Your search keyword '"Liu, Xunshan"' showing total 14 results

1. Photocatalytic Three-Component Reaction for the Synthesis of Multifunctional Diaryl Sulfides

Author

Lu, Hui-Ling, Jin, Jia-Hui, Liang, Shang-Chuang, Feng, Chuan-Wei, Li, Zhi-Ming, Zhao, Fu-Gang, Liu, Xunshan, and Shen, Yong-Miao

Abstract

A photocatalytic three-component reaction of a nitroarene, a thiophenol, and a ketone for the synthesis of multifunctional diaryl sulfides was reported using a nitro group as the nitrogen source and thiophenol as the sulfur source. Thiophenol also serves as a proton donor to reduce nitroarene to arylamine as a key intermediate for the formation of C–N and C–S bonds. Good functional group tolerance and mild reaction conditions make this method have practical synthetic value for diversified multifunctional diaryl sulfides.

Published

2023

2. Effective Approach toward Selective Near-Infrared Dyes: Rational Design, Synthesis, and Characterization of Thieno[3,4-b]thiophene-Based Quinoidal Oligomers

Author

Hei, Yuxuan, Zhang, Xinwei, He, Pengxing, Zhao, Eric Jiahan, Tang, Edison, Sharapov, Valerii, Liu, Xunshan, and Yu, Luping

Abstract

This paper describes syntheses, photophysical properties, and electrochemical characteristics of three thieno[3,4-b]thiophene (TT)-based quinoidal oligomers OnTTO. The rigid planar backbones of these oligomers give the molecules narrow absorption bands, and the main absorption bands were significantly red-shifted when the TT units were extended and demonstrated wide transparent windows. The compound O4TTOwas found to possess strong absorption in the near-infrared (NIR) region approaching 1200 nm but remained transparent in the visible region. Electrochemical experiments have shown that the energy band gaps gradually narrow when the TT units are increased. Optical properties predicted by density functional theory calculations are in good agreement with the experimental optical results. These dye molecules could be promising candidates for future NIR photodetectors, filters, and bioimaging technologies.

Published

2022

3. Energy Dissipation from Confined States in Nanoporous Molecular Networks

Author

D’Astolfo, Philipp, Wang, Xing, Liu, Xunshan, Kisiel, Marcin, Drechsel, Carl, Baratoff, Alexis, Aschauer, Ulrich, Decurtins, Silvio, Liu, Shi-Xia, Pawlak, Rémy, and Meyer, Ernst

Abstract

Crystalline nanoporous molecular networks are assembled on the Ag(111) surface, where the pores confine electrons originating from the surface state of the metal. Depending on the pore sizes and their coupling, an antibonding level is shifted upward by 0.1–0.3 eV as measured by scanning tunneling microscopy. On molecular sites, a downshifted bonding state is observed, which is occupied under equilibrium conditions. Low-temperature force spectroscopy reveals energy dissipation peaks and jumps of frequency shifts at bias voltages, which are related to the confined states. The dissipation maps show delocalization on the supramolecular assembly and a weak distance dependence of the dissipation peaks. These observations indicate that two-dimensional arrays of coupled quantum dots are formed, which are quantitatively characterized by their quantum capacitances and resonant tunneling rates. Our work provides a method for studying the capacitive and dissipative response of quantum materials with nanomechanical oscillators.

Published

2022

4. Donor–Acceptor Conjugated Copolymers Containing Transition-Metal Complex: Intrachain Magnetic Exchange Interactions and Magneto-Optical Activity

Author

Liu, Xunshan, Xie, Jiaze, Niklas, Jens, Turner, Emigdio E., Yuan, Dafei, Anderson, John S., Rack, Jeffrey J., Poluektov, Oleg G., and Yu, Luping

Abstract

A donor–acceptor conjugated copolymer containing thienothiophene (donor) units and Co(II) complexes (acceptor) has been synthesized and characterized. The studies of magnetic properties of the polymers by SQUID and EPR measurements showed antiferromagnetic exchange interaction between neighboring spin centers along with the polymer backbone through intrachain interactions. It is the first time that the D–A conjugated polymer backbone serves as bridging ligands for magnetic couplings, making these type of polymers promising as magnetic materials. Moreover, the magneto-optical activity of polymer LCP1was characterized using magnetic circular dichroism spectroscopy. It was found that the material exhibits a large magneto-optic rotation with a peak Verdet constant of 2980 deg·T–1·m–1at 590 nm.

