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1. Ionic Liquid Engineering in Perovskite Photovoltaics

Author

Wang, Fei, Duan, Dawei, Singh, Mriganka, Sutter‐Fella, Carolin M, Lin, Haoran, Li, Liang, Naumov, Panče, and Hu, Hanlin

Subjects
Chemical Engineering, Engineering, Environmental Engineering, devices, ionic liquids, perovskites, photovoltaics, Chemical engineering, Environmental engineering
Abstract

Over the past decade, perovskite photovoltaics have approached other currently available technologies and proven to be the most prospective type of solar cells. Although the many-sided research in this very active field has generated consistent results with regard to their undisputed consistently increasing power conversion efficiency, it also produced several rather contradictory opinions. Among other important details, debate surrounding their proneness to surface degradation and poor mechanical robustness, as well as the environmental footprint of this materials class, remains a moot point. The application of ionic liquids appears as one of the potential remedies to some of these challenges due to their high conductivity, the opportunities for chemical “tuning” of the structure, and relatively lower environmental footprint. This article provides an overview, classification, and applications of ionic liquids in perovskite solar cells. We summarize the use and role of ionic liquids as versatile additives, solvents, and modifiers in perovskite precursor solution, in charge transport layer, and in interfacial and stability engineering. Finally, challenges and the future prospects for the design and/or selection of ionic liquids with a specific profile that meets the requirements for next-generation highly efficient and stable perovskite solar cells are proposed.

Published
2023

2. Response to 'On the giant deformation and ferroelectricity of guanidinium nitrate' by Marek Szafra\'nski and Andrzej Katrusiak

Author

Karothu, Durga Prasad, Ferreira, Rodrigo, Dushaq, Ghada, Ahmed, Ejaz, Catalano, Luca, Halabi, Jad Mahmoud, Alhaddad, Zainab, Tahir, Ibrahim, Li, Liang, Mohamed, Sharmarke, Rasras, Mahmoud, and Naumov, Panče

Subjects
Condensed Matter - Materials Science
Abstract

Following a well-established practice of publishing commentaries to articles of other authors who work on materials that were earlier studied by them (n.b. six published comments[1-6]), Marek Szafra\'nski(MS) and Andrzej Katrusiak (AK) have filed on the preprint server arXiv a manuscript entitled "On the giant deformation and ferroelectricity of guanidinium nitrate"[7] with comments on our article "Exceptionally high work density of a ferroelectric dynamic organic crystal around room temperature" published in Nature Communications (2022, 13, 2823).[8] Both in the submitted comment as well as in the required (by the journal) direct communication with us preceding its posting, MS and AK have expressed dissatisfaction with the choice of literature references in our article, for which they felt that their previous work on this material has not been cited to a sufficient extent. In their comment, they summarize their other remarks on our article as "the structural determinations of GN [guanidinium nitrate] crystals, their phase transitions and associated giant deformation, as well as its detailed structural mechanism, the molecular dynamics and dielectric properties were reported before, while the semiconductivity, ferroelectricity, and fatigue resistance of the GN [guanidinium nitrate] crystals cannot be confirmed."[7] Apart from the sentiments of MS and AK on our choice of cited literature, we find their comments on the scientific content of our article to be strongly biased towards their own results and unfounded. Below, we provide a detailed response to their comments., Comment: 13 pages, 1 figure

Published
2023

16. Logarithmic and Archimedean organic crystalline spirals.

Author

Yang, Xuesong, Lan, Linfeng, Tahir, Ibrahim, Alhaddad, Zainab, Di, Qi, Li, Liang, Tang, Baolei, Naumov, Panče, and Zhang, Hongyu

Subjects
POLYDISPERSE polymers, HYBRID materials, CRYSTAL growth, CRYSTALS, HUMIDITY
Abstract

