and smooth films over large areas. This achievement is pivotal in ensuring the reproducibility and efficiency of photovoltaic devices. Furthermore, (ii) our investigations have led to an improvement in hole mobility within the HTMs. Through molecular engineering, such as increasing the molecular conjugation and introducing multiple SFX units, we have demonstrated enhanced charge-carrier mobility. This advancement plays a crucial role in minimizing charge recombination losses and improving the overall device efficiency. Additionally, (iii) we have explored the concept of defect passivation in SFX-based HTMs. By incorporating Lewis, QC 20240318

Published

2024

5. Advanced materials provide solutions towards a sustainable world

Author

Hultman, Lars, Kloo, Lars, Selleby, Malin, Berggren, Magnus, et al., Hultman, Lars, Kloo, Lars, Selleby, Malin, Berggren, Magnus, and et al.

Abstract

QC 20240215

Published

2024

6. Tailor-Making Low-Cost Spiro[fluorene-9,9′-xanthene]-Based 3D Oligomers for Perovskite Solar Cells

Author

Xu, Bo, Zhang, Jinbao, Hua, Yong, Liu, Peng, Wang, Linqin, Ruan, Changqing, Li, Yuanyuan, Boschloo, Gerrit, Johansson, Erik M.J., Kloo, Lars, Hagfeldt, Anders, Jen, Alex K.-Y., and Sun, Licheng

Published

2017

7. Tuning of Molecular Water Organization in Water-in-Salt Electrolytes by Addition of Chaotropic Ionic Liquids

Author

Tot, Aleksandar, Zhang, Leiting, Svensson, Per H., Kloo, Lars, Tot, Aleksandar, Zhang, Leiting, Svensson, Per H., and Kloo, Lars

Abstract

Water-in-salt electrolytes (WISEs) have expanded the useful electrochemical stability of water, making the development of functional aqueous lithium-ion batteries more accessible. The implementation of additives in the formulation of WISEs can further improve the electrochemical stability of water and avoid potential lithium-ion salt solubility issues. Here, we have used Gemini-type ionic liquids to suppress water activity by designing the structure of ionic-liquid cations. The different water-organizing effects of ionic-liquid cations have been investigated and correlated to battery performance in LTO/LMO full cells. The champion device, containing the most chaotropic ionic liquid, retained at least 99% of its Coulombic efficiency after 500 charging cycles, associated with a final specific discharge capacity of 85 mA hg(-1). These results indicated that water-rich Li+ solvation shells significantly contribute to the excellent device performance and long-term stability of the LTO/LMO-based full battery cells. This work shows that the fine-tuning of the Li+ solvation shell and water structure by the addition of chaotropic cations represents a promising strategy for generating more stable and effective lithium-ion-containing rechargeable aqueous batteries., QC 20240201

Published

2023

8. Accelerated Discovery of Perovskite-Inspired Materials through Robotized Screening Including Solar Cell Characterization

Author

Starkholm, Allan, Kloo, Lars, Svensson, Per H., Starkholm, Allan, Kloo, Lars, and Svensson, Per H.

Abstract

Currently, there is a strong need to accelerate development of systematic and robotized procedures for discovery of photovoltaic materials in order to aid the transition toward the use of clean and sustainable energy sources. Perovskite-type materials represent a broad class of compounds that have recently attracted great interest for application as photovoltaic materials. Such materials offer a vast chemical and structural space, qualifying them as an interesting starting point for further exploration using robotized screening methods. In this work, the development and application of a robotized procedure for the screening and solar cell characterization of perovskite-inspired materials is presented. Several combinations of cationic dyes and metal halides were examined by using a fully automated robotic screening cycle, including solar cell characterization based on triple mesoscopic solar cell devices. It is shown that the presented methodology is promising for the detection of new photovoltaic materials, which is demonstrated by the discovery of a selection of photovoltaic candidates. Some of the discovered candidates, for instance [QR]-[PbI3], were further characterized theoretically and experimentally., QC 20240103

Published

2023

9. Catenated compounds in group 17—polyhalides

Author

Kloo, Lars and Kloo, Lars

Abstract

The present chapter offers an overview of polyanions of the Group 17 as examples of catenation. The main knowledge obtained from the rich literature on polyiodides is summarized, and comparisons are made with other polyhalide systems in order to gain insights into similarities and differences. A strong emerging field is represented by polybromides in the liquid and solid state, as well as novel or rejuvenated areas of application. A detailed analysis of chemical bonding is given, and the special properties of halogen-halogen bonding are highlighted., Part of ISBN 9780128231531QC 20230725

Published

2023

10. Gold Polyiodide Hybrid Perovskite Solar Cells

Author

Starkholm, Allan, Kloo, Lars, Svensson, Per H., Starkholm, Allan, Kloo, Lars, and Svensson, Per H.

Abstract

In this work, we present the ionic liquid (IL) synthesis of two novel and [Et3S][AuI4][I-5] (2), and their application as active layers in monolithic solar cells. The compounds are composed of tetraiodoaurate anions and polyiodide entities, infinite polyiodide chains in 1 and pentaiodides in 2, which display short intermolecular contacts resulting in relatively small electronic bandgaps. This work represents the first demonstration of film deposition of gold iodide/polyiodide compounds onto porous monolithic substrates with subsequent solar cell characterization. The devices show promising photovoltaic performance and could unlock new materials design possibilities, ultimately moving away from lead-based photovoltaic materials. These findings further highlight the use of simple polyiodide entities to increase the structural and electronic dimensionality of gold perovskite-type anions., QC 20230309

Published

2023

11. Separation of ND(III), DY(III) and Y(III) by solvent extraction using D2EHPA and EHEHPA

Author

Mohammadi, Maryam, Forsberg, Kerstin, Kloo, Lars, Martinez De La Cruz, Joaquin, and Rasmuson, Åke

Published

2015

12. Electrochemical impedance and X-ray absorption spectroscopy analyses of degradation in dye-sensitized solar cells containing cobalt tris(bipyridine) redox shuttles

Author

Gao, Jiajia, Tot, Aleksandar, Tian, Haining, Gardner, James M., Phuyal, Dibya, Kloo, Lars, Gao, Jiajia, Tot, Aleksandar, Tian, Haining, Gardner, James M., Phuyal, Dibya, and Kloo, Lars

Abstract

Electrochemical impedance spectroscopy (EIS) is a commonly used steady-state technique to examine the internal resistance of electron-transfer processes in solar cell devices, and the results are directly related to the photovoltaic performance. In this study, EIS was performed to study the effects of accelerated ageing, aiming for insights into the degradation mechanisms of dye-sensitized solar cells (DSSCs) containing cobalt tris(bipyridine) complexes as redox mediators. Control experiments based on aged electrolytes differing in concentrations of the redox couple components and cation co-additives were conducted to reveal the correlation of the cell degradation with external and internal properties. The failure modes of the cells emerged as changes in the kinetics of charge- and ion-transfer processes. An insufficient concentration of the redox complexes, in particular Co(iii), was found to be the main reason for the inferior performance after ageing. The related characterization of electrolytes aged outside the solar cell devices confirms the loss of active Co(iii) complexes in the device electrolytes. A new EIS feature at low frequencies emerged during ageing and was analysed. The new EIS feature demonstrates the presence of an unexpected rate-limiting, charge-transfer process in aged devices, which can be attributed to the TiO2/electrolyte interface. High-resolution fluorescence detected X-ray absorption spectroscopy (HERFD-XAS) was performed to identify the reduction of a part of Co(iii) to Co(II) after ageing, by investigating the Co K absorption edge. The HERFD-XAS data suggested a partial reduction of Co(iii) to Co(ii), accompanied by a difference in symmetry of the reduced species.