Published

2022

5. Bottom-up Synthesis of Nitrogen-Doped Porous Graphene Nanoribbons

Author

Pawlak, Rémy, Liu, Xunshan, Ninova, Silviya, D’Astolfo, Philipp, Drechsel, Carl, Sangtarash, Sara, Häner, Robert, Decurtins, Silvio, Sadeghi, Hatef, Lambert, Colin J., Aschauer, Ulrich, Liu, Shi-Xia, and Meyer, Ernst

Abstract

Although methods for a periodic perforation and heteroatom doping of graphene sheets have been developed, patterning closely spaced holes on the nanoscale in graphene nanoribbons is still a challenging task. In this work, nitrogen-doped porous graphene nanoribbons (N-GNRs) were synthesized on Ag(111) using a silver-assisted Ullmann polymerization of brominated tetrabenzophenazine. Insights into the hierarchical reaction pathways from single molecules toward the formation of one-dimensional organometallic complexes and N-GNRs are gained by a combination of scanning tunneling microscopy (STM), atomic force microscopy (AFM) with CO-tip, scanning tunneling spectroscopy (STS), and density functional theory (DFT).

Published

2020

6. Finely Designed P3HT-Based Fully Conjugated Graft Polymer: Optical Measurements, Morphology, and the Faraday Effect

Author

Liu, Xunshan, Turner, Emigdio E., Sharapov, Valerii, Yuan, Dafei, Awais, Mohammad A., Rack, Jeffrey J., and Yu, Luping

Abstract

In this work, our group synthesized and characterized a fully conjugated graft polymer comprising of a donor–acceptor molecular backbone and regioregular poly(3-hexylthiophene) (RRP3HT) side chains. Here, our macromonomer (MM) was synthesized via Kumada catalyst transfer polycondensation reaction based on ditin-benzodithiophene (BDT) initiator. The tin content of MMwas then investigated by inductively coupled plasma-mass spectrometry (ICP-MS), which allowed for accurate control of donor/acceptor monomer ratio of 1:1 for the following Stille coupling polymerization toward our graft polymer (BP). The structures of the polymers were then characterized by gel permeation chromatography (GPC), NMR, and elemental analysis. This was followed by the characterization of optical, electrochemical, and physical properties. The magneto-optical activity of graft polymer BPwas then measured. It was found that, despite the presence of the acceptor backbone, the characteristic large Faraday rotation of RRP3HT was maintained in polymer BP, which exhibited a Verdet constant of 2.39 ± 0.57 (104) °/T·m.

Published

2020

7. Highly Emissive Semi-Ladder-Type Copolymers, Aggregation State, and Solution-Processed Organic Light-Emitting Transistor

Author

Yuan, Dafei, Awais, Mohammad A., Sharapov, Valerii, Liu, Xunshan, Neshchadin, Andriy, Chen, Wei, and Yu, Luping

Abstract

An organic light-emitting transistor (OLET) integrates the logic function of a field-effect transistor (FET) with electroluminescence of a light-emitting diode (LED) into a single device. This has the potential to play an important role in smart displays, electrically pumped organic laser, and other flexible electronic devices. For achieving high-performance solution-processed OLET, three semiladder copolymers—TPTI-CC, TPTI-C, and TPTI-F—were developed. It was found that variation in the chemical structure lead to significant differences in energy level, emission color, and intermolecular aggregation. High photoluminescence quantum yields (PLQY) was obtained in these three polymers. Solution-processed trilayered OLET devices were fabricated, which exhibited strong electroluminescence, balanced charge mobility, and external quantum efficiency (EQE) of 2.8%.

Published

2020

8. BODIPY-Containing Polymers with Ultralow Band Gaps and Ambipolar Charge Mobilities

Author

Zhang, Zhen, Yuan, Dafei, Liu, Xunshan, Kim, Mi-Jeong, Nashchadin, Andriy, Sharapov, Valerii, and Yu, Luping

Abstract

A series of BODIPY-containing donor–acceptor conjugated polymers was designed and synthesized through Pd-catalyzed cross-coupling reactions. The obtained polymers were characterized with NMR, UV–vis, and fluorescence spectroscopies, as well as cyclic voltammetry and thermal gravimetric analysis. These polymers were found to possess a strong and broad NIR absorption approaching 1600 nm, deep LUMO energy levels (<−4.0 eV), and good thermal stability. In-plane charge transport properties were studied in an organic thin-film transistor (OTFT) structure with the polymers exhibiting ambipolar charge mobilities up to 10–3cm2V–1s–1, which is one of the highest values for BODIPY-containing polymers. Due to the outstanding optoelectronic properties and good stability, our work demonstrates that BODIPY-containing polymers could be promising candidates for applications in NIR devices and bioimaging technologies.

