High‐efficiency Sb2S3‐based hybrid solar cell at low light intensity: cell made of synthesized Cu and Se‐doped Sb2S3

Janošević, Valentina; Mitrić, Miodrag; Bundaleski, Nenad; Rakočević, Zlatko Lj.; Validžić, Ivana Lj.

doi:10.1002/pip.2724

Cited by 32 publications

(36 citation statements)

References 48 publications

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“…Therefore, to increase the carrier concentration (the electrical conductivity) and improve the performance of Sb 2 S 3 ‐based solar cells, extrinsic doping becomes necessary for passivating the detrimental recombination center defects and producing more carriers. In the past decade, many experiments tried to dope the Sb 2 S 3 to increase the conductivity . However, the efficiency has not witnessed apparent increase (stagnating at 7.5% in the past 5 years).…”

Section: Resultsmentioning

confidence: 99%

“…In the past decade, many experiments tried to dope the Sb 2 S 3 to increase the conductivity. [6,15,[42][43][44][45] However, the efficiency has not witnessed apparent increase (stagnating at 7.5% in the past 5 years). This means increasing the conductivity of Sb 2 S 3 through the direct doping is quite difficult, which is easy to understand because the extremely low formation energy (high concentration) of dominant intrinsic donor V S2 and acceptor V Sb2 in Figure 5 can restrain the efficient external doping in intrinsic Sb 2 S 3 .…”

Section: A Two-step Strategy For Efficient P-type Doping and Overcomimentioning

confidence: 99%

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Intrinsic Defect Limit to the Electrical Conductivity and a Two‐Step p‐Type Doping Strategy for Overcoming the Efficiency Bottleneck of Sb₂S₃‐Based Solar Cells

2019

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The photovoltaic efficiency increase in Sb2S3‐based solar cells has stagnated for 5 years since the highest efficiency of 7.5% was achieved in 2014. One important bottleneck is the high electrical resistivity of Sb2S3. The first‐principle calculations reveal that the high‐resistivity results from the compensation between the intrinsic donor VS and acceptors VSb, SbS, and SSb which have comparably high concentration (low formation energy). The compensation also limits the improvement of conductivity through direct extrinsic doping. Further calculations of O dopants show that OS has low formation energy, so the dominant intrinsic donor VS can be passivated by O and thus the p‐type doping limit imposed by VS can be overcome. Meanwhile, other p‐type limiting and recombination‐center donor defects can be suppressed under the S‐rich condition, which explains why the highest efficiency is achieved in O‐doped Sb2S3 after sulfurization. Given the unexpected beneficial effects of O doping and sulfurization, a two‐step doping strategy is proposed for overcoming the efficiency bottleneck: 1) use O to passivate the VS and S‐rich condition to suppress other detrimental defects, making p‐type doping feasible and minority carrier lifetime long; 2) introduce other p‐type dopants to increase hole carrier concentration.

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Section: Resultsmentioning

confidence: 99%

Section: A Two-step Strategy For Efficient P-type Doping and Overcomimentioning

confidence: 99%

Intrinsic Defect Limit to the Electrical Conductivity and a Two‐Step p‐Type Doping Strategy for Overcoming the Efficiency Bottleneck of Sb₂S₃‐Based Solar Cells

2019

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“…For Sb 2 S 3 ‐based hybrid solar cell, 3 different Sb 2 S 3 powders (p‐, undoped‐, and n‐ Sb 2 S 3 ) were synthesized and their detail experimental procedure has been described in previous studies …”

Section: Methodsmentioning

confidence: 99%

“…Mostly, the thin films that are made from Sb 2 S 3 were derived from solutions depending on whether dye sensitized or photo‐electrochemical solar cells were made . Recently, we reported synthesis for producing amorphous and crystalline, doped and undoped Sb 2 S 3 powders with excellent electronic properties, ie, convenient band gap . Only Mokurala et al synthesized crystalline Sb 2 S 3 nanorods using antimony trichloride, oleylamine, thiourea, hexanethiol acetone, and toluene, by hot‐injection technique and applied it in solar cell .…”

Section: Introductionmentioning

confidence: 99%

“…The construction of solar cell device consists of a transparent electrode, indium tin oxide (ITO); absorber material, semiconductor Sb 2 S 3 ; conductive polymers PANI and P3HT; layer for electron conduction, TiO 2 ; chitosan (CS)/polyethylene glycol (PEG)/electrolyte blend and aluminum as counter electrode. In the literature, different inorganic and organic hole conducting materials were used . For fabrication of described solar cell, we used polymers P3HT and PANI.…”