Published

2022

13. Effect of the Ancillary Ligand on the Performance of Heteroleptic Cu(I) Diimine Complexes as Dyes in Dye-Sensitized Solar Cells

Author

Franchi, Daniele, Leandri, Valentina, Pizzichetti, Angela Raffaella Pia, Xu, Bo, Hao, Yan, Zhang, Wei, Sloboda, Tamara, Svanström, Sebastian, Cappel, Ute B., Kloo, Lars, Sun, Licheng, Gardner, James M., Franchi, Daniele, Leandri, Valentina, Pizzichetti, Angela Raffaella Pia, Xu, Bo, Hao, Yan, Zhang, Wei, Sloboda, Tamara, Svanström, Sebastian, Cappel, Ute B., Kloo, Lars, Sun, Licheng, and Gardner, James M.

Abstract

A series of heteroleptic Cu(I) diimine complexes with different ancillary ligands and 6,6'-dimethyl-2,2'-bipyridine-4,4'-dibenzoic acid (dbda) as the anchoring ligand were selfassembled on TiO2 surfaces and used as dyes for dye-sensitized solar cells (DSSCs). The binding to the TiO2 surface was studied by hard X-ray photoelectron spectroscopy for a brominecontaining complex, confirming the complex formation. The performance of all complexes was assessed and rationalized on the basis of their respective ancillary ligand. The DSSC photocurrent-voltage characteristics, incident photon-to-current conversion efficiency (IPCE) spectra, and calculated lowest unoccupied molecular orbital (LUMO) distributions collectively show a push-pull structural dye design, in which the ancillary ligand exhibits an electron-donating effect that can lead to improved solar cell performance. By analyzing the optical properties of the dyes and their solar cell performance, we can conclude that the presence of ancillary ligands with bulky substituents protects the Cu(I) metal center from solvent coordination constituting a critical factor in the design of efficient Cu(I)-based dyes. Moreover, we have identified some components in the I-/I-3(-)-based electrolyte that causes dissociation of the ancillary ligand, i.e., TiO2 photoelectrode bleaching. Finally, the detailed studies on one of the dyes revealed an electrolyte-dye interaction, leading to a dramatic change of the dye properties when adsorbed on the TiO2 surface.

Published

2022

14. Reversible Structural Isomerization of Nature's Water Oxidation Catalyst Prior to O-O Bond Formation

Author

Guo, Yu, Messinger, Johannes, Kloo, Lars, Sun, Licheng, Guo, Yu, Messinger, Johannes, Kloo, Lars, and Sun, Licheng

Abstract

Photosynthetic water oxidation is catalyzed by a manganese-calcium oxide cluster, which experiences five "S-states"during a light-driven reaction cycle. The unique "distorted chair"-like geometry of the Mn4CaO5(6) cluster shows structural flexibility that has been frequently proposed to involve "open"and "closed"-cubane forms from the S1 to S3 states. The isomers are interconvertible in the S1 and S2 states, while in the S3 state, the open-cubane structure is observed to dominate inThermosynechococcus elongatus (cyanobacteria) samples. In this work, using density functional theory calculations, we go beyond the S3+Yz state to the S3nYz→S4+Yz step, and report for the first time that the reversible isomerism, which is suppressed in the S3+Yz state, is fully recovered in the ensuing S3nstate due to the proton release from a manganese-bound water ligand. The altered coordination strength of the manganese-ligand facilitates formation of the closed-cubane form, in a dynamic equilibrium with the open-cubane form. This tautomerism immediately preceding dioxygen formation may constitute the rate limiting step for O2 formation, and exert a significant influence on the water oxidation mechanism in photosystem II.

Published

2022

15. An Ab Initio Molecular Dynamics Study of the Mechanism and Rate of Dye Regeneration by Iodide Ions in Dye-Sensitized Solar Cells

Author

He, Lanlan, Guo, Yu, Kloo, Lars, He, Lanlan, Guo, Yu, and Kloo, Lars

Abstract

In the ambition to improve the power conversion efficiency (PCE) of dye-sensitized solar cells (DSSCs), it will be essential to understand the mechanisms and rates of dye regeneration. Although the mechanism of dye regeneration has been studied by static density functional theory (DFT) and classical molecular dynamics (CMD) simulations, ab initio molecular dynamics simulation (aiMD) has the potential to combine the insights from both methods for a deeper understanding. In this work, a series of aiMD simulations has been performed to study the interaction between an oxidized organic model dye, LEG4, and an electrolyte containing iodide ions as reducing agents. Dynamic Mulliken and natural spin population analyses show that two iodide ions, I-center dot center dot center dot I-, are required for dye regeneration. It was found that a distance between I-center dot center dot center dot I(-)of less than 6.5 angstrom at site 1 benefits from the electrostatic environment of the triphenylamine group of the LEG4 dye, and a corresponding distance of 4.8 angstrom at site 2 is essential for the dye regeneration process to take place. The rate constants of the LEG4 regeneration by two iodine ions range from 10(5) to 10(12) s(-1), spanning a window in which results from both experimental and static theoretical calculations fall. It is also verified that the probability of electron transfer from a radical I-2(-) to the oxidized LEG4 dye is extremely low due to the rapid electron back transfer. However, it has been found that the addition of an additional iodide ion at a distance of 5 angstrom with respect to the radical I-2(-) opens the pathway for the reduction of the oxidized LEG4 dye with an associated formation of I-3(-). The current results highlight the necessity for a dynamical approach for a full understanding of the regeneration process., QC 20220315

Published

2022

16. Electron-hopping across dye-sensitized mesoporous NiO surfaces

Author

Wrede, Sina, He, Lanlan, Boschloo, Gerrit, Hammarström, Leif, Kloo, Lars, Tian, Haining, Wrede, Sina, He, Lanlan, Boschloo, Gerrit, Hammarström, Leif, Kloo, Lars, and Tian, Haining

Abstract

To gain a deeper understanding of the underlying charge processes in dye sensitized photocathodes, lateral electron hopping across dye-sensitized NiO photocathodes was investigated. For dye-sensitized systems, hole hopping across photoanodes has been studied extensively in the literature but no expansive studies on electron hopping in sensitized photocathodes exist today. Therefore, an organic p-type dye (TIP) with donor–linker–acceptor design, showing high stability and electrochemical reversibility, was used to study the electron transfer dynamics (electron-hopping) between dyes with temperature dependent spectroelectrochemistry and computational simulations. Besides intermolecular electron-hopping across the surface with a rate constant in the order of 105 s−1, our results show a second electron hopping pathway between NiO surface states with a rate constant in the order of 107 s−1, which precedes the electron hopping between the dyes. Upon application of a potential step negative enough to reduce both the dye and NiO surface states, the majority of NiO surface states need to be reduced before intermolecular electron transfer can take place. The results indicate that, in contrast to sensitized photoanodes where intermolecular charge transfer is known to influence recombination kinetics, intermolecular charge transport processes in TIP dye sensitized NiO photocathodes is less relevant because the fast electron transport between NiO surface states likely dominates recombination kinetics.

