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1,431 results on '"Bonn, Mischa"'

1. Curved graphene nanoribbons derived from tetrahydropyrene-based polyphenylenes via one-pot K-region oxidation and Scholl cyclization

Author

Obermann, Sebastian, Zheng, Wenhao, Melidonie, Jason, Böckmann, Steffen, Osella, Silvio, León, Lenin Andrés Guerrero, Hennersdorf, Felix, Beljonne, David, Weigand, Jan J., Bonn, Mischa, Hansen, Michael Ryan, Wang, Hai I., Ma, Ji, and Feng, Xinliang

Subjects
Physics - Applied Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science
Abstract

Precise synthesis of graphene nanoribbons (GNRs) is of great interest to chemists and materials scientists because of their unique opto-electronic properties and potential applications in carbon-based nanoelectronics and spintronics. In addition to the tunable edge structure and width, introducing curvature in GNRs is a powerful structural feature for their chemi-physical property modification. Here, we report an efficient solution synthesis of the first pyrene-based GNR (PyGNR) with curved geometry via one-pot K-region oxidation and Scholl cyclization of its corresponding well-soluble tetrahydropyrene-based polyphenylene precursor. The efficient A2B2-type Suzuki polymerization and subsequent Scholl reaction furnishes up to 35 nm long curved GNRs bearing cove- and armchair-edges. The construction of model compound, as a cutout of PyGNR, from a tetrahydropyrene-based oligophenylene precursor proves the concept and efficiency of the one-pot K-region oxidation and Scholl cyclization, which is clearly revealed by single crystal X-ray diffraction analysis. The structure and optical properties of PyGNR are investigated by Raman, FT-IR, solid-state NMR and UV-Vis analysis with the support of DFT calculations. PyGNR shows the absorption maximum at 680 nm, exhibiting a narrow optical bandgap of 1.4 eV, qualifying as a low-bandgap GNR. Moreover, THz spectroscopy on PyGNR estimates its macroscopic charge mobility of 3.6 cm2/Vs, outperforming other curved GNRs reported via conventional Scholl reaction.

Published
2024

2. Anisotropic electron-phonon interactions in 2D lead-halide perovskites

Author

Geuchies, Jaco J., Klarbring, Johan, Di Virgillio, Lucia, Fu, Shuai, Qu, Sheng, Liu, Guangyu, Wang, Hai, Frost, Jarvist M., Walsh, Aron, Bonn, Mischa, and Kim, Heejae

Subjects
Condensed Matter - Materials Science
Abstract

Two-dimensional hybrid organic-inorganic metal halide perovskites offer enhanced stability for perovskite-based applications. Their crystal structure's soft and ionic nature gives rise to strong interactions between charge carriers and ionic rearrangements. Here, we investigate the interaction of photo-generated electrons and ionic polarizations in single-crystal 2D perovskite butylammonium lead iodide, varying the inorganic lammelae thickness in the 2D single crystals. We determined the directionality of the transition dipole moments of the relevant phonon modes (in the 0.3-3 THz range) by angle-and-polarization dependent THz transmission measurements. We find a clear anisotropy of the in-plane photoconductivity, with a 10% reduction along the axis parallel with the transition dipole moment of the most strongly coupled phonon. Detailed calculations, based on Feynman polaron theory, indicate that the anisotropy originates from directional electron-phonon interactions., Comment: 50 pages, 5 figures main text, 13 figures in supplementary information

Published
2024

3. MXenes with ordered triatomic-layer borate polyanion terminations

Author

Li, Dongqi, Zheng, Wenhao, Gali, Sai Manoj, Sobczak, Kamil, Horák, Michal, Polčák, Josef, Lopatik, Nikolaj, Li, Zichao, Zhang, Jiaxu, Sabaghi, Davood, Zhou, Shengqiang, Michałowski, Paweł P., Zschech, Ehrenfried, Brunner, Eike, Donten, Mikołaj, Šikola, Tomáš, Bonn, Mischa, Wang, Hai I., Beljonne, David, Yu, Minghao, and Feng, Xinliang

Published
2024
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5. Porphyrin-fused graphene nanoribbons

Author

Chen, Qiang, Lodi, Alessandro, Zhang, Heng, Gee, Alex, Wang, Hai I., Kong, Fanmiao, Clarke, Michael, Edmondson, Matthew, Hart, Jack, O’Shea, James N., Stawski, Wojciech, Baugh, Jonathan, Narita, Akimitsu, Saywell, Alex, Bonn, Mischa, Müllen, Klaus, Bogani, Lapo, and Anderson, Harry L.

Published
2024
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6. Interfaces Govern Structure of Angstrom-scale Confined Water

Author

Wang, Yongkang, Tang, Fujie, Yu, Xiaoqing, Chiang, Kuo-Yang, Yu, Chun-Chieh, Ohto, Tatsuhiko, Chen, Yunfei, Nagata, Yuki, and Bonn, Mischa

Subjects
Physics - Chemical Physics
Abstract

Water plays a crucial role in geological, biological, and technological processes. Nanoscale water confinement occurs in many of these settings, including sedimentary rocks, water channel proteins, and applications like desalination and water purification membranes. The structure and properties of water in nanoconfinement can differ significantly from bulk water, exhibiting, for instance, modified hydrogen bonds, dielectric constant, and phase transitions. Despite the importance of strongly nanoconfined water, experimentally elucidating the nanoconfinement effect on water, such as its orientation and hydrogen bond (H-bond) network, has remained challenging. Here, we study two-dimensionally nanoconfined aqueous electrolyte solutions with tunable confinement from nanoscale to angstrom-scale sandwiched between a graphene sheet and CaF2. We employ heterodyne-detection sum-frequency generation (HD-SFG) spectroscopy, a surface-specific vibrational spectroscopy capable of directly and selective probing water orientation and H-bond environment at interfaces and under confinement. Remarkably, the vibrational spectra of the nanoscale confined water can be described quantitatively by the sum of the individual water surface signals from the CaF2/water and water/graphene interfaces until the confinement reduces to angstrom-scale (< ~8 {\AA}). Ab initio molecular dynamics simulations confirm our experimental observation. These results manifest that interfacial, rather than nanoconfinement effects, dominate the water structure until angstrom-level confinement.

