Your search keyword '"Szydłowska, Beata"' showing total 6 results

1. Understanding the Photoluminescence Quenching of Liquid Exfoliated WS2 Monolayers

Author

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

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 WS2 dispersions via steady-state and time-resolved optical spectroscopy and benchmark these materials against untreated and chemically treated ME WS2 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 WS2. We reveal that the energy transfer between the direct-gap monolayers and in-direct gap few-layers in LPE WS2 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.

Published

2022

2. Understanding the Photoluminescence Quenching of Liquid Exfoliated WS2 Monolayers

Author

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

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 WS2 dispersions via steady-state and time-resolved optical spectroscopy and benchmark these materials against untreated and chemically treated ME WS2 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 WS2. We reveal that the energy transfer between the direct-gap monolayers and in-direct gap few-layers in LPE WS2 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.

Published

2022

3. Understanding the Photoluminescence Quenching of Liquid Exfoliated WS2 Monolayers

Author

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

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 WS2 dispersions via steady-state and time-resolved optical spectroscopy and benchmark these materials against untreated and chemically treated ME WS2 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 WS2. We reveal that the energy transfer between the direct-gap monolayers and in-direct gap few-layers in LPE WS2 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.

Published

2022

4. Understanding the Photoluminescence Quenching of Liquid Exfoliated WS2 Monolayers

Author

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

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 WS2 dispersions via steady-state and time-resolved optical spectroscopy and benchmark these materials against untreated and chemically treated ME WS2 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 WS2. We reveal that the energy transfer between the direct-gap monolayers and in-direct gap few-layers in LPE WS2 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.

Published

2022

5. Understanding the Photoluminescence Quenching of Liquid Exfoliated WS2 Monolayers

Author

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

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 WS2 dispersions via steady-state and time-resolved optical spectroscopy and benchmark these materials against untreated and chemically treated ME WS2 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 WS2. We reveal that the energy transfer between the direct-gap monolayers and in-direct gap few-layers in LPE WS2 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.

Published

2022

6. 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, 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, and Backes, Claudia

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.

Published

2022