Published

2022

17. Electrostatic interactions and physisorption: mechanisms of passive cesium adsorption on Prussian blue

Author

Nordstrand, Johan, Kloo, Lars, Nordstrand, Johan, and Kloo, Lars

Abstract

The dangers posed by nuclear accidents necessitate developments in techniques for cesium removal. One such is the adsorption of cesium cations in Prussian blue (PB) materials, on which adsorption can be a substation process or pure physisorption. The underlying mechanism of the latter is not well understood, although a Langmuir isotherm is frequently used to model experimental results. In this work, we exploit tight-binding density-functional theory (DFTB) methods to probe the atomic interactions in the physisorption process. The results show that there is a diminishing return for the energy of adsorption as more sites are filled. This means that the adsorption sites are not independent, as stipulated by the ideal Langmuir isotherm. Instead, the results indicate that electrostatic effects need to be considered to explain the theoretical and experimental results. Therefore, an electrostatic Langmuir (EL) model is introduced, which contains an electrostatic ideality correction to the classic Langmuir isotherm. For future materials development, these physical insights indicate that shielding effects as well as the number of independent physical sites must be considered when synthesizing effective Prussian blue analogs (PBA). In conclusion, the study provides insights into the limiting mechanisms in the physisorption of cesium cations on PB., QC 20221201

Published

2022

18. Sodium to cesium ions: a general ladder mechanism of ion diffusion in prussian blue analogs

Author

Nordstrand, Johan, Toledo-Carrillo, Esteban Alejandro, Kloo, Lars, Dutta, Joydeep, Nordstrand, Johan, Toledo-Carrillo, Esteban Alejandro, Kloo, Lars, and Dutta, Joydeep

Abstract

Prussian blue analogs (PBAs) form crystals with large lattice voids that are suitable for the capture, transport and storage of various interstitial ions. Recently, we introduced the concept of a ladder mechanism to describe how sodium ions inside a PBA crystal structure diffuse by climbing the frames formed by aligned cyanide groups in the host structure. The current work uses semi-empirical tight-binding density functional theory (DFTB) in a multiscale approach to investigate how differences in the size of the monovalent cation affect the qualitative and quantitative aspects of the diffusion process. The results show that the ladder mechanism represents a unified framework, from which both similarities and differences between cation types can be understood. Fundamental Coulombic interactions make all positive cations avoid the open vacant areas in the structure, while cavities surrounded by partially negatively charged cyanide groups form diffusion bottlenecks and traps for larger cations. These results provide a new and quantitative way of understanding the suppression of cesium adsorption that has previously been reported for PBAs characterized by a low vacancy density. In conclusion, this work provides a unified picture of the cation adsorption in PBAs based on the newly formulated ladder mechanism., QC 20221125

Published

2022

19. Ladder Mechanisms of Ion Transport in Prussian Blue Analogues

Author

Nordstrand, Johan, Toledo-Carrillo, Esteban Alejandro, Vafakhah, Sareh, Guo, Lu, Yang, Hui Ying, Kloo, Lars, Dutta, Joydeep, Nordstrand, Johan, Toledo-Carrillo, Esteban Alejandro, Vafakhah, Sareh, Guo, Lu, Yang, Hui Ying, Kloo, Lars, and Dutta, Joydeep

Abstract

Prussian blue (PB) and its analogues (PBAs) are drawing attention as promising materials for sodium-ion batteries and other applications, such as desalination of water. Because of the possibilities to explore many analogous materials with engineered, defect-rich environments, computational optimization of ion-transport mechanisms that are key to the device performance could facilitate real-world applications. In this work, we have applied a multiscale approach involving quantum chemistry, self-consistent mean-field theory, and finite-element modeling to investigate ion transport in PBAs. We identify a cyanide-mediated ladder mechanism as the primary process of ion transport. Defects are found to be impermissible to diffusion, and a random distribution model accurately predicts the impact of defect concentrations. Notably, the inclusion of intermediary local minima in the models is key for predicting a realistic diffusion constant. Furthermore, the intermediary landscape is found to be an essential difference between both the intercalating species and the type of cation doping in PBAs. We also show that the ladder mechanism, when employed in multiscale computations, properly predicts the macroscopic charging performance based on atomistic results. In conclusion, the findings in this work may suggest the guiding principles for the design of new and effective PBAs for different applications., QC 20220506

Published

2022

20. On closed-shell interactions between heavy main-group elements

Author

Kloo, Lars and Kloo, Lars

Abstract

A series of di- and polymetal complexes involving closed-shell, heavy main-group atoms and ions shows a selection of special physical properties. These involve short metal-metal contacts, low entropies of formation and, most interestingly, strong Raman bands at low wavenumbers. These results together with the constitution of the coordination compounds, where the majority of electrons are assembled on the highly polarizable metal atoms and ions, experimental results have been interpreted in terms of direct, partial covalent metal-metal bonding. Previous theoretical studies have challenged this view and instead attributed the obvious attractive forces involved to secondary-type of interactions, such as dispersion. This study utilizes a multitude of theoretical tools, such as natural bond order (NBO) and natural energy decomposition analysis (NEDA), non-covalent interaction (NCI) analysis, electron localization functions (ELFs), and atoms-in-molecules (AIM) to characterize the interactions in models comprising closed-shell dimers, as well as experimentally studied ring and cage systems constituting the main reason for the hypotheses on metal-metal interactions. The results show that all experimental results can be attributed to the covalent interactions between the electron-rich, metal centers and the bridging anions in ring and cage coordination compounds of high symmetry, where the experimentally observed effects can be traced to the combination of covalent interactions between the metal centers and the anions along the edges of the ring and cage systems in combination with the cooperative effects generated by the high symmetry of these ring and cage systems., QC 20221025

Published

2022

21. 1.20 - Mesoporous Dye-Sensitized Solar Cells

Author

Hagfeldt, A., Cappel, U. B., Boschloo, G., Sun, Licheng, Kloo, Lars, Pettersson, H., Gibson, E. A., Hagfeldt, A., Cappel, U. B., Boschloo, G., Sun, Licheng, Kloo, Lars, Pettersson, H., and Gibson, E. A.

Abstract

Photovoltaics, or solar cells, are fast growing both with regards to industrialization and research. Globally, the total PV installation is around 40 GW and an annual growth rate of 45% has been experienced over recent years. In the comparison between different photovoltaic technologies a figure of merit is the production cost per peak watt of solar electricity produced. For so called second generation thin film solar cells production costs down to and even below 1 $ W−1 peak are reported. To be competitive with conventional energy sources for large-scale electricity production new PV technologies need to aim at production costs below 0.5 $ W−1 peak. The dye-sensitized solar cell (DSC) is a molecular solar cell technology which have the potential to achieve production costs below 0.5 $ W−1 peak. DSC is based on molecular and nanometer-scale components. Record cell efficiencies of 12%, promising stability data and means of energy efficient production methods have been accomplished. As selling points for the DSC technology the prospect of low-cost investments and fabrication are key features. DSCs offer the possibilities to design solar cells with a large flexibility in shape, color, and transparency. This chapter describes the basic principles of the operation of DSC, the state-of-the-art, the materials development that is currently taking place as well as the potentials for future development., Part of ISBN 9780128197349 9780128197271QC 20230724