Published
2023

7. Direct Measurement of Mode-resolved Electron-Phonon Coupling with Two-Dimensional Spectroscopy

Author

Qu, Sheng, Sharma, Vishal K., Geuchies, Jaco, Grechko, Maksim, Bonn, Mischa, Pientka, Falko, and Kim, Heejae

Subjects
Condensed Matter - Materials Science
Abstract

Electron-phonon coupling (EPC) is foundational in condensed matter physics, determining intriguing phenomena and properties in both conventional and quantum materials. In this manuscript, we propose and demonstrate a novel two dimensional (2D) EPC spectroscopy which allows for direct extraction of EPC matrix elements. We find that two pronounced phonon modes of methylammonium lead iodide (MAPI) at room temperature exhibit highly distinctive EPC behaviors, both in strength, geometry, and temperature dependence across the phase transition. This demonstration indicates the potential of our novel 2D spectroscopy for studying the evolution of mode-resolved EPC at various external conditions and phonon-mediated light induced ultrafast control of condensed materials.

Published
2023

8. A Cu3BHT-Graphene van der Waals Heterostructure with Strong Interlayer Coupling

Author

Wang, Zhiyong, Fu, Shuai, Zhang, Wenjie, Liang, Baokun, Liu, Tsai Jung, Hambsch, Mike, Pöhls, Jonas F., Wu, Yufeng, Zhang, Jianjun, Lan, Tianshu, Li, Xiaodong, Qi, Haoyuan, Polozij, Miroslav, Mannsfeld, Stefan C. B., Kaiser, Ute, Bonn, Mischa, Weitz, R. Thomas, Heine, Thomas, Parkin, Stuart S. P., Wang, Hai I, Dong, Renhao, and Feng, Xinliang

Subjects
Physics - Applied Physics
Abstract

Two dimensional van der Waals heterostructures (2D are of significant interest due to their intriguing physical properties that are critically defined by the constituent monolayers and their interlayer coupling . However, typical inorganic 2 D vdWhs fall into the weakly coupled region, limiting efficient interfacial charge flow crucial for developing high performance quantum opto electronics. Here, we demonstrate strong interlayer coupling in Cu3 BHT (BHT = benzenehexathiol) graphene vdWhs an organic inorganic bilayer characterized by prominent interlayer charge transfer Monolayer Cu3 BHT with a Kagome lattice is synthesized on the water surface and then coupled with graphene to produce a cm2 scale 2D vdWh. Spectroscopic and electrical studies, along with theoretical calculation s show significant hole transfer from monolayer Cu3 BHT to graphene upon contact , being characteristic fingerprints for strong interlayer coupling This study unveils the great potential of integrating highly pi-conjugated 2D coordination polymers (2DCPs) into 2D vdWhs to explor e intriguing physical phenomena.

Published
2023

9. Spontaneous Exciton Dissociation in Transition Metal Dichalcogenide Monolayers

Author

Handa, Taketo, Holbrook, Madisen A., Olsen, Nicholas, Holtzman, Luke N., Huber, Lucas, Wang, Hai I., Bonn, Mischa, Barmak, Katayun, Hone, James C., Pasupathy, Abhay N., and Zhu, X. -Y.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Since the seminal work on MoS2 monolayers, photoexcitation in atomically-thin transition metal dichalcogenides (TMDCs) has been assumed to result in excitons with large binding energies (~ 200-600 meV). Because the exciton binding energies are order-of-magnitude larger than thermal energy at room temperature, it is puzzling that photocurrent and photovoltage generation have been observed in TMDC-based devices, even in monolayers with applied electric fields far below the threshold for exciton dissociation. Here, we show that the photoexcitation of TMDC monolayers results in a substantial population of free charges. Performing ultrafast terahertz (THz) spectroscopy on large-area, single crystal WS2, WSe2, and MoSe2 monolayers, we find that ~10% of excitons spontaneously dissociate into charge carriers with lifetimes exceeding 0.2 ns. Scanning tunnelling microscopy reveals that photo-carrier generation is intimately related to mid-gap defect states, likely via trap-mediated Auger scattering. Only in state-of-the-art quality monolayers14, with mid-gap trap densities as low as 10^9 cm^-2, does intrinsic exciton physics start to dominate the THz response. Our findings reveal that excitons or excitonic complexes are only the predominant quasiparticles in photo-excited TMDC monolayers at the limit of sufficiently low defect densities., Comment: 18 pages, 5 figures, SI

Published
2023

10. Controlling the electro-optic response of a semiconducting perovskite coupled to a phonon-resonant cavity

Author

Di Virgilio, Lucia, Geuchies, Jaco J., Kim, Heejae, Krewer, Keno, Wang, Hai, Grechko, Maksim, and Bonn, Mischa