Crystals can be found in many shapes but do not usually grow as spirals. Here we show that applying a non-uniform layer of a polymer blend onto slender centimeter-size organic crystals prestrains the crystals into hybrid dynamic elements with spiral shapes that respond reversibly to environmental variations in temperature or humidity by curling. Exposure to humidity results in partial uncurling within several seconds, whereby a logarithmic-type spiral crystal is transformed into an Archimedean one. Conical helices obtained by lateral pulling of the spirals can wind around solid objects similar to plant tendrils or lift suspended objects with a positive correlation between the actuator's elongation and the cargo mass. The morphological, kinematic, and kinetic attributes turn these hybrid materials into an attractive platform for flexible sensors and soft robots, while they also provide an approach to morph crystalline fibers in non-natural spiral habits inaccessible with the common crystallization approaches. The growth of crystals as spirals is unusual and this morphology can be applied to the development of flexible sensors and soft robots when the crystals respond to external stimuli. Here, the authors report the incorporation of a non-uniform layer of a polymer blend onto slender centimeter-size organic crystals to produce crystals having spiral shapes that respond reversibly to environmental variations. [ABSTRACT FROM AUTHOR]

Published
2024
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18. Ferroelastic ionic organic crystals that self-heal to 95%.

Author

Al-Handawi, Marieh B., Commins, Patrick, Dalaq, Ahmed S., Santos-Florez, Pedro A., Polavaram, Srujana, Didier, Pascal, Karothu, Durga Prasad, Zhu, Qiang, Daqaq, Mohammed, Li, Liang, and Naumov, Panče

Subjects
DIGITAL image correlation, IONIC crystals, AMORPHOUS substances, IONIC bonds, CRYSTALS
Abstract

The realm of self-healing materials integrates chemical and physical mechanisms that prevent wear and fracturing and extend the operational lifetime. Unlike the favorable rheology of amorphous soft materials that facilitates efficient contact between fragments, the efficiency of recovery of atomistically ordered materials is restricted by slower interfacial mass transport and the need for ideal physical alignment, which limits their real-world application. We report drastic enhancements in efficiency and recovery time in the self-healing of anilinium bromide, challenging these limitations. Crystals of this material recovered up to 49% within seconds and up to 95% after 100 min via ferroelastic detwinning. The spatial evolution of strain during cracking and healing was measured in real time using digital image correlation. Favorable alignment and strong ionic bonding across the interface of partially fractured crystals facilitate self-healing. This study elevates organic crystals close to the best-in-class self-healing polymers and sets an approach for durable crystal-based optoelectronics. Self-healing in structurally ordered materials is restricted by slow interfacial mass transport and the need for ideal physical alignment. Here the authors show self-healing in an anilinium bromide crystals achieving up to 95% recovery through ferroelastic detwinning. [ABSTRACT FROM AUTHOR]

Published
2024
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21. Trap-Driven Exciton Recombination Processes within Femtosecond Laser-Synthesized Strongly Oxidized Silicon Nanoparticles

Author

Piatkowski, Piotr A., Abbasi, Naveed Ali, Awad, Wegood M., Naumov, Panče, and Alnaser, Ali S.

Abstract

Trap states are central to silicon nanoparticle (Si NP) photoluminescence and charge transport properties, significantly influencing their potential for real-life applications. Laser ablation, typically conducted in a controlled environment, is an efficient technique for Si NPs synthesis that inherently minimizes the incorporation of impurities. This work presents results from time-integrated and time-resolved spectroscopic and microscopic studies of Si NPs synthesized by femtosecond laser ablation. The stationary spectroscopic and microscopic results indicate that the amorphous Si phase and oxidized SiOxmesoporous phase cover the crystalline Si core. The analysis of time-resolved transient absorption spectra and dynamics indicates that the exciton initially photoinduced in the crystalline Si core is transferred to the shell-related trap states within approximately 2 ps. The trapped charges are further redistributed among localized states on a time scale of a few picoseconds. Finally, the traps in various Si NPs samples are depopulated into the valence band (VB) within approximately 170–190 and 1600–2100 ps. Our results highlight the importance of understanding the role of surface composition and morphology in shaping the complex photoinduced processes in the excited states of laser-synthesized Si NPs. Improving surface performance will help to increase Si NPs size-tunable photoluminescence efficiency, paving the way for developing materials suitable for future photoemitting devices.