Published

2022

22. On the non-existence of a square-planar pentaiodide coordination complex I(i)4−

Author

Kloo, Lars and Kloo, Lars

Abstract

The properties of two conformers of the pentaiodide ion, a V-shaped and regularly observed I5− ion, and a so far undetected square-planar coordination complex of II4− composition, have been investigated by computational methods. The latter compound is indicated by the analogy to the coordination chemistry of gold with halide ligands, as well as isoelectronic main-group compounds. Static and dynamic simulations at density-functional and semi-empirical level including effects of solvent and counter ions indicate that the square-planar II4− indeed represents a well-defined local minimum on the pentaiodide potential energy surface, albeit less stable than the typically observed V-shaped I5−. No simple pathway of transformation between the two forms of the pentaiodide ion can be identified. Molecular dynamics simulations indicate that the presence of cations, unavoidable during the synthesis of polyiodide compounds, may trigger decomposition of the II4− coordination complex into smaller polyiodide building blocks and thus constitute the main reason why this conformer so far has not been identified in solid polyiodide compounds. However, its intrinsic stability indicates that the square-planar form should be possible to isolate in solid compounds given the right conditions of synthesis., QC 20230601

Published

2022

23. Water-in-salt electrolytes - molecular insights to the high solubility of lithium-ion salts

Author

Tot, Aleksandar, Kloo, Lars, Tot, Aleksandar, and Kloo, Lars

Abstract

The recently established water-in-salt electrolyte (WISE) concept indicates the possible application of aqueous electrolytes in lithium-ion batteries (LiBs). The application of this type of highly concentrated electrolyte relies on a proper understanding of their thermodynamically stable solutions. Therefore, fundamental insights regarding the Li[TFSI] solubility in water are important for the rational design of reproducible and stable WISE., QC 20230522

Published

2022

24. Synthesis and characterization of binuclear palladium(I) compounds and the influence of competing arenes

Author

Åkerstedt, Josefin, Gorlov, Mikhail, Fischer, Andreas, and Kloo, Lars

Published

2010

25. Inkjet-Printed Electron Transport Layers for Perovskite Solar Cells

Author

Lu, Dongli, primary, Zhang, Wei, additional, Kloo, Lars, additional, and Belova, Liubov, additional

Published

2021

26. A crosslinked polymer as dopant-free hole-transport material for efficient n-i-p type perovskite solar cells

Author

Wang, Linqin, Zhang, Fuguo, Liu, Tianqi, Zhang, Wei, Li, Yuanyuan, Cai, Bin, He, Lanlan, Guo, Yu, Yang, Xichuan, Xu, Bo, Gardner, James M., Kloo, Lars, Sun, Licheng, Wang, Linqin, Zhang, Fuguo, Liu, Tianqi, Zhang, Wei, Li, Yuanyuan, Cai, Bin, He, Lanlan, Guo, Yu, Yang, Xichuan, Xu, Bo, Gardner, James M., Kloo, Lars, and Sun, Licheng

Abstract

A new crosslinked polymer, called P65, with appropriate photo-electrochemical, opto-electronic, and thermal properties, has been designed and synthesized as an efficient, dopant-free, hole-transport material (HTM) for n-i-p type planar perovskite solar cells (PSCs). P65 is obtained from a low-cost and easily synthesized spiro[fluorene-9,9′-xanthene]-3′,6′-diol (SFX-OH)-based monomer X65 through a free-radical polymerization reaction. The combination of a three-dimensional (3D) SFX core unit, hole-transport methoxydiphenylamine group, and crosslinked polyvinyl network provides P65 with good solubility and excellent film-forming properties. By employing P65 as a dopant-free hole-transport layer in conventional n-i-p type PSCs, a power conversion efficiency (PCE) of up to 17.7% is achieved. To the best of our knowledge, this is the first time a 3D, crosslinked, polymeric dopant-free HTM has been reported for use in conventional n-i-p type PSCs. This study provides a new strategy for the future development of a 3D crosslinked polymeric dopant-free HTM with a simple synthetic route and low-cost for commercial, large-scale applications in future PSCs., QC 20201028

Published

2021

27. Necessity of structural rearrangements for O[sbnd]O bond formation between O5 and W2 in photosystem II

Author

Guo, Yu, Zhang, Biaobiao, Kloo, Lars, Sun, Licheng, Guo, Yu, Zhang, Biaobiao, Kloo, Lars, and Sun, Licheng

Abstract

Numerous aspects of the water oxidation mechanism in photosystem II have not been fully elucidated, especially the O[sbnd]O bond formation pathway. However, a body of experimental evidences have identified the O5 and W2 ligands of the oxygen-evolving complex as the highly probable substrate candidates. In this work, we studied O[sbnd]O bond formation between O5 and W2 based on the native Mn4Ca cluster by density functional calculations. Structural rearrangements before the formation of the S4 state were found as a prerequisite for O[sbnd]O bond formation between O5 and W2, regardless if the suggested pathways involving the typical Mn1(IV)-O[rad] species or the recently proposed Mn4(VII)(O)2 species. Possible alternatives for the S2 → S3 and S3 → S4 transitions accounting for such required rearrangements are discussed. These findings reflect that the structural flexibility of the Mn4Ca cluster is essential to allow structural rearrangements during the catalytic cycle., QC 20210603

Published

2021

28. Inkjet-Printed Electron Transport Layers for Perovskite Solar Cells

Author

Lu, Dongli, Zhang, Wei, Kloo, Lars, Belova, Lyubov, Lu, Dongli, Zhang, Wei, Kloo, Lars, and Belova, Lyubov

Abstract

Inkjet printing emerged as an alternative deposition method to spin coating in the field of perovskite solar cells (PSCs) with the potential of scalable, low-cost, and no-waste manufacturing. In this study, the materials TiO2, SrTiO3, and SnO2 were inkjet-printed as electron transport layers (ETLs), and the PSC performance based on these ETLs was optimized by adjusting the ink preparation methods and printing processes. For the mesoporous ETLs inkjet-printed from TiO2 and SrTiO3 nanoparticle inks, the selection of solvents for dispersing nanoparticles was found to be important and a cosolvent system is beneficial for the film formation. Meanwhile, to overcome the low current density and severe hysteresis in SrTiO3-based devices, mixed mesoporous SrTiO3/TiO2 ETLs were also investigated. In addition, inkjet-printed SnO2 thin films were fabricated by using a cosolvent system and the effect of the SnO2 ink concentrations on the device performance was investigated. In comparison with PSCs based on TiO2 and SrTiO3 ETLs, the SnO2-based devices offer an optimal power conversion efficiency (PCE) of 17.37% in combination with a low hysteresis. This work expands the range of suitable ETL materials for inkjet-printed PSCs and promotes the commercial applications of inkjet printing techniques in PSC manufacturing., QC 20220124

Published

2021

29. Ionic Liquid Synthesis of (Et3S)[Ag4I5] – A Structure Containing Basket-Like Silver-Iodide Cages with Ag22+ Pairs

Author

Svensson, Per H., Kloo, Lars, Svensson, Per H., and Kloo, Lars

Abstract

The compound (Et3S)[Ag4I5], 1, is readily synthesized from room-temperature, ionic-liquid media and displays a complex network structure of Ag6I6 cages with Ag22+ pairs forming 1D-chains linked into layers distinctly separate from the disordered sulphonium cations. The compound should be regarded as a large-bandgap semiconductor, but its significant structural voids qualify the compound a candidate for optoelectronic applications through the inclusion of suitable guest molecules., QC 20211108

Published

2021

30. The dynamics of light-induced interfacial charge transfer of different dyes in dye-sensitized solar cells studied byab initiomolecular dynamics

