Synergistic Plasmonic Responses of Multi-Shaped Au Nanostructures Hybridized with Few-Layer WS₂ Nanosheets for Organic Solar Cells

Abstract: Raising the photocurrent and successively achieving a high power conversion efficiency (PCE) in organic solar cells (OSCs) with physically thin photoactive layers is usually a highly challenging task because of their excitonic nature. Herein, we utilized the synergistic plasmonic effects of multi-shaped Au nanostructures (diameter/edge length ∼50 nm) hybridized with few-layer WS 2 nanosheets in improving the photocurrent of fullerene and non-fullerene-based OSCs. A PCE enhancement of more than 15% and an exter… Show more

“…2,14,15 The current research scenario is focused on addressing these challenges to improve the performance and stability of OSCs. 16−20 With regards to the electron transport layer (ETL) materials, such as conjugated and nonconjugated polymers, 21−23 organic small molecules, 24,25 and transition metal oxides, 26,27 interface engineering for the manipulation of the internal built-in potential using novel molecules and 2D materials 28−30 has exhibited efficient performance in OSCs due to their excellent optical and electronic properties. However, very few reports are available for the hole transport layer (HTL); therefore, a significant finding for HTLs instead of ETLs is still needful.…”

“…Solution-processed organic solar cells (OSCs), with their unique features of low weight, flexibility, semitransparency, and inexpensive manufacturing techniques, enable the development of the most promising energy technology for applications such as portable electronics, wearable devices, and building-integrated photovoltaics. − The power conversion efficiencies (PCEs) of the state-of-the-art OSCs have been boosted to over 19% in recent years due to the development of novel conjugated wide band gap polymer donors and narrow band gap nonfullerene acceptors (NFAs) for the active layer. − In contrast to the outstanding achievements on absorbing layer systems, research on transport layers is far behind. Besides, the long-term sustainability of OSCs remains a challenge. ,, The current research scenario is focused on addressing these challenges to improve the performance and stability of OSCs. − With regards to the electron transport layer (ETL) materials, such as conjugated and nonconjugated polymers, − organic small molecules, , and transition metal oxides, , interface engineering for the manipulation of the internal built-in potential using novel molecules and 2D materials − has exhibited efficient performance in OSCs due to their excellent optical and electronic properties. However, very few reports are available for the hole transport layer (HTL); therefore, a significant finding for HTLs instead of ETLs is still needful .…”

Solution-Processed Co₃O₄-Based Hole Transport Layer for Nonfullerene Organic Solar Cells

“…2,14,15 The current research scenario is focused on addressing these challenges to improve the performance and stability of OSCs. 16−20 With regards to the electron transport layer (ETL) materials, such as conjugated and nonconjugated polymers, 21−23 organic small molecules, 24,25 and transition metal oxides, 26,27 interface engineering for the manipulation of the internal built-in potential using novel molecules and 2D materials 28−30 has exhibited efficient performance in OSCs due to their excellent optical and electronic properties. However, very few reports are available for the hole transport layer (HTL); therefore, a significant finding for HTLs instead of ETLs is still needful.…”

“…Solution-processed organic solar cells (OSCs), with their unique features of low weight, flexibility, semitransparency, and inexpensive manufacturing techniques, enable the development of the most promising energy technology for applications such as portable electronics, wearable devices, and building-integrated photovoltaics. − The power conversion efficiencies (PCEs) of the state-of-the-art OSCs have been boosted to over 19% in recent years due to the development of novel conjugated wide band gap polymer donors and narrow band gap nonfullerene acceptors (NFAs) for the active layer. − In contrast to the outstanding achievements on absorbing layer systems, research on transport layers is far behind. Besides, the long-term sustainability of OSCs remains a challenge. ,, The current research scenario is focused on addressing these challenges to improve the performance and stability of OSCs. − With regards to the electron transport layer (ETL) materials, such as conjugated and nonconjugated polymers, − organic small molecules, , and transition metal oxides, , interface engineering for the manipulation of the internal built-in potential using novel molecules and 2D materials − has exhibited efficient performance in OSCs due to their excellent optical and electronic properties. However, very few reports are available for the hole transport layer (HTL); therefore, a significant finding for HTLs instead of ETLs is still needful .…”

Solution-Processed Co₃O₄-Based Hole Transport Layer for Nonfullerene Organic Solar Cells

“…In the last few years, the power conversion efficiency (PCE) of organic solar cells (OSCs) has been triggered mainly due to the development of novel wide-bandgap conjugated polymers and low-bandgap non-fullerene acceptors (NFAs), active layer morphology optimization, device interface engineering and utilization of various novel nanomaterials. [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19] Several research groups have reported PCEs of more than 19% in single bulk OSCs. [20][21][22][23][24][25][26] Although high-performance devices have been frequently demonstrated, their PCE and open-circuit voltage (V OC ) still lag behind those of other competing technologies such as Si, GaAs, and perovskite solar cells.…”

Machine-learning-guided prediction of photovoltaic performance of non-fullerene organic solar cells using novel molecular and structural descriptors

Gold nanostructures/quantum dots for the enhanced efficiency of organic solar cells