Published

2020

9. Sequential Bending and Twisting around C–C Single Bonds by Mechanical Lifting of a Pre-Adsorbed Polymer

Author

Pawlak, Rémy, Vilhena, J. G., D’Astolfo, Philipp, Liu, Xunshan, Prampolini, Giacomo, Meier, Tobias, Glatzel, Thilo, Lemkul, Justin A., Häner, Robert, Decurtins, Silvio, Baratoff, Alexis, Pérez, Rubén, Liu, Shi-Xia, and Meyer, Ernst

Abstract

Bending and twisting around carbon–carbon single bonds are ubiquitous in natural and synthetic polymers. Force-induced changes were so far not measured at the single-monomer level, owing to limited ways to apply local forces. We quantified down to the submolecular level the mechanical response within individual poly-pyrenylene chains upon their detachment from a gold surface with an atomic force microscope at 5 K. Computer simulations based on a dedicated force field reproduce the experimental traces and reveal symmetry-broken bent and rotated conformations of the sliding physisorbed segment besides steric hindrance of the just lifted monomer. Our study also shows that the tip–molecule bond remains intact but remarkably soft and links force variations to complex but well-defined conformational changes.

Published

2020

10. Robust graphene-based molecular devices

Author

El Abbassi, Maria, Sangtarash, Sara, Liu, Xunshan, Perrin, Mickael Lucien, Braun, Oliver, Lambert, Colin, van der Zant, Herre Sjoerd Jan, Yitzchaik, Shlomo, Decurtins, Silvio, Liu, Shi-Xia, Sadeghi, Hatef, and Calame, Michel

Abstract

One of the main challenges to upscale the fabrication of molecular devices is to achieve a mechanically stable device with reproducible and controllable electronic features that operates at room temperature1,2. This is crucial because structural and electronic fluctuations can lead to significant changes in the transport characteristics at the electrode–molecule interface3,4. In this study, we report on the realization of a mechanically and electronically robust graphene-based molecular junction. Robustness was achieved by separating the requirements for mechanical and electronic stability at the molecular level. Mechanical stability was obtained by anchoring molecules directly to the substrate, rather than to graphene electrodes, using a silanization reaction. Electronic stability was achieved by adjusting the p–porbitals overlap of the conjugated head groups between neighbouring molecules. The molecular devices exhibited stable current–voltage (I–V) characteristics up to bias voltages of 2.0?V with reproducible transport features in the temperature range from 20 to 300?K.

Published

2019

11. Dipole Moment and Polarizability of Tunable Intramolecular Charge Transfer States in Heterocyclic π-Conjugated Molecular Dyads Determined by Computational and Stark Spectroscopic Study

Author

Rohwer, Egmont J., Akbarimoosavi, Maryam, Meckel, Steven E., Liu, Xunshan, Geng, Yan, Lawson Daku, Latévi Max, Hauser, Andreas, Cannizzo, Andrea, Decurtins, Silvio, Stanley, Robert J., Liu, Shi-Xia, and Feurer, Thomas

Abstract

The annulation of two redox-active molecules into a compact and planar structure paves the way toward a new class of electronically versatile materials whose physical properties can be tuned via a substitution of one of the constituting moieties. Specifically, we present tetrathiafulvalene–benzothiadiazole donor–acceptor molecules. The critical role played by the dielectric properties of these molecules is evident by the large spectral shifts of the ground-state absorption spectra in a range of solvents. Stark spectroscopy is performed to determine experimentally dipole and polarizability change over transitions in the visible range with particular attention to the transition from the highest-occupied molecular orbital (HOMO) to the lowest-unoccupied molecular orbital (LUMO). The experimental results are compared to the results of time-dependent density functional theory calculations, and we reciprocally validate results from calculation and experiment. This allows us to filter out effective models and reveal important insights. The calculations are initially performed in the gas phase and subsequently a polarizable continuum model is adopted to probe the influence of the solvent on the molecular dielectric properties. The results show a large charge displacement from the HOMO to the LUMO and confirm the intramolecular charge transfer nature of the lowest-energy transition. Substitution of the acceptor moiety with electron-withdrawing groups results in changes to the experimentally determined molecular properties consistent with the effects predicted by computational results. The dominant contribution to the electroabsorption signal is due to the change in dipole moment, which is measured to be roughly 20 D for all samples and forms a small angle with the transition dipole moment in a toluene solvent environment.