Author

He, Lanlan, Guo, Yu, Kloo, Lars, He, Lanlan, Guo, Yu, and Kloo, Lars

Abstract

The charge-transport dynamics at the dye-TiO2interface plays a vital role for the resulting power conversion efficiency (PCE) of dye sensitized solar cells (DSSCs). In this work, we have investigated the charge-exchange dynamics for a series of organic dyes, of different complexity, and a small model of the semiconductor substrate TiO2. The dyes studied involve L1, D35 and LEG4, all well-known organic dyes commonly used in DSSCs. The computational studies have been based onab initiomolecular dynamics (aiMD) simulations, from which structural snapshots have been collected. Estimates of the charge-transfer rate constants of the central exchange processes in the systems have been computed. All dyes show similar properties, and differences are mainly of quantitative character. The processes studied were the electron injection from the photoexcited dye, the hole transfer from TiO2to the dye and the recombination loss from TiO2to the dye. It is notable that the electronic coupling/transfer rates differ significantly between the snapshot configurations harvested from the aiMD simulations. The differences are significant and indicate that a single geometrically optimized conformation normally obtained from static quantum-chemistry calculations may provide arbitrary results. Both protonated and deprotonated dye systems were studied. The differences mainly appear in the rate constant of recombination loss between the protonated and the deprotonated dyes, where recombination losses take place at significantly higher rates. The inclusion of lithium ions close to the deprotonated dye carboxylate anchoring group mitigates recombination in a similar way as when protons are retained at the carboxylate group. This may give insight into the performance-enchancing effects of added salts of polarizing cations to the DSSC electrolyte. In addition, solvent effects can retard charge recombination by about two orders of magnitude, which demonstrates that the presence of a solvent will incr, QC 20220826

Published

2021

31. Influence of TiO2surface defects on the adsorption of N719 dye molecules

Author

Shamsaldeen, A. A., Kloo, Lars, Yin, Y., Gibson, C., Adhikari, S. G., Andersson, G. G., Shamsaldeen, A. A., Kloo, Lars, Yin, Y., Gibson, C., Adhikari, S. G., and Andersson, G. G.

Abstract

Surface defects influence the dye adsorption on TiO2 used as a substrate in dye-sensitized solar cells (DSSCs). In this study, we have used different Ar+ sputtering doses to create a controlled density of defects on a TiO2 surface exposed to different pre-heating temperatures in order to analyse the influence of defects on the N719 dye adsorption. TiO2 was pre-treated using two different treatments. The first treatment involved heating to 200 °C with subsequent sputtering at different doses. The second treatment included heating only, but at four different temperatures starting at 200 °C. After the pre-treatments, the TiO2 samples were immersed into an N719 dye solution for 24 hours at room temperature to dye the TiO2 substrates. The amount of Ti3+ surface defects introduced by the different pre-treatments and their influence on dye adsorption onto the TiO2 surface were examined by X-ray photoelectron spectroscopy (XPS), ultraviolet photoelectron spectroscopy (UPS) and metastable induced electron spectroscopy (MIES). Neutral impact collision ion scattering spectroscopy (NICISS) was used to determine the coverage of the TiO2 surface by adsorbed dye molecules. It was found that Ti3+ surface defects were formed by Ar+ sputtering but not by pre-treatment through heating alone. MIES analysis of the outer-most layer and density of states calculations show that the thiocyanate ligand of the N719 dye becomes directed away from the TiO2 surface. Both XPS and NICISS results indicate that the amount of adsorbed N719 dye decreases with increasing density of Ti3+ surface defects. Thus, the generation of surface defects reduces the ability of the TiO2 surface to adsorb the dye molecules. Heating alone as pre-treatment of the TiO2 substrates instead increases the dye adsorption, without causing detectable defects on the TiO2 surface., QC 20220523

Published

2021

32. Formation of carbonated apatite particles from a supersaturated inorganic blood serum model

Author

Sandin, Karin, Kloo, Lars, Nevsten, Pernilla, Wallenberg, Reine L., and Olsson, Lars-Fride

Published

2009

33. Implicit Tandem Organic-Inorganic Hybrid Perovskite Solar Cells Based on Internal Dye Sensitization : Robotized Screening, Synthesis, Device Implementation, and Theoretical Insights

Author

Starkholm, Allan, Kloo, Lars, Svensson, Per H., Starkholm, Allan, Kloo, Lars, and Svensson, Per H.

Abstract

Low-dimensional hybrid perovskite materials offer significantly improved stability as well as an extensive compositional space to explore. However, they suffer from poor photovoltaic performance as compared to the 3D perovskite materials because of poor charge-transport properties. Herein, we present the concept of internal dye-sensitized hybrid perovskite compounds involving five novel low-dimensional perovskite-type materials 1-5 incorporating triarylmethane, phenazinium and near-infrared (NIR) cyanine cationic dyes, respectively. The synthesis characterization and theoretical analysis of these compounds are presented. Theoretical calculations provide interesting insights into the effects of these dyes on the band structure of the low-dimensional anionic metal-halides and especially highlight compound 1 as a promising photovoltaic candidate. Solar cell investigation of devices based on 1 were conducted. The results show an average power conversion efficiency (PCE) of about 0.1%, which is among the highest reported for a 1D material despite the use of undoped Spiro-OMeTAD as the hole-transport material (HTM). Incident photon-to-electron efficiency (IPCE) spectra confirm the contribution of the dye to the overall photocurrent of the solar cell. Moreover, examination of solar cell devices based on the bismuth-based compound 5 resulted in PCEs in the range of 0.1%. This illustrates the potential of this concept to be exploited for lead-free photovoltaics. Finally automated robotized screening of low-dimensional hybrid perovskite materials through the screening robot PROTEUS has emerged as a powerful tool in the search for novel perovskite-like materials. Our work highlights that the use of cationic dyes could induce interesting sensitizing properties to low-dimensional metal-halide chains and may therefore provide inspiration and new design strategies for the synthesis of new lead-free photovoltaic materials, QC 20201215

Published

2020

34. Exploring Lewis-Base Effects to Improve the Efficiency of [Co(bpy)(3)](2+/3+)-Mediated Dye-Sensitized Solar Cells

Author

Gao, Jiajia, Prajapati, Govind Kumar, Hao, Yan, Kloo, Lars, Gao, Jiajia, Prajapati, Govind Kumar, Hao, Yan, and Kloo, Lars

Abstract

The state-of-the-art cobalt(II/III) tris(bipyridyl) redox shuttles open a chapter for pursuing highly efficient dye-sensitized solar cells (DSSCs). Previous work has demonstrated that light exposure of the Co(III) along with the Lewis base additive, tert-butylpyridine (TBP), effectively improves the solar cell efficiency. With this as a platform, a new Lewis base, i.e., tert-butylpyridine N-oxide (TBP-O), is introduced as an electrolyte co-additive instead of TBP alone. The resulting D3S-sensitized solar cells exhibit an efficiency of 6.6% at full solar illumination, which further increases to 8.1% by exposing the new electrolyte mixture to the light and thus outperforms typical Li+-containing DSSCs. A mechanism with regard to the interactions between Co(III) and Lewis base additives supported by electrochemical and spectroscopic studies is suggested to explain the performance improvement. The study illustrates negative effects of TBP on the charge- and mass-transfer kinetics at the electrode/electrolyte interface and reveals that the effects are eliminated by a light-induced reaction between Co(III) and TBP-O., QC 20200729.QC 20210917.