Published
2024
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22. Distinct Mechanical Properties and Photomechanical Response from Isostructural, yet Chemically Different Molecular Crystal Actuators

Author

Lin, Jiawei, Zhou, Jianmin, Li, Liang, Tahir, Ibrahim, Wu, Songgu, Naumov, Panče, and Gong, Junbo

Abstract

Deciphering the effect of small changes in crystal packing and intermolecular interactions on the type and magnitude of mechanical motion is central to the manipulation of the macrodynamic behavior of dynamic crystals as smart materials. Here, we describe a peculiar example where both the mechanical flexibility and the photomechanical motion in molecular crystals can be altered by a single small chemical substitution. Specifically, we demonstrate that the mechanical flexibility of an organic crystal switches from plastic bending to elastic/plastic bending by changing a single functional group of a thiophene ring from methyl (crystal 1) to ethyl (crystal 2), but they have an almost identical crystal structure. The different molecular packing also determines the rate of the [2 + 2] photocycloaddition reaction, which further reflects on the type of photomechanical effect: while upon UV radiation, crystals 1undergo bending or coiling, depending on the crystal thickness, crystals 2do not display macroscopic photomechanical response. The bending of crystals 1can be repeated up to 30 times, and this deformation can be applied to move objects that are 103–104times the mass of the crystals with an output force density of 107–108N/m3and output work density of 102–103J/m3, surpassing a variety of traditional actuators.

Published
2024
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24. A Thermosalient and Mechanically Compliant Organic Crystalline Optical Waveguide Switcher.

Author

Di, Qi, Al‐Handawi, Marieh B., Li, Liang, Naumov, Panče, and Zhang, Hongyu

Subjects
MOLECULAR crystals, REVERSIBLE phase transitions, CENTRAL processing units, MECHANICAL energy, ELECTRONIC equipment
Abstract

The dense and ordered molecular arrangements endow dynamic molecular crystals with fast response, rapid energy conversion, low energy dissipation, and strong coupling between heat/light and mechanical energy. Most of the known dynamic crystals can only respond to a single stimulus, and materials that can respond to multiple stimuli are rare. Here, we report an organic crystalline material that can be bent plastically and is also thermosalient, as its crystals can move when they undergo a reversible phase transition. The crystals transmit light regardless of their shape or crystalline phase. The combination of light transduction and reversible thermomechanical deformation provides an opportunity to switch the waveguiding capability of the material in a narrow temperature range, which holds a tremendous potential for applications in heat‐averse electronic components, such as central processing units. Unlike existing electronics, the material we report here is completely organic and therefore much lighter, potentially reducing the overall weight of electronic circuits. [ABSTRACT FROM AUTHOR]

Published
2024
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26. Strategies to Diversification of the Mechanical Properties of Organic Crystals.

Author

Dai, Shuting, Zhong, Jiangbin, Yang, Xiqiao, Chen, Chao, Zhou, Liping, Liu, Xinyu, Sun, Jingbo, Ye, Kaiqi, Zhang, Hongyu, Li, Liang, Naumov, Panče, and Lu, Ran

Subjects
CRYSTALS, SHAPE memory polymers, CHEMICAL engineering, INTERMOLECULAR interactions, MOLECULAR crystals, CHEMICAL engineers
Abstract

