Your search keyword '"Szydłowska, Beata"' showing total 22 results

1. Printed nanomaterial sensor platforms for COVID-19 and future pandemics

Author

Szydłowska, Beata M., Cai, Zizhen, and Hersam, Mark C.

Published

2023

2. Electroluminescence from Megasonically Solution-Processed MoS2 Nanosheet Films.

Author

Rangnekar, Sonal V., Sangwan, Vinod K., Jin, Mengru, Khalaj, Maryam, Szydłowska, Beata M., Dasgupta, Anushka, Kuo, Lidia, Kurtz, Heather E., Marks, Tobin J., and Hersam, Mark C.

Published

2023

3. Sonication-assisted liquid exfoliation and size-dependent properties of magnetic two-dimensional α -RuCl3.

Author

Synnatschke, Kevin, Jonak, Martin, Storm, Alexander, Laha, Sourav, Köster, Janis, Petry, Julian, Ott, Steffen, Szydłowska, Beata, Duesberg, Georg S, Kaiser, Ute, Klingeler, Rüdiger, Lotsch, Bettina V, and Backes, Claudia

Subjects

SONICATION, CENTRIFUGATION, MAGNETIC properties, X-ray photoelectron spectroscopy, ATOMIC force microscopy, TRANSMISSION electron microscopy, MAGNETIC ions

Abstract

Originating from the hexagonal arrangement of magnetic ions in the presence of strong spin orbit coupling, α -RuCl3 is considered as model system for the Kitaev-Heisenberg model. While the magnetic properties of α -RuCl3 have been studied in bulk single crystals or micromechanically-exfoliated nanosheets, little is known about the nanosheets' properties after exfoliation by techniques suitable for mass production such as liquid phase exfoliation (LPE). Here, we demonstrate sonication-assisted LPE on α -RuCl3 single crystals in an inert atmosphere. Coupled with centrifugation-based size selection techniques, the accessible size- and thickness range is quantified by statistical atomic force microscopy. Individual nanosheets obtained after centrifugation-based size selection are subjected to transmission electron microscopy to confirm their structural integrity after the exfoliation. The results are combined with bulk characterisation methods, including Raman and x-ray photoelectron spectroscopy, and powder diffraction experiments to evaluate the structural integrity of the nanosheets. We report changes of the magnetic properties of the nanomaterial with nanosheet size, as well as photospectroscopic metrics for the material concentration and average layer number. Finally, a quantitative analysis on environmental effects on the nanomaterial integrity is performed based on time and temperature dependent absorbance spectroscopy revealing a relatively slow decay (half-life of ∼2000 h at 20 °C), albeit with low activation energies of 6–20 kJ mol−1. [ABSTRACT FROM AUTHOR]

Published

2023

4. Highly conductive and long-term stable films from liquid-phase exfoliated platinum diselenide.

Author

Lee, Kangho, Szydłowska, Beata M., Hartwig, Oliver, Synnatschke, Kevin, Tywoniuk, Bartlomiej, Hartman, Tomáš, Tomašević-Ilić, Tijana, Gabbett, Cian P., Coleman, Jonathan N., Sofer, Zdeněk, Spasenović, Marko, Backes, Claudia, and Duesberg, Georg S.

Abstract

Liquid-phase exfoliation (LPE) has been introduced as a versatile and scalable production method for two-dimensional (2D) materials. This method yields dispersions that allow for the fabrication of printable and flexible electronic devices. However, the fabrication of uniform and homogeneous films from LPE dispersions with a performance similar to that of bottom-up grown materials remains a challenge, as the film quality strongly influences the optical and electrical performance of devices. Furthermore, long-term stability remains a major challenge for all 2D material based applications. In this study, we report on highly conductive tiled network films made of platinum diselenide (PtSe2) flakes derived using a scalable LPE method. We characterized the homogeneous films in terms of morphology and electrical behavior. As an example of applicability, we produce a chemiresistive sensor structure with the PtSe2 films and show significant resistance changes upon periodic ammonia gas exposures, revealing a sub-0.1 part per million (ppm) detection limit (DL). More remarkably the devices are fully functional after 15 months, underlining the high stability of PtSe2 based devices. [ABSTRACT FROM AUTHOR]

Published

2023

5. Understanding the Photoluminescence Quenching of Liquid Exfoliated WS2 Monolayers.

Author

Li, Zhaojun, Rashvand, Farnia, Bretscher, Hope, Szydłowska, Beata M., Xiao, James, Backes, Claudia, and Rao, Akshay