Section: Introductionmentioning

confidence: 99%

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Efficient and novel Sb₂ S₃ based solar cells with chitosan/poly(ethylene glycol)/electrolyte blend

et al. 2017

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Summary We present here a novel solar cell made of ITO/composite p‐doped Sb2S3 + P3HT + PANI+TiO2/amorphous Sb2S3 + P3HT + PANI + TiO2/n‐doped Sb2S3 + P3HT + PANI + TiO2/solid carrier/aluminum as counter electrode. With spraying technique, the layers were deposited and the thickness of films was 1 μm. A new solid carrier of electrolyte was a blend consisted of chitosan (low MW), polyethylene glycol and electrolyte. X‐ray diffraction was recorded to confirm the amorphous nature of the blend. Information about the surface appearance and roughness of a solid carrier dry and soaked in the electrolyte was given by atomic force microscopy. The solar cell was examined at very low and low light intensity (5% and 35% of sun, respectively), and at standard test conditions (100% of sun) using different light sources. The whole cell surface was 7.5 cm2 while the illuminated part was 3 cm2. Obtained results expressed for the illuminated surface showed the highest efficiency of 23.1% at 5% of sun while the efficiency of the cell was 2.9% at 35% of sun and only 0.75% at intensity of 100% of sun.

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Enhancing potassium‐ion storage of Bi₂S₃ through external–internal dual synergism: Ti₃C₂T_x compositing and Cu²⁺ doping

Sha,

You,

et al. 2024

Carbon Energy

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Potassium‐ion batteries (PIBs) offer a cost‐effective and resource‐abundant solution for large‐scale energy storage. However, the progress of PIBs is impeded by the lack of high‐capacity, long‐life, and fast‐kinetics anode electrode materials. Here, we propose a dual synergic optimization strategy to enhance the K+ storage stability and reaction kinetics of Bi2S3 through two‐dimensional compositing and cation doping. Externally, Bi2S3 nanoparticles are loaded onto the surface of three‐dimensional interconnected Ti3C2Tx nanosheets to stabilize the electrode structure. Internally, Cu2+ doping acts as active sites to accelerate K+ storage kinetics. Various theoretical simulations and ex situ techniques are used to elucidate the external–internal dual synergism. During discharge, Ti3C2Tx and Cu2+ collaboratively facilitate K+ intercalation. Subsequently, Cu2+ doping primarily promotes the fracture of Bi2S3 bonds, facilitating a conversion reaction. Throughout cycling, the Ti3C2Tx composite structure and Cu2+ doping sustain functionality. The resulting Cu2+‐doped Bi2S3 anchored on Ti3C2Tx (C‐BT) shows excellent rate capability (600 mAh g–1 at 0.1 A g–1; 105 mAh g–1 at 5.0 A g–1) and cycling performance (91 mAh g–1 at 5.0 A g–1 after 1000 cycles) in half cells and a high energy density (179 Wh kg–1) in full cells.

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High‐efficiency Sb₂S₃‐based hybrid solar cell at low light intensity: cell made of synthesized Cu and Se‐doped Sb₂S₃

Cited by 32 publications

References 48 publications

Intrinsic Defect Limit to the Electrical Conductivity and a Two‐Step p‐Type Doping Strategy for Overcoming the Efficiency Bottleneck of Sb₂S₃‐Based Solar Cells

Intrinsic Defect Limit to the Electrical Conductivity and a Two‐Step p‐Type Doping Strategy for Overcoming the Efficiency Bottleneck of Sb₂S₃‐Based Solar Cells

Efficient and novel Sb₂ S₃ based solar cells with chitosan/poly(ethylene glycol)/electrolyte blend

Enhancing potassium‐ion storage of Bi₂S₃ through external–internal dual synergism: Ti₃C₂T_x compositing and Cu²⁺ doping

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High‐efficiency Sb2S3‐based hybrid solar cell at low light intensity: cell made of synthesized Cu and Se‐doped Sb2S3

Cited by 32 publications

References 48 publications

Intrinsic Defect Limit to the Electrical Conductivity and a Two‐Step p‐Type Doping Strategy for Overcoming the Efficiency Bottleneck of Sb2S3‐Based Solar Cells

Intrinsic Defect Limit to the Electrical Conductivity and a Two‐Step p‐Type Doping Strategy for Overcoming the Efficiency Bottleneck of Sb2S3‐Based Solar Cells

Efficient and novel Sb2 S3 based solar cells with chitosan/poly(ethylene glycol)/electrolyte blend

Enhancing potassium‐ion storage of Bi2S3 through external–internal dual synergism: Ti3C2Tx compositing and Cu2+ doping

Contact Info

Product

Resources

About

High‐efficiency Sb₂S₃‐based hybrid solar cell at low light intensity: cell made of synthesized Cu and Se‐doped Sb₂S₃

Intrinsic Defect Limit to the Electrical Conductivity and a Two‐Step p‐Type Doping Strategy for Overcoming the Efficiency Bottleneck of Sb₂S₃‐Based Solar Cells

Intrinsic Defect Limit to the Electrical Conductivity and a Two‐Step p‐Type Doping Strategy for Overcoming the Efficiency Bottleneck of Sb₂S₃‐Based Solar Cells

Efficient and novel Sb₂ S₃ based solar cells with chitosan/poly(ethylene glycol)/electrolyte blend

Enhancing potassium‐ion storage of Bi₂S₃ through external–internal dual synergism: Ti₃C₂T_x compositing and Cu²⁺ doping