Highly enhanced UV absorption and light emission of monolayer WS2 through hybridization with Ti2N MXene quantum dots and g-C3N4 quantum dots
通过与Ti₂N MXene量子点和g-C₃N₄ 量子点杂交,高度增强单层WS₂的紫外线吸收和发光
Ti₂N MXene 量子ドットとg−C₃N₄ 量子ドットとのハイブリダイゼーションにより、単層 WS₂ の紫外線吸収と発光を高度に増強する
Ti₂N MXene 양자점 및 g-C₃N₄ 양자점과 교잡함으로써 단일 WS₂ 의 자외선 흡수와 발광을 고도로 향상시킵니다
Al cruzarse con los puntos cuánticos Ti₂N mxene g−C₃N₄, se mejora altamente la absorción ultravioleta y la luminiscencia de una sola capa de WS₂
Absorption UV et Luminescence fortement améliorées de la monocouche WS₂ par hybridation avec les Quantum Dots Ti₂N MXene et g−C₃N₄
Благодаря скрещиванию с квантовыми точками Ti₂N MXene и g-C₃N₄, ультрафиолетовое поглощение и свет в однослойном WS₂ значительно улучшены
Anir S. Sharbirin, Rebekah E. Kong, Wendy B. Mato, Trang Thu Tran, Eunji Lee, Jolene W. P. Khor, Afrizal L. Fadli, Jeongyong Kim
Department of Energy Science, Sungkyunkwan University, Suwon 16419, Republic of Korea
Opto-Electronic Advances, 28 June 2024

Two-dimensional (2D) transition metal dichalcogenides (TMD) are atomically thin semiconductors with promising optoelectronic applications across the visible spectrum. However, their intrinsically weak light absorption and the low photoluminescence quantum yield (PLQY) restrict their performance and potential use, especially in ultraviolet (UV) wavelength light ranges. Quantum dots (QD) derived from 2D materials (2D/QD) provide efficient light absorption and emission of which energy can be tuned for desirable light wavelength.

In this study, we greatly enhanced the photon absorption and PLQY of monolayer (1L) tungsten disulfide (WS₂) in the UV range via hybridization with 2D/QD, particularly titanium nitride MXene QD (Ti₂N MQD) and graphitic carbon nitride QD (GCNQD). With the hybridization of MQD or GCNQD, 1L-WS₂ showed a maximum PL enhancement by 15 times with 300 nm wavelength excitation, while no noticeable enhancement was observed when the excitation photon energy was less than the bandgap of the QD, indicating that UV absorption by the QD played a crucial role in enhancing the light emission of 1L-WS₂ in our 0D/2D hybrid system.

Our findings present a convenient method for enhancing the photo-response of 1L-WS₂ to UV light and offer exciting possibilities for harvesting UV energy using 1L-TMD.
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