Published

2022

6. All‐Printed Ultrahigh‐Responsivity MoS2 Nanosheet Photodetectors Enabled by Megasonic Exfoliation.

Author

Kuo, Lidia, Sangwan, Vinod K., Rangnekar, Sonal V., Chu, Ting‐Ching, Lam, David, Zhu, Zhehao, Richter, Lee J., Li, Ruipeng, Szydłowska, Beata M., Downing, Julia R., Luijten, Benjamin J., Lauhon, Lincoln J., and Hersam, Mark C.

Published

2022

7. Liquid-Phase Exfoliation of Magnetically and Optoelectronically Active Ruthenium Trichloride Nanosheets.

Author

Lam, David, Lebedev, Dmitry, Kuo, Lidia, Sangwan, Vinod K., Szydłowska, Beata M., Ferraresi, Filippo, Söll, Aljoscha, Sofer, Zdeněk, and Hersam, Mark C.

Published

2022

8. Highly Conductive Networks of Silver Nanosheets.

Author

Kelly, Adam G., O'Reilly, Jane, Gabbett, Cian, Szydłowska, Beata, O'Suilleabhain, Domhnall, Khan, Umar, Maughan, Jack, Carey, Tian, Sheil, Siadhbh, Stamenov, Plamen, and Coleman, Jonathan N.

Published

2022

9. Preparation of WS2–PMMA composite films for optical applications.

Author

Szydłowska, Beata M., Graf, Arko, Kelly, Adam, Blau, Werner J., Gather, Malte C., Zaumseil, Jana, and Backes, Claudia

Abstract

Thus far, research activities of 2D materials in optics, photonics and optoelectronics predominantly focus on micromechanically cleaved or grown nanosheets. Here, we show that high quality liquid-exfoliated nanosheets offer an alternative approach. Starting from well-defined, monolayer rich WS2 dispersions obtained after liquid exfoliation and size selection in aqueous surfactant, we present an optimised protocol facilitating transfer of the nanosheets to a polymer solution in organic media. From such dispersions, we fabricate WS2–polymer thin films by spin coating. The characteristic photoluminescence of WS2 monolayers is retained in the film at 2.04 eV without broadening (line width 40 meV) or significant changes in the line-shape. This confirms that nanosheet aggregation is efficiently prevented on transfer and deposition. The films are extremely smooth and uniform over large areas with a root mean square roughness <0.5 nm. To demonstrate the potential in optical applications, the nonlinear optical response was studied, revealing promise as optical limiter. In addition, we show that the photoluminescence can be manipulated by coupling the exciton response to cavity photons in a Ag microcavity. [ABSTRACT FROM AUTHOR]

Published

2020

10. Site‐Selective Oxidation of Monolayered Liquid‐Exfoliated WS2 by Shielding the Basal Plane through Adsorption of a Facial Amphiphile.

Author

Grieger, Sebastian, Szydłowska, Beata M., Rao, Vaishnavi J., Steinmann, Eva, Dodds, Marcus, Gholamvand, Zahra, Duesberg, Georg S., Zaumseil, Jana, and Backes, Claudia

Subjects

*ADSORPTION (Chemistry), *GOLD nanoparticles, *MECHANICAL properties of condensed matter, *OXIDATION, *SURFACE active agents

Abstract

In recent years, various functionalization strategies for transition‐metal dichalcogenides have been explored to tailor the properties of materials and to provide anchor points for the fabrication of hybrid structures. Herein, new insights into the role of the surfactant in functionalization reactions are described. Using the spontaneous reaction of WS2 with chloroauric acid as a model reaction, the regioselective formation of gold nanoparticles on WS2 is shown to be heavily dependent on the surfactant employed. A simple model is developed to explain the role of the chosen surfactant in this heterogeneous functionalization reaction. The surfactant coverage is identified as the crucial element that governs the dominant reaction pathway and therefore can severely alter the reaction outcome. This study shows the general importance of the surfactant choice and how detrimental or beneficial a certain surfactant can be to the desired functionalization. [ABSTRACT FROM AUTHOR]