Published

2020

35. Comparison between Benzothiadizole-Thiophene- and Benzothiadizole-Furan-Based D-A-pi-A Dyes Applied in Dye-Sensitized Solar Cells : Experimental and Theoretical Insights

Author

Sharmoukh, Walid, Cong, Jiayan, Ali, Basant A., Allam, Nageh K., Kloo, Lars, Sharmoukh, Walid, Cong, Jiayan, Ali, Basant A., Allam, Nageh K., and Kloo, Lars

Abstract

Three novel donor-acceptor-pi-acceptor-type compounds (WS5, WS6, and WS7) were synthesized and investigated in dye-sensitized solar cells (DSSCs) exploring the effect of conjugated linkers on device performance. The new dyes showed strong light-harvesting ability in the visible region with relatively high molar absorption coefficients (>21 800 M-1 cm(-1)).This can be attributed to their intrinsic charge transfer (CT) from the arylamine to the acceptor group. Density functional theory (DFT) calculations revealed a favorable lowest unoccupied molecular orbital (LUMO) energy level, allowing efficient injection into the semiconductor conduction band after excitation. Upon application in DSSC devices, the WS5 dye containing 4,7-di(furan-2-yl)benzo[c][1,2,5]thiadiazole as conjugated linker mediated the highest device power conversion efficiency (PCE) amounting to 5.5%. This is higher than that of the WS6-containing dye based on the 4,7-di(thiophen-2-yl)benzo[c][1,2,5]thiadiazole linker (3.5%) and the WS7 dye based on the 4-(thiophen-2-yl)benzo[c][1,2,5]thiadiazole linker (4.3%) under AM 1.5 G illumination. The present results show furan-based dye linker systems to have a significant potential for improving DSSC efficiencies., QC 20201008

Published

2020

36. Conformational and Compositional Tuning of Phenanthrocarbazole-Based Dopant-Free Hole-Transport Polymers Boosting the Performance of Perovskite Solar Cells

Author

Yao, Zhaoyang, Zhang, Fuguo, Guo, Yaxiao, Wu, Heng, He, Lanlan, Liu, Zhou, Cai, Bin, Guo, Yu, Brett, Calvin, Li, Yuanyuan, Venugopal Srambickal, Chinmaya, Yang, Xichuan, Chen, Gang, Widengren, Jerker, Liu, Dianyi, Gardner, James M., Kloo, Lars, Sun, Licheng, Yao, Zhaoyang, Zhang, Fuguo, Guo, Yaxiao, Wu, Heng, He, Lanlan, Liu, Zhou, Cai, Bin, Guo, Yu, Brett, Calvin, Li, Yuanyuan, Venugopal Srambickal, Chinmaya, Yang, Xichuan, Chen, Gang, Widengren, Jerker, Liu, Dianyi, Gardner, James M., Kloo, Lars, and Sun, Licheng

Abstract

Conjugated polymers are regarded as promising candidates for dopant-free hole-transport materials (HTMs) in efficient and stable perovskite solar cells (PSCs). Thus far, the vast majority of polymeric HTMs feature structurally complicated benzo[1,2-b:4,5-b']dithiophene (BDT) analogs and electron-withdrawing heterocycles, forming a strong donor-acceptor (D-A) structure. Herein, a new class of phenanthrocarbazole (PC)-based polymeric HTMs (PC1, PC2, and PC3) has been synthesized by inserting a PC unit into a polymeric thiophene or selenophene chain with the aim of enhancing the pi-pi stacking of adjacent polymer chains and also to efficiently interact with the perovskite surface through the broad and planar conjugated backbone of the PC. Suitable energy levels, excellent thermostability, and humidity resistivity together with remarkable photoelectric properties are obtained via meticulously tuning the conformation and elemental composition of the polymers. As a result, PSCs containing PC3 as dopant-free HTM show a stabilized power conversion efficiency (PCE) of 20.8% and significantly enhanced longevity, rendering one of the best types of PSCs based on dopant-free HTMs. Subsequent experimental and theoretical studies reveal that the planar conformation of the polymers contributes to an ordered and face-on stacking of the polymer chains. Furthermore, introduction of the "Lewis soft" selenium atom can passivate surface trap sites of perovskite films by Pb-Se interaction and facilitate the interfacial charge separation significantly. This work reveals the guiding principles for rational design of dopant-free polymeric HTMs and also inspires rational exploration of small molecular HTMs., QC 20201110

Published

2020

37. Efficient Naphthalene Imide-Based Interface Engineering Materials for Enhancing Perovskite Photovoltaic Performance and Stability

Author

Wang, Helin, Guo, Yu, He, Lanlan, Kloo, Lars, Song, Jun, Qu, Junle, Qian, Peng-Cheng, Wong, Wai-Yeung, Wang, Helin, Guo, Yu, He, Lanlan, Kloo, Lars, Song, Jun, Qu, Junle, Qian, Peng-Cheng, and Wong, Wai-Yeung

Abstract

The ways to overcome surface charge recombination and poor interface contact are still the central challenges for the development of inorganic-organic hybrid halide perovskite solar cells (PSCs). [6,6]-Phenyl C-61 butyric acid methyl ester (PCBM) is commonly employed in PSCs, but it has some disadvantages including high charge recombination and poor surface coverage. Therefore, the addition of an interfacial engineering layer showing efficient surface passivation, electron extraction, and excellent interface contact can solve the above problems. Furthermore, by employing interface engineering with a spike structure of the energy levels, the reduced energy losses are beneficial to elevating the open-circuit voltage (V-oc) in PSCs. Herein, the linear naphthalene imide dimer containing an indacenodithiophene unit (IDTT2NPI) has been developed as an excellent interface engineering material to strengthen the perovskite performance. The introduction of a spike interface on the top of a methylammonium lead triiodide (MAPbI(3)) film resulted in a high V-oc of 1.12 V with the optimal efficiency reaching 20.2%. The efficiency enhancement can be traced to the efficient surface passivation and enhanced interface contact. The mechanism of IDTT2NPI as the interface engineering layer was investigated by both experiments and theoretical calculations. This work provides a promising naphthalene imide-based interfacial material for high-efficiency and stable PSCs., QC 20201026

Published

2020

38. Organic Salts as p-Type Dopants for Efficient LiTFSI-Free Perovskite Solar Cells

Author

Zhang, Wei, Zhang, Fuguo, Xu, Bo, Li, Yuanyuan, Wang, Linqin, Zhang, Biaobiao, Guo, Yu, Gardner, James M., Sun, Licheng, Kloo, Lars, Zhang, Wei, Zhang, Fuguo, Xu, Bo, Li, Yuanyuan, Wang, Linqin, Zhang, Biaobiao, Guo, Yu, Gardner, James M., Sun, Licheng, and Kloo, Lars

Abstract

Despite the ubiquity and importance of organic hole-transport materials in photovoltaic devices, their intrinsic low conductivity remains a drawback. Thus, chemical doping is an indispensable solution to this drawback and is essentially always required. The most widely used p-type dopant, FK209, is a cobalt coordination complex. By reducing Co(III) to Co(II), Spiro-OMeTAD becomes partially oxidized, and the film conductivity is initially increased. In order to further increase the conductivity, the hygroscopic co-dopant LiTFSI is typically needed. However, lithium salts are normally quite hygroscopic, and thus, water absorption has been suggested as a significant reason for perovskite degradation and therefore limited device stability. In this work, we report a LiTFSI-free doping process by applying organic salts in relatively high amounts. The film conductivity and morphology have been studied at different doping amounts. The resulting solar cell devices show comparable power conversion efficiencies to those based on conventional LiTFSI-doped Spiro-OMeTAD but show considerably better long-term device stability in an ambient atmosphere., QC 20201007