Subjects
Physics - Applied Physics, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Optical cavities, resonant with vibrational or electronic transitions of material within the cavity, enable control of light-matter interaction. Previous studies have reported cavity-induced modifications of chemical reactivity, fluorescence, phase behavior, and charge transport. Here, we explore the effect of resonant cavity-phonon coupling on the transient photoconductivity in a hybrid organic-inorganic perovskite. To this end, we measure the ultrafast photoconductivity response of perovskite in a tunable Fabry-Perot terahertz cavity, designed to be transparent for optical excitation. The terahertz-cavity field-phonon interaction causes apparent Rabi splitting between the perovskite phonon mode and the cavity mode. We explore whether the cavity-phonon interaction affects the material electron-phonon interaction by determining the charge carrier mobility through the photoconductivity. Despite the apparent hybridization of cavity and phonon modes, we show that the perovskite properties, in both ground (phonon response) and excited (photoconductive response) states, remain unaffected by the tunable light-matter interaction. Yet the response of the integral perovskite-terahertz optical cavity system depends critically on the interaction strength of the cavity with the phonon: the transient terahertz response to optical excitation can be increased up to 3-fold by tuning the cavity-perovskite interaction strength. These results enable tunable switches and frequency-controlled induced transparency devices., Comment: 14 pages, 4 figures

Published
2023

12. Transiently delocalized states enhance hole mobility in organic molecular semiconductors

Author

Giannini, Samuele, Di Virgilio, Lucia, Bardini, Marco, Hausch, Julian, Geuchies, Jaco, Zheng, Wenhao, Volpi, Martina, Elsner, Jan, Broch, Katharina, Geerts, Yves H., Schreiber, Frank, Schweicher, Guillaume, Wang, Hai I., Blumberger, Jochen, Bonn, Mischa, and Beljonne, David

Subjects
Condensed Matter - Soft Condensed Matter, Condensed Matter - Materials Science
Abstract

There is compelling evidence that charge carriers in organic semiconductors (OSs) self-localize in nano-scale space because of dynamic disorder. Yet, some OSs, in particular recently emerged high-mobility organic molecular crystals, feature reduced mobility at increasing temperature, a hallmark for delocalized band transport. Here we present the temperature-dependent mobility in two record-mobility OSs: DNTT (dinaphtho[2,3-b:2',3'-f]thieno[3,2-b]-thiophene), and its alkylated derivative, C8-DNTT-C8. By combining terahertz photoconductivity measurements with fully atomistic non-adiabatic molecular dynamics simulations, we show that while both crystals display a power-law decrease of the mobility (\mu) with temperature (T, following: \mu \propto T^(-n)), the exponent n differs substantially. Modelling provides n values in good agreement with experiments and reveals that the differences in the falloff parameter between the two chemically closely related semiconductors can be traced to the delocalization of the different states thermally accessible by charge carriers, which in turn depends on the specific electronic band structure of the two systems. The emerging picture is that of holes surfing on a dynamic manifold of vibrationally-dressed extended states with a temperature-dependent mobility that provides a sensitive fingerprint for the underlying density of states., Comment: 28 pages, 5 Figures

Published
2023

13. Electron cooling in graphene enhanced by plasmon-hydron resonance

Author

Yu, Xiaoqing, Principi, Alessandro, Tielrooij, Klaas-Jan, Bonn, Mischa, and Kavokine, Nikita

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Chemical Physics
Abstract

Evidence is accumulating for the crucial role of a solid's free electrons in the dynamics of solid-liquid interfaces. Liquids induce electronic polarization and drive electric currents as they flow; electronic excitations, in turn, participate in hydrodynamic friction. Yet, the underlying solid-liquid interactions have been lacking a direct experimental probe. Here, we study the energy transfer across liquid-graphene interfaces using ultrafast spectroscopy. The graphene electrons are heated up quasi-instantaneously by a visible excitation pulse, and the time evolution of the electronic temperature is then monitored with a terahertz pulse. We observe that water accelerates the cooling of the graphene electrons, whereas other polar liquids leave the cooling dynamics largely unaffected. A quantum theory of solid-liquid heat transfer accounts for the water-specific cooling enhancement through a resonance between the graphene surface plasmon mode and the so-called hydrons -- water charge fluctuations --, particularly the water libration modes, that allows for efficient energy transfer. Our results provide direct experimental evidence of a solid-liquid interaction mediated by collective modes and support the theoretically proposed mechanism for quantum friction. They further reveal a particularly large thermal boundary conductance for the water-graphene interface and suggest strategies for enhancing the thermal conductivity in graphene-based nanostructures.

Published
2023
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14. Extracting the sample response function from experimental two-dimensional terahertz-infrared-visible spectra

Author

Seliya, Pankaj, Bonn, Mischa, and Grechko, Maksim

Subjects
Physics - Chemical Physics
Abstract

Terahertz molecular motions are often probed by high-frequency molecular oscillators in different types of non-linear vibrational spectroscopy. Recently developed two-dimensional terahertz-infrared-visible spectroscopy allows direct measuring of this coupling and, thus, obtaining site-specific terahertz vibrational spectrum. However, these data are affected by the intensity and phase of the employed laser pulses. In this work, we develop a method of extracting sample response - representing solely physical properties of a material - from experimental spectra. Using dimethyl sulfoxide (DMSO) as a model molecule to verify this method, we measure the coupling between C-H stretch vibration of its methyl groups and terahertz intramolecular twist and wagging modes.