Published

2020

11. Amyloid Fibril Design: Limiting Structural Polymorphism in Alzheimer's Aβ Protofilaments.

Author

Tywoniuk, Bartłomiej, Yuan, Ye, McCartan, Sarah, Szydłowska, Beata Maria, Tofoleanu, Florentina, Brooks, Bernard R., and Buchete, Nicolae-Viorel

Published

2018

12. Liquid Exfoliated Co(OH)2 Nanosheets as Low‐Cost, Yet High‐Performance, Catalysts for the Oxygen Evolution Reaction.

Author

McAteer, David, Godwin, Ian J., Ling, Zheng, Harvey, Andrew, He, Lily, Boland, Conor S., Vega‐Mayoral, Victor, Szydłowska, Beata, Rovetta, Aurélie A., Backes, Claudia, Boland, John B., Chen, Xin, Lyons, Michael E. G., and Coleman, Jonathan N.

Subjects

OXYGEN evolution reactions, WATER electrolysis, CATALYTIC activity, ELECTROCHEMICAL electrodes, CARBON nanofibers

Abstract

Abstract: Identifying cheap, yet effective, oxygen evolution catalysts is critical to the advancement of water splitting. Using liquid exfoliated Co(OH)2 nanosheets as a model system, a simple procedure is developed to maximize the activity of any oxygen evolution reaction nanocatalyst. First the nanosheet edges are confirmed as the active areas by analyzing the catalytic activity as a function of nanosheet size. This allows the authors to select the smallest nanosheets (length ≈50 nm) as the best performing catalysts. While the number of active sites per unit electrode area can be increased via the electrode thickness, this is found to be impossible beyond ≈10 µm due to mechanical instabilities. However, adding carbon nanotubes increases both toughness and conductivity significantly. These enhancements mean that composite electrodes consisting of small Co(OH)2 nanosheets and 10 wt% nanotubes can be made into freestanding films with thickness of up to 120 µm with no apparent electrical limitations. The presence of diffusion limitations results in an optimum electrode thickness of 70 µm, yielding a current density of 50 mA cm−2 at an overpotential of 235 mV, close to the state of the art in the field. Applying this procedure to a high‐performance catalyst such as NiFeOx should significantly surpass the state of the art. [ABSTRACT FROM AUTHOR]

Published

2018

13. Quantifying the Role of Nanotubes in Nano: Nano Composite Supercapacitor Electrodes.

Author

Zheng Ling, Harvey, Andrew, McAteer, David, Godwin, Ian J., Szydłowska, Beata, Griffin, Aideen, Vega-Mayoral, Victor, Yongchen Song, Seral-Ascaso, Andrés, Nicolosi, Valeria, and Coleman, Jonathan

Subjects

NANOTUBES, SUPERCAPACITORS, ELECTRODES, NANOCOMPOSITE materials, ADDITIVES

Abstract

Many promising supercapacitor electrode materials have high resistivity and require conductive additives to function effectively. However, the detailed role of the additive is not understood. Here, this question is resolved by applying a quantitative model for resistance-limited supercapacitor electrodes to Co(OH)2-nanosheet/carbon nanotube composites. Without nanotubes, theory predicts and experiments show that while the low-rate capacitance increases linearly with electrode thickness, the high rate capacitance decreases with thickness due to slow charging. Experiments supported by theory show that nanotube addition has two effects. First, the nanotube network effectively distributes charge, increasing the intrinsic electrode performance to the limit associated with its accessible surface area. Second, at high-rate, the increased electrode conductivity shifts the rate-limiting resistance from electrode to electrolyte, thus removing the thickness-dependent capacitance falloff. Furthermore, the analysis quantifies the out-of-plane conductivity of the nanotube network, identifies the cross-over from resistance-limited to diffusion-limited behavior, and allows full electrode modeling, facilitating rational design. [ABSTRACT FROM AUTHOR]

Published

2018

14. Quantifying the Role of Nanotubes in Nano:Nano Composite Supercapacitor Electrodes.

Author

Ling, Zheng, Harvey, Andrew, McAteer, David, Godwin, Ian J., Szydłowska, Beata, Griffin, Aideen, Vega‐Mayoral, Victor, Song, Yongchen, Seral‐Ascaso, Andrés, Nicolosi, Valeria, and Coleman, Jonathan

Subjects

CARBON nanotubes, SUPERCAPACITOR electrodes, ELECTRICAL resistivity, ELECTRIC charge, ELECTRIC conductivity