Published

2020

39. Single crystal structure and opto-electronic properties of oxidized Spiro-OMeTAD

Author

Zhang, Wei, Wang, Linqin, Guo, Yu, Zhang, Biaobiao, Leandri, Valentina, Xu, Bo, Li, Zhuofeng, Gardner, James M., Sun, Licheng, Kloo, Lars, Zhang, Wei, Wang, Linqin, Guo, Yu, Zhang, Biaobiao, Leandri, Valentina, Xu, Bo, Li, Zhuofeng, Gardner, James M., Sun, Licheng, and Kloo, Lars

Abstract

Single crystals of Spiro(TFSI)2 were grown, the optical and electronic properties were characterized and compared with neutral Spiro-OMeTAD. Density-functional theory was used to get insights into binding and band structure properties. The flat valence bands indicate a rather limited orbital overlap in Spiro(TFSI)2., QC 20200204

Published

2020

40. Molten and solid trialkysulfonium iodides and their polyiodides as electrolytes in dye-sensitized nanocrystalline solar cells

Author

Paulsson, Helene, Hagfeldt, Anders, and Kloo, Lars

Subjects

Chemistry, Physical and theoretical -- Research, Electrolyte solutions, Iodides, Chemicals, plastics and rubber industries

Abstract

Potential new electrolyte for dye-sensitized nanocrystalline solar cells (DNSCs) of Gratzel type based on trialkylsulfonium iodides is studied. The room temperature molten salts of (Et2MeS)I, (Bu2MeS)I, and (Bu2EtS)I have shown good conducting abilities at ambient conditions.

Published

2003

41. Comparison between Benzothiadizole–Thiophene- and Benzothiadizole–Furan-Based D–A−π–A Dyes Applied in Dye-Sensitized Solar Cells: Experimental and Theoretical Insights

Author

Sharmoukh, Walid, primary, Cong, Jiayan, additional, Ali, Basant A., additional, Allam, Nageh K., additional, and Kloo, Lars, additional

Published

2020

42. Figures S1 - S5 from Towards implementing hierarchical porous zeolitic imidazolate frameworks in dye-sensitized solar cells

Author

Abdelhamid, Hani Nasser, El-Zohry, Ahmed M., Jiayan Cong, Thersleff, Thomas, Karlsson, Martin, Kloo, Lars, and Xiaodong Zou

Abstract

Figure S1: FT-IR spectra of a) L1@ZIF-8, b) L1Fc@ZIF-8, and c) L1Fc2@ZIF-8.; Figure S2: SEM images of a) L1@ZIF-8, b) L1Fc@ZIF-8, and c) L1Fc2@ZIF-8.; Figure S3: Camera images of ZIF-8, L1@ZIF-8, L1Fc@ZIF-8, and L1Fc2@ZIF-8.; Figure S4: NLDFT pore size distribution using N2@77 on Carbon slit pores.; Figure S5: Excitation emission spectra of dye solar cell before and after encapsulation into ZIF-8 for a) L1, b) L1Fc and c) L1Fc2.

Published

2019

43. Reaction between palladium(II) and gallium(III) halogenides in arenes: influence of halogen nature on the formation of binuclear palladium(I) clusters

Author

Gorlov, Mikhail, Fischer, Andreas, and Kloo, Lars

Published

2004

44. Exploring the Optical and Electrochemical Properties of Homoleptic versus Heteroleptic Diimine Copper(I) Complexes

Author

Leandri, Valentina, Raffaella, Angela, Pizzichetti, Pia, Xu, Bo, Franchi, Daniele, Zhang, Wei, Benesperi, Iacopo, Freitag, Marina, Sun, Licheng, Kloo, Lars, Gardner, James M., Leandri, Valentina, Raffaella, Angela, Pizzichetti, Pia, Xu, Bo, Franchi, Daniele, Zhang, Wei, Benesperi, Iacopo, Freitag, Marina, Sun, Licheng, Kloo, Lars, and Gardner, James M.

Abstract

Due to ligand scrambling, the synthesis and investigation of the properties of heteroleptic Cu(I) complexes can be a challenging task. In this work, we have studied the optical and electrochemical properties of a series of homoleptic complexes, such as [Cu(dbda)(2)](+), [Cu(dmp)(2)](+), [Cu(Br-dmp)(2)](+), [Cu(bcp)(2)](+), [Cu(dsbtmp)(2)](+), [Cu(biq)(2)](+), and [Cu(dap)(2)](+) in solution, and those of their heteroleptics [Cu(dbda)(dmp)](+), [Cu(dbda)(Br-dmp)](+), [Cu(dbda)(bcp)](+), [Cu(dbda)(dsbtmp))(+), [Cu(dbda)(biq)](+), [Cu(dbda)(dap)](+) adsorbed on the surface of anatase TiO2 (dbda = 6,6'-dimethyl-2,2'-bipyridine-4,4'-dibenzoic acid; dmp = 2,9-dimethyl-1,10-phenanthroline; Br-dmp = 5-bromo 2,9-dimethyl-1,10-phenanthroline; bcp = bathocuproine or 2,9-dimethyl-4,7-diphenyl-1,10-phenanthroline; dsbtmp = 2,9-di(sec-butyl)-3,4,7,8-tetramethyl-1,10-phenanthroline; biq = 2,2'-biquinoline; dap = 2,9-dianisyl-1,10-phenanthroline). We show that the maximum absorption wavelengths of the heteroleptic complexes on TiO2 can be reasonably predicted from those of the homoleptic complexes in solution through a simple linear relation, whereas the prediction of their redox properties is less trivial. In the latter case, two different linear patterns emerge: one including the ligands bcp, biq, and dap and another one including the ligands dmp, Br-dmp, and dsbtmp. We offer an interpretation of the data based on the chemical structure of the ligands. On one hand, ligands bcp, biq, and dap possess a more extended pi-conjugated system, which gives a more prominent contribution to the overall redox properties of the ligand dbda. On the other hand, the ligands dmp, Br-dmp, and dsbtmp are all phenanthroline-based containing alkyl substituents and contribute less than dbda to the overall redox properties.

Published

2019

45. Light-induced electrolyte improvement in cobalt tris(bipyridine)-mediated dye-sensitized solar cells

Author

Gao, Jiajia, Yang, Wenxing, El-Zohry, Ahmed M., Prajapati, Govind Kumar, Fang, Yuan, Dai, Jing, Hao, Yan, Leandri, Valentina, Svensson, Per H., Furao, Istvan, Boschloo, Gerrit, Lund, Torben, Kloo, Lars, Gao, Jiajia, Yang, Wenxing, El-Zohry, Ahmed M., Prajapati, Govind Kumar, Fang, Yuan, Dai, Jing, Hao, Yan, Leandri, Valentina, Svensson, Per H., Furao, Istvan, Boschloo, Gerrit, Lund, Torben, and Kloo, Lars

Abstract

Lithium-ion-free tris(2,2 '-bipyridine) Co(ii/iii)-mediated electrolytes have previously been proposed for long-term stable dye-sensitized solar cells (DSSCs). Such redox systems also offer an impressive DSSC performance improvement under light soaking exposure, manifested by an increase in photocurrent and fill factor without the expense of decreasing photovoltage. Kinetic studies show that charge transfer and ion diffusion at the electrode/electrolyte interface are improved due to the light exposure. Control experiments reveal that the light effect is unambiguously associated with electrolyte components, [Co(bpy)(3)](3+) and the Lewis-base additive tert-butylpyridine (TBP). Electrochemical and spectroscopic investigation of the [Co(bpy)(3)](3+)/TBP mixtures points out that the presence of TBP, which retards the electrolyte diffusion, however causes an irreversible redox reaction of [Co(bpy)(3)](3+) upon light exposure that improves the overall conductivity. This discovery not only provides a new strategy to mitigate the typical J(sc)-V-oc trade-off in Co(ii/iii)-mediated DSSCs but also highlights the importance of investigating the photochemistry of a photoelectrochemical system.