Published

2018

12. Donor–Acceptor Properties of a Single-Molecule Altered by On-Surface Complex Formation

Author

Meier, Tobias, Pawlak, Rémy, Kawai, Shigeki, Geng, Yan, Liu, Xunshan, Decurtins, Silvio, Hapala, Prokop, Baratoff, Alexis, Liu, Shi-Xia, Jelínek, Pavel, Meyer, Ernst, and Glatzel, Thilo

Abstract

Electron donor–acceptor molecules are of outstanding interest in molecular electronics and organic solar cells for their intramolecular charge transfer controlled viaelectrical or optical excitation. The preservation of their electronic character in the ground state upon adsorption on a surface is cardinal for their implementation in such single-molecule devices. Here, we investigate by atomic force microscopy and scanning tunneling microscopy a prototypical system consisting of a π-conjugated tetrathiafulvalene-fused dipyridophenazine molecule adsorbed on thin NaCl films on Cu(111). Depending on the adsorption site, the molecule is found either in a nearly undisturbed free state or in a bound state. In the latter case, the molecule adopts a specific adsorption site, leading to the formation of a chelate complex with a single Na+alkali cation pulled out from the insulating film. Although expected to be electronically decoupled, the charge distribution of the complex is drastically modified, leading to the loss of the intrinsic donor–acceptor character. The chelate complex formation is reversible with respect to lateral manipulations, enabling tunable donor–acceptor molecular switches activated by on-surface coordination.

Published

2017

13. Quantum Interference-Controlled Conductance Enhancement in Stacked Graphene-like Dimers

Author

Li, Peihui, Hou, Songjun, Alharbi, Bader, Wu, Qingqing, Chen, Yijian, Zhou, Li, Gao, Tengyang, Li, Ruihao, Yang, Lan, Chang, Xinyue, Dong, Gang, Liu, Xunshan, Decurtins, Silvio, Liu, Shi-Xia, Hong, Wenjing, Lambert, Colin J., Jia, Chuancheng, and Guo, Xuefeng

Abstract

Stacking interactions are of significant importance in the fields of chemistry, biology, and material optoelectronics because they determine the efficiency of charge transfer between molecules and their quantum states. Previous studies have proven that when two monomers are π-stacked in series to form a dimer, the electrical conductance of the dimer is significantly lower than that of the monomer. Here, we present a strong opposite case that when two anthanthrene monomers are π-stacked to form a dimer in a scanning tunneling microscopic break junction, the conductance increases by as much as 25 in comparison with a monomer, which originates from a room-temperature quantum interference. Remarkably, both theory and experiment consistently reveal that this effect can be reversed by changing the connectivity of external electrodes to the monomer core. These results demonstrate that synthetic control of connectivity to molecular cores can be combined with stacking interactions between their π systems to modify and optimize charge transfer between molecules, opening up a wide variety of potential applications ranging from organic optoelectronics and photovoltaics to nanoelectronics and single-molecule electronics.

Published

2022

14. Synergy between Photoluminescence and Charge Transport Achieved by Finely Tuning Polymeric Backbones for Efficient Light-Emitting Transistor

Author

Yuan, Dafei, Awais, Mohammad A., Sharapov, Valerii, Liu, Xunshan, Neshchadin, Andriy, Chen, Wei, and Yu, Luping

Abstract

The lack of design principle for developing high-performance polymer materials displaying strong fluorescence and high ambipolar charge mobilities limited their performance in organic light-emitting transistors (OLETs), electrically pumped organic laser, and other advanced electronic devices. A series of semiladder polymers by copolymerization of weak acceptors (TPTQ or TPTI) and weak donors (fluorene (F) or carbazole (C)) have been developed for luminescent and charge transporting properties. It was found that enhanced planarity, high crystallinity, and a delicate balance in interchain aggregation obtained in the new copolymer, TPTQ-F, contributed to high ambipolar charge mobilities and photoluminescent quantum yield. TPTQ-F showed excellent performance in solution-processed multilayered OLET devices with an external quantum efficiency (EQE) of 5.3%.

Published

2021