Published
2022
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15. Surface-specific vibrational spectroscopy of interfacial water reveals large pH change near graphene electrode at low current densities

Author

Wang, Yongkang, Seki, Takakazu, Liu, Xuan, Yu, Xiaoqing, Yu, Chun-Chieh, Domke, Katrin F., Hunger, Johannes, Koper, Marc T. M., Chen, Yunfei, Nagata, Yuki, and Bonn, Mischa

Subjects
Physics - Chemical Physics
Abstract

Molecular-level insight into interfacial water at buried electrode interfaces is essential in elucidating many phenomena of electrochemistry, but spectroscopic probing of the buried interfaces remains challenging. Here, using surface-specific vibrational spectroscopy, we probe and identify the interfacial water orientation and interfacial electric field at the calcium fluoride (CaF2)-supported electrified graphene/water interface under applied potentials. Our data shows that the water orientation changes drastically at negative potentials (<-0.03 V vs. Pd/H2), from O-H group pointing down towards bulk solution to pointing up away from the bulk solution, which arises from charging/discharging not of the graphene but of the CaF2 substrate. The potential-dependent spectra are nearly identical to the pH-dependent spectra, evidencing that the applied potentials change the local pH (more than five pH units) near the graphene electrode even at a current density below 1 microamp per square centimeter. Our work provides molecular-level insights into the dissociation and reorganization of interfacial water on an electrode/electrolyte interface.

Published
2022

16. The Surface of Electrolyte Solutions is Stratified

Author

Litman, Yair, Chiang, Kuo-Yang, Seki, Takakazu, Nagata, Yuki, and Bonn, Mischa

Subjects
Physics - Chemical Physics, Condensed Matter - Soft Condensed Matter
Abstract

The distribution of ions at the air/water interface plays a decisive role in many natural processes. It is generally understood that polarizable ions with low charge density are surface-active, implying they sit on top of the water surface. Here, we revise this established hypothesis by combining surface-specific heterodyne-detected vibrational sum-frequency generation with neural network-assisted ab initio molecular dynamics simulations. Our results directly demonstrate that ions in typical electrolyte solutions are, in fact, located in a subsurface region leading to a stratification of such interfaces into two distinctive water layers. The outermost surface is ion-depleted, and the sub-surface layer is ion-enriched. As a result, an effective liquid/liquid interface buried a few {\AA} inside the solution emerges, creating a second water/electrolyte interface, in addition to the outermost air/water interface.

Published
2022

17. Probing Carrier Dynamics in sp$^{3}$-Functionalized Single-Walled Carbon Nanotubes with Time-Resolved Terahertz Spectroscopy

Author

Zheng, Wenhao, Zorn, Nicolas F., Bonn, Mischa, Zaumseil, Jana, and Wang, Hai I.

Subjects
Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The controlled introduction of covalent sp$^{3}$ defects into semiconducting single-walled carbon nanotubes (SWCNTs) gives rise to exciton localization and red-shifted near-infrared luminescence. The single-photon emission characteristics of these functionalized SWCNTs make them interesting candidates for electrically driven quantum light sources. However, the impact of sp$^{3}$ defects on the carrier dynamics and charge transport in carbon nanotubes remains an open question. Here, we use ultrafast, time-resolved optical-pump terahertz-probe spectroscopy as a direct and quantitative technique to investigate the microscopic and temperature-dependent charge transport properties of pristine and functionalized (6,5) SWCNTs in dispersions and thin films. We find that sp$^{3}$ functionalization increases charge carrier scattering, thus reducing the intra-nanotube carrier mobility. In combination with electrical measurements of SWCNT network field-effect transistors, these data enable us to distinguish between contributions of intra-nanotube band transport, sp$^{3}$ defect scattering and inter-nanotube carrier hopping to the overall charge transport properties of nanotube networks., Comment: ACS Nano 2022

Published
2022
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18. Compositional engineering of interfacial charge transfer in van der Waals heterostructures of graphene and transition metal dichalcogenides.

Author

Wen, Guanzhao, Fu, Shuai, Bonn, Mischa, and Wang, Hai I.

Subjects
CHARGE exchange, INTERFACE dynamics, CHARGE transfer, TERAHERTZ spectroscopy, SCHOTTKY barrier
Abstract

Owing to their unique optical and electronic properties, vertical van der Waals heterostructures (vdWHs) have attracted considerable attention in optoelectronic applications, such as photodetection, light harvesting, and light-emitting diodes. To fully harness these properties, it is crucial to understand the interfacial charge transfer (CT) and recombination dynamics across vdWHs. However, the effects of interfacial energetics and defect states on interfacial CT and recombination processes in graphene-transition metal dichalcogenide (Gr-TMD) vdWHs remain debated. Here, we investigate the interfacial CT dynamics in Gr-TMD vdWHs with different chemical compositions (W, Mo, S, and Se) and tunable interfacial energetics. We demonstrate, using ultrafast terahertz spectroscopy, that while the photo-induced electron transfer direction is universal with graphene donating electrons to TMDs, its efficiency is chalcogen-dependent: the CT efficiency of S atom-based vdWHs is 3–5 times higher than that of Se-based vdWHs thanks to the lower Schottky barrier present in S-based vdWHs. In contrast, the electron back transfer process from TMD to Gr, which defines the charge separation time, is transition metal-dependent and dominated by the mid-gap defect level of TMDs: W transition metal-based vdWHs possess extremely long charge separation, well beyond 1 ns, which is significantly longer than Mo-based vdWHs with only 10 s of ps charge separation. This difference can be traced to the much deeper mid-gap defect reported in W-based TMDs compared to Mo-based ones, resulting in modified energetics for the back electron transfer from the trapped states to graphene. Our results shed light on the role of interfacial energetics and defects by tailoring chemical compositions of TMDs on the interfacial CT and recombination dynamics in Gr-TMD vdWHs, which is pivotal for optimizing optoelectronic devices, particularly in the field of photodetection. [ABSTRACT FROM AUTHOR]