Structurally ordered soft materials that respond to complementary stimuli are susceptible to control over their spatial and temporal morphostructural configurations by intersectional or combined effects such as gating, feedback, shape‐memory, or programming. In the absence of general and robust design and prediction strategies for their mechanical properties, at present, combined chemical and crystal engineering approaches could provide useful guidelines to identify effectors that determine both the magnitude and time of their response. Here, we capitalize on the purported ability of soft intermolecular interactions to instigate mechanical compliance by using halogenation to elicit both mechanical and photochemical activity of organic crystals. Starting from (E)‐1,4‐diphenylbut‐2‐ene‐1,4‐dione, whose crystals are brittle and photoinert, we use double and quadruple halogenation to introduce halogen‐bonded planes that become interfaces for molecular gliding, rendering the material mechanically and photochemically plastic. Fluorination diversifies the mechanical effects further, and crystals of the tetrafluoro derivative are not only elastic but also motile, displaying the rare photosalient effect. [ABSTRACT FROM AUTHOR]

Published
2024
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30. Flexible molecular crystals for optoelectronic applications

Author

Wei, Chuanxin, primary, Li, Liang, additional, Zheng, Yingying, additional, Wang, Lizhi, additional, Ma, Jingyao, additional, Xu, Man, additional, Lin, Jinyi, additional, Xie, Linghai, additional, Naumov, Panče, additional, Ding, Xuehua, additional, Feng, Quanyou, additional, and Huang, Wei, additional

Published
2024
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33. Bending, Twisting, and Propulsion of Photoreactive Crystals by Controlled Gas Release.

Author

Yu, Chunjiao, Jiang, Xiaofan, Al‐Handawi, Marieh B., Naumov, Panče, Li, Liang, Yu, Qi, and Wang, Guoming

Subjects
CRYSTALS, CRYSTAL surfaces, GASES, ORGANIC bases, METAL complexes
Abstract

The rapid release of gas by a chemical reaction to generate momentum is one of the most fundamental ways to elicit motion that could be used to sustain and control the motility of objects. We report that hollow crystals of a three‐dimensional supramolecular metal complex that releases gas by photolysis can propel themselves or other objects and advance in space when suspended in mother solution. In needle‐like regular crystals, the reaction occurs mainly on the surface and results in the formation of cracks that evolve due to internal pressure; the expansion on the cracked surface of the crystal results in bending, twisting, or coiling of the crystal. In hollow crystals, gas accumulates inside their cavities and emanates preferentially from the recess at the crystal terminus, propelling the crystals to undergo directional photomechanical motion through the mother solution. The motility of the object which can be controlled externally to perform work delineates the concept of "crystal microbots", realized by photoreactive organic crystals capable of prolonged directional motion for actuation or delivery. Within the prospects, we envisage the development of a plethora of light‐weight, efficient, autonomously operating robots based on organic crystals with high work capacity where motion over large distances can be attained due to the large volume of latent gas generated from a small volume of the crystalline solid. [ABSTRACT FROM AUTHOR]

Published
2024
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47. Mechanical properties and peculiarities of molecular crystals

Author

Awad, Wegood M., primary, Davies, Daniel W., additional, Kitagawa, Daichi, additional, Mahmoud Halabi, Jad, additional, Al-Handawi, Marieh B., additional, Tahir, Ibrahim, additional, Tong, Fei, additional, Campillo-Alvarado, Gonzalo, additional, Shtukenberg, Alexander G., additional, Alkhidir, Tamador, additional, Hagiwara, Yuki, additional, Almehairbi, Mubarak, additional, Lan, Linfeng, additional, Hasebe, Shodai, additional, Karothu, Durga Prasad, additional, Mohamed, Sharmarke, additional, Koshima, Hideko, additional, Kobatake, Seiya, additional, Diao, Ying, additional, Chandrasekar, Rajadurai, additional, Zhang, Hongyu, additional, Sun, Changquan Calvin, additional, Bardeen, Christopher, additional, Al-Kaysi, Rabih O., additional, Kahr, Bart, additional, and Naumov, Panče, additional

Published
2023
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