Abstract

Abstract: Many promising supercapacitor electrode materials have high resistivity and require conductive additives to function effectively. However, the detailed role of the additive is not understood. Here, this question is resolved by applying a quantitative model for resistance‐limited supercapacitor electrodes to Co(OH)2‐nanosheet/carbon nanotube composites. Without nanotubes, theory predicts and experiments show that while the low‐rate capacitance increases linearly with electrode thickness, the high rate capacitance decreases with thickness due to slow charging. Experiments supported by theory show that nanotube addition has two effects. First, the nanotube network effectively distributes charge, increasing the intrinsic electrode performance to the limit associated with its accessible surface area. Second, at high‐rate, the increased electrode conductivity shifts the rate‐limiting resistance from electrode to electrolyte, thus removing the thickness‐dependent capacitance falloff. Furthermore, the analysis quantifies the out‐of‐plane conductivity of the nanotube network, identifies the cross‐over from resistance‐limited to diffusion‐limited behavior, and allows full electrode modeling, facilitating rational design. [ABSTRACT FROM AUTHOR]

Published

2018

15. Ultrafast Nonlinear Optical Properties of a Graphene Saturable Mirror in the 2 μm Wavelength Region.

Author

Wang, Gaozhong, Wang, Kangpeng, Szydłowska, Beata M., Baker‐Murray, Aidan A., Wang, Jing Jing, Feng, Yanyan, Zhang, Xiaoyan, Wang, Jun, and Blau, Werner J.

Subjects

OPTICAL properties of graphene, PICOSECOND pulses, SEMICONDUCTORS, PHOTONICS, WAVELENGTHS

Abstract

Mid-infrared ultrafast lasers have emerged as a promising platform for both science and industry because of their inherent high raw power and eye-safe spectrum. 2D nanostructures such as graphene have emerged as promising photonic materials for laser mode-locking to generate ultrashort pulses. However, there are still many unanswered questions about graphene's key advantages to be practical devices, especially over the matured semiconductor saturable absorber mirror (SESAM). In this work, we conducted systematic comparisons on the nonlinear optical properties of graphene and that of a commercial SESAM at 2 μm wavelength. Our results showed that graphene has significant advantages over the commercial SESAM, exhibiting ∼28% less absorptive cross-section ratio of excited-state to ground-state and ∼50 times faster relaxation time. This implies that graphene can be exploited as a better mode-locker than the current commercial SESAM for high power, high repetition rate and ultrafast mid-infrared laser sources. [ABSTRACT FROM AUTHOR]

Published

2017

16. Sonication-assisted liquid exfoliation and size-dependent properties of magnetic two-dimensional α -RuCl3.

Author

Synnatschke, Kevin, Jonak, Martin, Storm, Alexander, Laha, Sourav, Köster, Janis, Petry, Julian, Ott, Steffen, Szydłowska, Beata, Duesberg, Georg S, Kaiser, Ute, Klingeler, Rüdiger, Lotsch, Bettina V, and Backes, Claudia

Subjects

*SONICATION, *CENTRIFUGATION, *MAGNETIC properties, *X-ray photoelectron spectroscopy, *ATOMIC force microscopy, *TRANSMISSION electron microscopy, *MAGNETIC ions

Abstract

Originating from the hexagonal arrangement of magnetic ions in the presence of strong spin orbit coupling, α -RuCl3 is considered as model system for the Kitaev-Heisenberg model. While the magnetic properties of α -RuCl3 have been studied in bulk single crystals or micromechanically-exfoliated nanosheets, little is known about the nanosheets' properties after exfoliation by techniques suitable for mass production such as liquid phase exfoliation (LPE). Here, we demonstrate sonication-assisted LPE on α -RuCl3 single crystals in an inert atmosphere. Coupled with centrifugation-based size selection techniques, the accessible size- and thickness range is quantified by statistical atomic force microscopy. Individual nanosheets obtained after centrifugation-based size selection are subjected to transmission electron microscopy to confirm their structural integrity after the exfoliation. The results are combined with bulk characterisation methods, including Raman and x-ray photoelectron spectroscopy, and powder diffraction experiments to evaluate the structural integrity of the nanosheets. We report changes of the magnetic properties of the nanomaterial with nanosheet size, as well as photospectroscopic metrics for the material concentration and average layer number. Finally, a quantitative analysis on environmental effects on the nanomaterial integrity is performed based on time and temperature dependent absorbance spectroscopy revealing a relatively slow decay (half-life of ∼2000 h at 20 °C), albeit with low activation energies of 6–20 kJ mol−1. [ABSTRACT FROM AUTHOR]