Published
2024
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23. Exceptionally high charge mobility in phthalocyanine-based poly(benzimidazobenzophenanthroline)-ladder-type two-dimensional conjugated polymers

Author

Wang, Mingchao, Fu, Shuai, Petkov, Petko, Fu, Yubin, Zhang, Zhitao, Liu, Yannan, Ma, Ji, Chen, Guangbo, Gali, Sai Manoj, Gao, Lei, Lu, Yang, Paasch, Silvia, Zhong, Haixia, Steinrück, Hans-Peter, Cánovas, Enrique, Brunner, Eike, Beljonne, David, Bonn, Mischa, Wang, Hai I., Dong, Renhao, and Feng, Xinliang

Published
2023
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25. Hot-Carrier Cooling in High-Quality Graphene is Intrinsically Limited by Optical Phonons

Author

Pogna, Eva A. A., Jia, Xiaoyu, Principi, Alessandro, Block, Alexander, Banszerus, Luca, Zhang, Jincan, Liu, Xiaoting, Sohier, Thibault, Forti, Stiven, Soundarapandian, Karuppasamy, Terrés, Bernat, Mehew, Jake D., Trovatello, Chiara, Coletti, Camilla, Koppens, Frank H. L., Bonn, Mischa, van Hulst, Niek, Verstraete, Matthieu J., Peng, Hailin, Liu, Zhongfan, Stampfer, Christoph, Cerullo, Giulio, and Tielrooij, Klaas-Jan

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Physics - Applied Physics
Abstract

Many promising optoelectronic devices, such as broadband photodetectors, nonlinear frequency converters, and building blocks for data communication systems, exploit photoexcited charge carriers in graphene. For these systems, it is essential to understand, and eventually control, the cooling dynamics of the photoinduced hot-carrier distribution. There is, however, still an active debate on the different mechanisms that contribute to hot-carrier cooling. In particular, the intrinsic cooling mechanism that ultimately limits the cooling dynamics remains an open question. Here, we address this question by studying two technologically relevant systems, consisting of high-quality graphene with a mobility >10,000 cm$^2$V$^{-1}$s$^{-1}$ and environments that do not efficiently take up electronic heat from graphene: WSe$_2$-encapsulated graphene and suspended graphene. We study the cooling dynamics of these two high-quality graphene systems using ultrafast pump-probe spectroscopy at room temperature. Cooling via disorder-assisted acoustic phonon scattering and out-of-plane heat transfer to the environment is relatively inefficient in these systems, predicting a cooling time of tens of picoseconds. However, we observe much faster cooling, on a timescale of a few picoseconds. We attribute this to an intrinsic cooling mechanism, where carriers in the hot-carrier distribution with enough kinetic energy emit optical phonons. During phonon emission, the electronic system continuously re-thermalizes, re-creating carriers with enough energy to emit optical phonons. We develop an analytical model that explains the observed dynamics, where cooling is eventually limited by optical-to-acoustic phonon coupling. These fundamental insights into the intrinsic cooling mechanism of hot carriers in graphene will play a key role in guiding the development of graphene-based optoelectronic devices.

Published
2021

26. Liquid Flow Reversibly Creates a Macroscopic Surface Charge Gradient

Author

Ober, Patrick, Boon, Willem, Dijkstra, Marjolein, Backus, Ellen, van Roij, René, and Bonn, Mischa

Subjects
Condensed Matter - Soft Condensed Matter, Physics - Chemical Physics, Physics - Fluid Dynamics, Physics - Geophysics
Abstract

The charging and dissolution of mineral surfaces in contact with flowing liquids are ubiquitous in nature, as most minerals in water spontaneously acquire charge and dissolve. Mineral dissolution has been studied extensively under equilibrium conditions, even though non-equilibrium phenomena are pervasive and substantially affect the mineral-water interface. Here we demonstrate using interface-specific spectroscopy that liquid flow along a calcium fluoride surface creates a reversible, spatial charge gradient, with decreasing surface charge downstream of the flow. The surface charge gradient can be quantitatively accounted for by a reaction-diffusion-advection model, which reveals that the charge gradient results from a delicate interplay between diffusion, advection, dissolution, and desorption/adsorption. The underlying mechanism is expected to be valid for a wide variety of systems, including groundwater flows in nature and microfluidic systems., Comment: 25 pages, 8 figures, Supplementary Information: 21 pages, 7 figures

Published
2020
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27. Depth-profiling alkyl chain order in unsaturated lipid monolayers on water.