Published

2019

46. Towards implementing hierarchical porous zeolitic imidazolate frameworks in dye-sensitized solar cells

Author

Abdelhamid, Hani Nasser, El-Zohry, Ahmed M., Cong, Jiayan, Thersleff, Thomas, Karlsson, Martin, Kloo, Lars, Zou, Xiaodong, Abdelhamid, Hani Nasser, El-Zohry, Ahmed M., Cong, Jiayan, Thersleff, Thomas, Karlsson, Martin, Kloo, Lars, and Zou, Xiaodong

Abstract

A one-pot method for encapsulation of dye, which can be applied for dye-sensitized solar cells (DSSCs), and synthesis of hierarchical porous zeolitic imidazolate frameworks (ZIF-8), is reported. The size of the encapsulated dye tunes the mesoporosity and surface area of ZIF-8. The mesopore size, Langmuir surface area and pore volume are 15 nm, 960-1500 m(2). g(-1) and 0.36-0.61 cm(3). g(-1), respectively. After encapsulation into ZIF-8, the dyes show longer emission lifetimes (greater than 4-8-fold) as compared to the corresponding non-encapsulated dyes, due to suppression of aggregation, and torsional motions.

Published

2019

47. An Indacenodithieno[3,2-b]thiophene-Based Organic Dye for Solid-State p-Type Dye-Sensitized Solar Cells

Author

Xu, Bo, Wrede, Sina, Curtze, Allison, Tian, Lei, Pati, Palas Baran, Kloo, Lars, Wu, Yiying, Tian, Haining, Xu, Bo, Wrede, Sina, Curtze, Allison, Tian, Lei, Pati, Palas Baran, Kloo, Lars, Wu, Yiying, and Tian, Haining

Abstract

An indacenodithieno[3,2-b]thiophene (IDTT) unit is used as a linker moiety to design a new p-type dye-TIP-for solid-state p-type dye-sensitized solar cells. Solar cells based on the TIP dye offered an efficiency of 0.18 % with an open-circuit photovoltage of 550 mV and a short-circuit photocurrent density of 0.86 mA cm(-2), which is better than those of two reference dyes, PB6 and BH4. Charge lifetime experiments reveal that the IDTT linker-based TIP dye significantly suppresses charge recombination losses in the devices.

Published

2019

48. Impact of Linking Topology on the Properties of Carbazole-Based Hole-Transport Materials and their Application in Solid-State Mesoscopic Solar Cells

Author

Wang, Linqin, Sheibani, Esmaeil, Guo, Yu, Zhang, Wei, Li, Yuanyuan, Liu, Peng, Xu, Bo, Kloo, Lars, Sun, Licheng, Wang, Linqin, Sheibani, Esmaeil, Guo, Yu, Zhang, Wei, Li, Yuanyuan, Liu, Peng, Xu, Bo, Kloo, Lars, and Sun, Licheng

Abstract

Carbazole is a promising core for the molecular design of hole-transport materials (HTMs) for solid-state mesoscopic solar cells (ssMSCs), such as solid-state dye-sensitized solar cells (ssDSSCs) and perovskite solar cells (PSCs) due to its low cost and excellent optoelectronic properties of its derivatives. Although carbazole-based HTMs are intensely investigated in ssMSCs and promising device performance is demonstrated, the fundamental understanding of the impact of linking topology on the properties of carbazole-based HTMs is lacking. Herein, the effect of the linking topology on the optical and electronic properties of a series of carbazole-based HTMs with 2,7-substitution and 3,6-substitution is systematically investigated. The results demonstrate that the 2,7-substituted carbazole-based HTMs display higher hole mobility and conductivity among this series of analogous molecules, thereby exhibiting better device performance. In addition, the conductivity of the HTMs is improved after light treatment, which explains the commonly observed light-soaking phenomenon of ssMSCs in general. All these carbazole-based HTMs are successfully applied in ssMSCs and one of the HTMs X50-based devices yield a promising efficiency of 6.8% and 19.2% in ssDSSCs and PSCs, respectively. This study provides guidance for the molecular design of effective carbazole-based HTMs for high-performance ssMSCs and related electronic devices., QC 20190813. QC 20200502

Published

2019

49. Energy-Loss Reduction as a Strategy to Improve the Efficiency of Dye-Sensitized Solar Cells

Author

Yao, Zhaoyang, Guo, Yaxiao, Wang, Linqin, Hao, Yan, Guo, Yu, Franchi, Daniele, Zhang, Fuguo, Kloo, Lars, Sun, Licheng, Yao, Zhaoyang, Guo, Yaxiao, Wang, Linqin, Hao, Yan, Guo, Yu, Franchi, Daniele, Zhang, Fuguo, Kloo, Lars, and Sun, Licheng

Abstract

Four weak donor backbones (BT, BTP, BT2, and BT3), featuring stepwise enhanced electron-donating capacities, are designed and synthesized. The sp(3) type carbons introduced are tethered with auxiliary groups to generate a better electron-blocking stereoscopic structure. A series of NB dyes are subsequently synthesized from these central cores by end-capping a strong diphenylamine donor and a planar heterocyclic acceptor 4-(benzo[c][1,2,5]thiadiazol-4-ylethynyl)benzoic acid. The fine-tuning of steric configurations and energy levels of the resulting dye molecules reduces the energy losses significantly when applied in dye-sensitized solar cells. These devices offer one of the highest open-circuit voltages (approximate to 1.03 V) reported so far, and high power conversion efficiencies of 9.6%-12.1% using the NB dyes in combination with a well-developed cobalt-tris(4-methoxyphenyl)amine-based tandem electrolyte., QC 20191119

Published

2019

50. Polyiodide Hybrid Perovskites : A Strategy To Convert Intrinsic 2D Systems into 3D Photovoltaic Materials

Author

Starkholm, Allan, Kloo, Lars, Svensson, Per H., Starkholm, Allan, Kloo, Lars, and Svensson, Per H.

Abstract

Two new organic inorganic hybrid perovskite compounds, (Me3S)(2)Pb5I14*2I(2) (1) and (C8H11S)(2)Pb2I6*I-2 (2), have been synthesized and subsequently characterized in this study. The materials were synthesized from facile one-pot, one-step reactions of lead iodide, corresponding sulfide, methanol, iodine, and hydroiodic acid in the case of 2. Structural analysis reveals the presence of polyiodide entities in both compounds. Compound 1 contains triiodide anions, I-3(-), that are uniquely shared between the 2D inorganic slabs, forming a 3D network. Both 1 and 2 have I-2 molecules that are bridging the inorganic slabs through a structural motif that can be regarded as a tetraiodide anion, I-4(2-). Optical spectroscopy shows band gaps of 1.86 eV for 1 and 1.89 eV for 2. The optoelectronic properties were further investigated with band structure calculations. Single-crystal IV-characteristics of 1 show that the compound is photoactive confirming it as a promising photovoltaic candidate. Compound 1 highlights a novel strategy of designing 3D semiconducting hybrid materials by incorporating polyiodides to provide direct geometric and electronic connections between the semiconducting inorganic perovskite sheets., QC 20190314

Published

2019