Published

2023

17. Electroluminescence from Megasonically Solution-Processed MoS 2 Nanosheet Films.

Author

Rangnekar SV, Sangwan VK, Jin M, Khalaj M, Szydłowska BM, Dasgupta A, Kuo L, Kurtz HE, Marks TJ, and Hersam MC

Abstract

Due to their superior optoelectronic properties, monolayer two-dimensional (2D) transition metal dichalcogenides (TMDs) have attracted significant attention for electroluminescent devices. However, challenges in isolating optoelectronically active TMD monolayers using scalable liquid phase exfoliation have precluded electroluminescence in large-area, solution-processed TMD films. Here, we overcome these limitations and demonstrate electroluminescence from molybdenum disulfide (MoS 2 ) nanosheet films by employing a monolayer-rich MoS 2 ink produced by electrochemical intercalation and megasonic exfoliation. Characteristic monolayer MoS 2 photoluminescence and electroluminescence spectral peaks at 1.88-1.90 eV are observed in megasonicated MoS 2 films, with the emission intensity increasing with film thickness over the range 10-70 nm. Furthermore, employing a vertical light-emitting capacitor architecture enables uniform electroluminescence in large-area devices. These results indicate that megasonically exfoliated MoS 2 monolayers retain their direct bandgap character in electrically percolating thin films even following multistep solution processing. Overall, this work establishes megasonicated MoS 2 inks as an additive manufacturing platform for flexible, patterned, and miniaturized light sources that can likely be expanded to other TMD semiconductors.

Published

2023

18. Understanding the Photoluminescence Quenching of Liquid Exfoliated WS 2 Monolayers.

Author

Li Z, Rashvand F, Bretscher H, Szydłowska BM, Xiao J, Backes C, and Rao A

Abstract

Monolayer transition metal dichalcogenides (TMDs) are being investigated as active materials in optoelectronic devices due to their strong excitonic effects. While mechanical exfoliation (ME) of monolayer TMDs is limited to small areas, these materials can also be exfoliated from their parent layered materials via high-volume liquid phase exfoliation (LPE). However, it is currently considered that LPE-synthesized materials show poor optoelectronic performance compared to ME materials, such as poor photoluminescence quantum efficiencies (PLQEs). Here we evaluate the photophysical properties of monolayer-enriched LPE WS 2 dispersions via steady-state and time-resolved optical spectroscopy and benchmark these materials against untreated and chemically treated ME WS 2 monolayers. We show that the LPE materials show features of high-quality semiconducting materials such as very small Stokes shift, smaller photoluminescence line widths, and longer exciton lifetimes than ME WS 2 . We reveal that the energy transfer between the direct-gap monolayers and in-direct gap few-layers in LPE WS 2 dispersions is a major reason for their quenched PL. Our results suggest that LPE TMDs are not inherently highly defective and could have a high potential for optoelectronic device applications if improved strategies to purify the LPE materials and reduce aggregation could be implemented., Competing Interests: The authors declare no competing financial interest., (© 2022 The Authors. Published by American Chemical Society.)

Published

2022

19. All-Printed Ultrahigh-Responsivity MoS 2 Nanosheet Photodetectors Enabled by Megasonic Exfoliation.

Author

Kuo L, Sangwan VK, Rangnekar SV, Chu TC, Lam D, Zhu Z, Richter LJ, Li R, Szydłowska BM, Downing JR, Luijten BJ, Lauhon LJ, and Hersam MC