Author

Yu, Chun-Chieh, Seki, Takakazu, Chiang, Kuo-Yang, Wang, Yongkang, Bonn, Mischa, and Nagata, Yuki

Abstract

Unsaturated lipids with C=C groups in their alkyl chains are widely present in the cell membrane and food. The C=C groups alter the lipid packing density, membrane stability, and persistence against lipid oxidation. Yet, molecular-level insights into the structure of the unsaturated lipids remain scarce. Here, we probe the molecular structure and organization of monolayers of unsaturated lipids on the water surface using heterodyne-detected sum-frequency generation (HD-SFG) spectroscopy. We vary the location of the C=C in the alkyl chain and find that at high lipid density, the location of the C=C group affects neither the interfacial water organization nor the tail of the alkyl chain. Based on this observation, we use the C=C stretch HD-SFG response to depth-profile the alkyl chain conformation of the unsaturated lipid. We find that the first 1/3 of carbon atoms from the headgroup are relatively rigid, oriented perpendicular to the surface. In contrast, the remaining carbon atoms can be approximated as free rotators, introducing the disordering of the alkyl chains. [ABSTRACT FROM AUTHOR]

Published
2024
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28. Grating-graphene metamaterial as a platform for terahertz nonlinear photonics

Author

Deinert, Jan-Christoph, Iranzo, David Alcaraz, Perez, Raul, Jia, Xiaoyu, Hafez, Hassan A., Ilyakov, Igor, Awari, Nilesh, Chen, Min, Bawatna, Mohammed, Ponomaryov, Alexey N., Germanskiy, Semyon, Bonn, Mischa, Koppens, Frank H. L., Turchinovich, Dmitry, Gensch, Michael, Kovalev, Sergey, and Tielrooij, Klaas-Jan

Subjects
Physics - Optics, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science
Abstract

Nonlinear optics is an increasingly important field for scientific and technological applications, owing to its relevance and potential for optical and optoelectronic technologies. Currently, there is an active search for suitable nonlinear material systems with efficient conversion and small material footprint. Ideally, the material system should allow for chip-integration and room-temperature operation. Two-dimensional materials are highly interesting in this regard. Particularly promising is graphene, which has demonstrated an exceptionally large nonlinearity in the terahertz regime. Yet, the light-matter interaction length in two-dimensional materials is inherently minimal, thus limiting the overall nonlinear-optical conversion efficiency. Here we overcome this challenge using a metamaterial platform that combines graphene with a photonic grating structure providing field enhancement. We measure terahertz third-harmonic generation in this metamaterial and obtain an effective third-order nonlinear susceptibility with a magnitude as large as 3$\cdot$10$^{-8}$m$^2$/V$^2$, or 21 esu, for a fundamental frequency of 0.7 THz. This nonlinearity is 50 times larger than what we obtain for graphene without grating. Such an enhancement corresponds to third-harmonic signal with an intensity that is three orders of magnitude larger due to the grating. Moreover, we demonstrate a field conversion efficiency for the third harmonic of up to $\sim$1% using a moderate field strength of $\sim$30 kV/cm. Finally we show that harmonics beyond the third are enhanced even more strongly, allowing us to observe signatures of up to the 9$^{\rm th}$ harmonic. Grating-graphene metamaterials thus constitute an outstanding platform for commercially viable, CMOS compatible, room temperature, chip-integrated, THz nonlinear conversion applications.

Published
2020
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29. The Drude-Smith Model for Conductivity: de novo Derivation and Interpretation

Author

Krewer, Keno L., Ballabio, Marco, and Bonn, Mischa

Subjects
Condensed Matter - Materials Science
Abstract

The Drude-Smith model successfully describes the frequency and phase-resolved electrical conductivity data for a surprisingly broad range of systems, especially in the terahertz region. Still, its interpretation is unclear since its original derivation is flawed. We use an intuitive physical framework to derive the Drude-Smith formula for systems where microscopically free charges are accumulated on a mesoscopic scale by localized scatterers. Within this framework, the model allows us to quantify the microscopic momentum relaxation time of the charges and the fraction of mesoscopically localized charges in addition to the direct current limit of the conductivity. We show that the Drude-Smith model is unique among different Drude-Lorentz models because the relaxation time of the free carriers also determines the frequency and damping of the resonance of the bound charges., Comment: The assumptions made in eq. (6) / fig 1 b) are self- contradictory. It is no legitimate to assume that the incoming current stops instantaneously but the back current does not. The state of the art (Ku\v{z}el, P. & N\v{e}mec, H. Adv. Opt. Mater. 8, 1--23 (2020).) is that Drude-Smith is an empirical parameterisation and a general microscopic interpretation of the parameters alone should not be done

Published
2020

30. Long-Lived Charge Separation Following Pump-Energy Dependent Ultrafast Charge Transfer in Graphene/WS$_2$ Heterostructures

Author

Fu, Shuai, Fossé, Indy du, Jia, Xiaoyu, Xu, Jingyin, Yu, Xiaoqing, Zhang, Heng, Zheng, Wenhao, Krasel, Sven, Chen, Zongping, Wang, Zhiming M., Tielrooij, Klaas-Jan, Bonn, Mischa, Houtepen, Arjan J., and Wang, Hai I.

Subjects
Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Van der Waals heterostructures consisting of graphene and transition metal dichalcogenides (TMDCs) have recently shown great promise for high-performance optoelectronic applications. However, an in-depth understanding of the critical processes for device operation, namely interfacial charge transfer (CT) and recombination, has so far remained elusive. Here, we investigate these processes in graphene-WS$_2$ heterostructures, by complementarily probing the ultrafast terahertz photoconductivity in graphene and the transient absorption dynamics in WS$_2$ following photoexcitation. We find that CT across graphene-WS$_2$ interfaces occurs via photo-thermionic emission for sub-A-exciton excitation, and direct hole transfer from WS$_2$ to the valence band of graphene for above-A-exciton excitation. Remarkably, we observe that separated charges in the heterostructure following CT live extremely long: beyond 1 ns, in contrast to ~1 ps charge separation reported in previous studies. This leads to efficient photogating of graphene. These findings provide relevant insights to optimize further the performance of optoelectronic devices, in particular photodetection.

Published
2020
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32. Thickness-dependent electron momentum relaxation times in thin iron films

Author

Krewer, Keno L., Zhang, Wentao, Arabski, Jacek, Schmerber, Guy, Beaurepaire, Eric, Bonn, Mischa, and Turchinovich, Dmitry

Subjects
Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Terahertz time-domain conductivity measurements in 2 to 100 nm thick iron films resolve the femtosecond time delay between applied electric fields and resulting currents. This response time decreases for thinner metal films. The macroscopic response time depends on the mean and the variance of the distribution of microscopic momentum relaxation times of the conducting electrons. Comparing the recorded response times with DC-conductivities demonstrates increasing variance of the microscopic relaxation times with increasing film thickness. At least two electron species contribute to conduction in bulk with substantially differing relaxation times. The different electron species are affected differently by the confinement because they have different mean free paths., Comment: 11 pages, 3 figures

Published
2019
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33. Molecular Structure and Modeling of Water–Air and Ice–Air Interfaces Monitored by Sum-Frequency Generation

Author

Tang, Fujie, Ohto, Tatsuhiko, Sun, Shumei, Rouxel, Jérémy R, Imoto, Sho, Backus, Ellen HG, Mukamel, Shaul, Bonn, Mischa, and Nagata, Yuki

Subjects
Chemical Sciences, General Chemistry
Abstract

From a glass of water to glaciers in Antarctica, water-air and ice-air interfaces are abundant on Earth. Molecular-level structure and dynamics at these interfaces are key for understanding many chemical/physical/atmospheric processes including the slipperiness of ice surfaces, the surface tension of water, and evaporation/sublimation of water. Sum-frequency generation (SFG) spectroscopy is a powerful tool to probe the molecular-level structure of these interfaces because SFG can specifically probe the topmost interfacial water molecules separately from the bulk and is sensitive to molecular conformation. Nevertheless, experimental SFG has several limitations. For example, SFG cannot provide information on the depth of the interface and how the orientation of the molecules varies with distance from the surface. By combining the SFG spectroscopy with simulation techniques, one can directly compare the experimental data with the simulated SFG spectra, allowing us to unveil the molecular-level structure of water-air and ice-air interfaces. Here, we present an overview of the different simulation protocols available for SFG spectra calculations. We systematically compare the SFG spectra computed with different approaches, revealing the advantages and disadvantages of the different methods. Furthermore, we account for the findings through combined SFG experiments and simulations and provide future challenges for SFG experiments and simulations at different aqueous interfaces.

Published
2020

34. On selection rules in two-dimensional terahertz–infrared–visible spectroscopy.

Author

Seliya, Pankaj, Bonn, Mischa, and Grechko, Maksim

Subjects
*SPECTROMETRY, *RAMAN spectroscopy, *LASER pulses, *DIMETHYL sulfoxide, *TERAHERTZ spectroscopy
Abstract

Two-dimensional terahertz–infrared–visible (2D TIRV) spectroscopy directly measures the coupling between quantum high-frequency vibrations and classical low-frequency modes of molecular motion. In addition to coupling strength, the signal intensity in 2D TIRV spectroscopy can also depend on the selection rules of the excited transitions. Here, we explore the selection rules in 2D TIRV spectroscopy by studying the coupling between the high-frequency CH3 stretching and low-frequency vibrations of liquid dimethyl sulfoxide (DMSO). Different excitation pathways are addressed using variations in laser pulse timing and different polarizations of exciting pulses and detected signals. The DMSO signals generated via different excitation pathways can be readily distinguished in the spectrum. The intensities of different excitation pathways vary unequally with changes in polarization. We explain how this difference stems from the intensities of polarized and depolarized Raman and hyper-Raman spectra of high-frequency modes. These results apply to various systems and will help design and interpret new 2D TIRV spectroscopy experiments. [ABSTRACT FROM AUTHOR]

Published
2024
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36. Charge transport mechanism in networks of armchair graphene nanoribbons

Author

Richter, Nils, Chen, Zongping, Tries, Alexander, Prechtl, Thorsten, Narita, Akimitsu, Müllen, Klaus, Asadi, Kamal, Bonn, Mischa, and Kläui, Mathias

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

In graphene nanoribbons (GNRs), the lateral confinement of charge carriers opens a band gap, the key feature to enable novel graphene-based electronics. Successful synthesis of GNRs has triggered efforts to realize field-effect transistors (FETs) based on single ribbons. Despite great progress, reliable and reproducible fabrication of single-ribbon FETs is still a challenge that impedes applications and the understanding of the charge transport. Here, we present reproducible fabrication of armchair GNR-FETs based on a network of nanoribbons and analyze the charge transport mechanism using nine-atom wide and, in particular, five-atom-wide GNRs with unprecedented conductivity. We show formation of reliable Ohmic contacts and a yield of functional FETs close to unity by lamination of GNRs on the electrodes. Modeling the charge carrier transport in the networks reveals that this process is governed by inter-ribbon hopping mediated by nuclear tunneling, with a hopping length comparable to the physical length of the GNRs. Furthermore, we demonstrate that nuclear tunneling is a general charge transport characteristic of the GNR networks by using two different GNRs. Overcoming the challenge of low-yield single-ribbon transistors by the networks and identifying the corresponding charge transport mechanism puts GNR-based electronics in a new perspective.