Abstract

Printed 2D materials, derived from solution-processed inks, offer scalable and cost-effective routes to mechanically flexible optoelectronics. With micrometer-scale control and broad processing latitude, aerosol-jet printing (AJP) is of particular interest for all-printed circuits and systems. Here, AJP is utilized to achieve ultrahigh-responsivity photodetectors consisting of well-aligned, percolating networks of semiconducting MoS 2 nanosheets and graphene electrodes on flexible polyimide substrates. Ultrathin (≈1.2 nm thick) and high-aspect-ratio (≈1 μm lateral size) MoS 2 nanosheets are obtained by electrochemical intercalation followed by megasonic atomization during AJP, which not only aerosolizes the inks but also further exfoliates the nanosheets. The incorporation of the high-boiling-point solvent terpineol into the MoS 2 ink is critical for achieving a highly aligned and flat thin-film morphology following AJP as confirmed by grazing-incidence wide-angle X-ray scattering and atomic force microscopy. Following AJP, curing is achieved with photonic annealing, which yields quasi-ohmic contacts and photoactive channels with responsivities exceeding 10 3  A W -1 that outperform previously reported all-printed visible-light photodetectors by over three orders of magnitude. Megasonic exfoliation coupled with properly designed AJP ink formulations enables the superlative optoelectronic properties of ultrathin MoS 2 nanosheets to be preserved and exploited for the scalable additive manufacturing of mechanically flexible optoelectronics., (© 2022 The Authors. Advanced Materials published by Wiley-VCH GmbH.)

Published

2022

20. Site-Selective Oxidation of Monolayered Liquid-Exfoliated WS 2 by Shielding the Basal Plane through Adsorption of a Facial Amphiphile.

Author

Grieger S, Szydłowska BM, Rao VJ, Steinmann E, Dodds M, Gholamvand Z, Duesberg GS, Zaumseil J, and Backes C

Abstract

In recent years, various functionalization strategies for transition-metal dichalcogenides have been explored to tailor the properties of materials and to provide anchor points for the fabrication of hybrid structures. Herein, new insights into the role of the surfactant in functionalization reactions are described. Using the spontaneous reaction of WS 2 with chloroauric acid as a model reaction, the regioselective formation of gold nanoparticles on WS 2 is shown to be heavily dependent on the surfactant employed. A simple model is developed to explain the role of the chosen surfactant in this heterogeneous functionalization reaction. The surfactant coverage is identified as the crucial element that governs the dominant reaction pathway and therefore can severely alter the reaction outcome. This study shows the general importance of the surfactant choice and how detrimental or beneficial a certain surfactant can be to the desired functionalization., (© 2020 The Authors. Published by Wiley-VCH Verlag GmbH & Co. KGaA.)

Published

2020

21. Ultrafast Nonlinear Excitation Dynamics of Black Phosphorus Nanosheets from Visible to Mid-Infrared.

Author

Wang K, Szydłowska BM, Wang G, Zhang X, Wang JJ, Magan JJ, Zhang L, Coleman JN, Wang J, and Blau WJ

Abstract

The recent progress on black phosphorus makes it a promising candidate material for broadband nanophotonic devices, especially operating in the mid-infrared spectral region. Here, the excited carrier dynamics and nonlinear optical response of unoxidized black phosphorus nanosheets and their wavelength dependence were systematically studied from 800 nm to 2.1 μm. The wavelength-dependent relaxation times of black phosphorus nanosheets are determined to be 360 fs to 1.36 ps with photon energies from 1.55 to 0.61 eV. In a comparative study with graphene, we found that black phosphorus has a faster carrier relaxation in near- and mid-infrared region. With regard to nonlinear optical absorption, the response of black phosphorus significantly increases from near- to mid-infrared, and black phosphorus is also confirmed to be better as saturable absorber to MoS2 in infrared region.

Published

2016

22. Production of Highly Monolayer Enriched Dispersions of Liquid-Exfoliated Nanosheets by Liquid Cascade Centrifugation.

Author

Backes C, Szydłowska BM, Harvey A, Yuan S, Vega-Mayoral V, Davies BR, Zhao PL, Hanlon D, Santos EJ, Katsnelson MI, Blau WJ, Gadermaier C, and Coleman JN

Abstract

While liquid exfoliation is a powerful technique to produce defect-free nanosheets in large quantities, its usefulness is limited by broad nanosheet thickness distributions and low monolayer contents. Here we demonstrate liquid processing techniques, based on iterative centrifugation cascades, which can be designed to achieve either highly efficient nanosheet size-selection and/or monolayer enrichment. The resultant size-selected dispersions were used to establish quantitative metrics to determine monolayer volume fraction, as well as mean nanosheet size and thickness, from standard spectroscopic measurements. Such metrics allowed us to design and optimize centrifugation cascades to enrich liquid exfoliated WS2 dispersions up to monolayer contents of 75%. Monolayer-rich dispersions show relatively bright photoluminescence with narrow line widths (<35 meV) indicating the high quality of the nanosheets. The enriched dispersions display extinction spectra with distinct features, which also allow the direct estimation of monolayer contents.

Published

2016