Published
2018

41. Hierarchical assembly and environmental enhancement of bacterial ice nucleators.

Author

Renzer, Galit, de Almeida Ribeiro, Ingrid, Hao-Bo Guo, Fröhlich-Nowoisky, Janine, Berry, Rajiv J., Bonn, Mischa, Molinero, Valeria, and Meister, Konrad

Subjects
HETEROGENOUS nucleation, BACTERIAL cell walls, FREEZE-thaw cycles, ELECTROSTATIC interaction, CLASSROOM activities
Abstract

Bacterial ice nucleating proteins (INPs) are exceptionally effective in promoting the kinetically hindered transition of water to ice. Their efficiency relies on the assembly of INPs into large functional aggregates, with the size of ice nucleation sites determining activity. Experimental freezing spectra have revealed two distinct, defined aggregate sizes, typically classified as class A and C ice nucleators (INs). Despite the importance of INPs and years of extensive research, the precise number of INPs forming the two aggregate classes, and their assembly mechanism have remained enigmatic. Here, we report that bacterial ice nucleation activity emerges from more than two prevailing aggregate species and identify the specific number of INPs responsible for distinct crystallization temperatures. We find that INP dimers constitute class C INs, tetramers class B INs, and hexamers and larger multimers are responsible for the most efficient class A activity. We propose a hierarchical assembly mechanism based on tyrosine interactions for dimers, and electrostatic interactions between INP dimers to produce larger aggregates. This assembly is membrane-assisted: Increasing the bacterial outer membrane fluidity decreases the population of the larger aggregates, while preserving the dimers. Inversely, Dulbecco’s Phosphate-Buffered Saline buffer increases the population of multimeric class A and B aggregates 200-fold and endows the bacteria with enhanced stability toward repeated freeze-thaw cycles. Our analysis suggests that the enhancement results from the better alignment of dimers in the negatively charged outer membrane, due to screening of their electrostatic repulsion. This demonstrates significant enhancement of the most potent bacterial INs. [ABSTRACT FROM AUTHOR]

Published
2024
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44. Structural adaptability and surface activity of peptides derived from tardigrade proteins.

Author

Giubertoni, Giulia, Chagri, Sarah, Argudo, Pablo G., Prädel, Leon, Maltseva, Daria, Greco, Alessandro, Caporaletti, Federico, Pavan, Alberto, Ilie, Ioana M., Ren, Yong, Ng, David Y.W., Bonn, Mischa, Weil, Tanja, and Woutersen, Sander

Abstract

Tardigrades are unique micro‐organisms with a high tolerance to desiccation. The protection of their cells against desiccation involves tardigrade‐specific proteins, which include the so‐called cytoplasmic abundant heat soluble (CAHS) proteins. As a first step towards the design of peptides capable of mimicking the cytoprotective properties of CAHS proteins, we have synthesized several model peptides with sequences selected from conserved CAHS motifs and investigated to what extent they exhibit the desiccation‐induced structural changes of the full‐length proteins. Using circular dichroism spectroscopy, two‐dimensional infrared spectroscopy, and molecular dynamics simulations, we have found that the CAHS model peptides are mostly disordered, but adopt a more α$$ \alpha $$‐helical structure upon addition of 2,2,2‐trifluoroethanol, which mimics desiccation. This structural behavior is similar to that of full‐length CAHS proteins, which also adopt more ordered conformations upon desiccation. We also have investigated the surface activity of the peptides at the air/water interface, which also mimics partial desiccation. Interestingly, sum‐frequency generation spectroscopy shows that all model peptides are surface active and adopt a helical structure at the air/water interface. Our results suggest that amino acids with high helix‐forming propensities might contribute to the propensity of these peptides to adopt a helical structure when fully or partially dehydrated. Thus, the selected sequences retain part of the CAHS structural behavior upon desiccation, and might be used as a basis for the design of new synthetic peptide‐based cryoprotective materials. [ABSTRACT FROM AUTHOR]

Published
2024
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46. Quasi-Homogeneous Photocatalysis in Ultrastiff Microporous Polymer Aerogels

Author

Su, Yan, primary, Li, Bo, additional, Wang, Zaoming, additional, Legrand, Alexandre, additional, Aoyama, Takuma, additional, Fu, Shuai, additional, Wu, Yishi, additional, Otake, Ken-Ichi, additional, Bonn, Mischa, additional, Wang, Hai I., additional, Liao, Qing, additional, Urayama, Kenji, additional, Kitagawa, Susumu, additional, Huang, Liangbin, additional, Furukawa, Shuhei, additional, and Gu, Cheng, additional

Published
2024
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50. Control of the Hydroquinone/Benzoquinone Redox State in High‐Mobility Semiconducting Conjugated Coordination Polymers

Author

Huang, Xing, primary, Li, Yang, additional, Fu, Shuai, additional, Ma, Chao, additional, Lu, Yang, additional, Wang, Mingchao, additional, Zhang, Peng, additional, Li, Ze, additional, He, Feng, additional, Huang, Chuanhui, additional, Liao, Zhongquan, additional, Zou, Ye, additional, Zhou, Shengqiang, additional, Helm, Manfred, additional, Petkov, Petko St., additional, Wang, Hai I., additional, Bonn, Mischa, additional, Li, Jian, additional, Xu, Wei, additional, Dong, Renhao, additional, and Feng, Xinliang, additional

Published
2024
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