Efficacious performance of photoactive electrode In:SnO2/Er2S3:In2S3 in a photoelectrochemical system

Gul, Mahwash Mahar; Ahmad, Khuram Shahzad; Thomas, Andrew G.; Ali, Daoud

doi:10.1016/j.apmt.2023.101797

Cited by 13 publications

(9 citation statements)

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“…Notably, according to excellent specific capacitance values, this research has demonstrated the exceptional performance of metal sulfides in supercapacitance. 21 The results of these experiments highlight the potential of metal sulfides, especially bi compositions, as prospective contenders for improving energy storage and conversion technologies. Metal sulfides' remarkable electrochemical qualities open the door for the creation of effective and high-performance devices, which will help to meet the rising demand for sustainable and clean energy solutions.…”

Section: Introductionmentioning

confidence: 88%

“…19 The potential of metal sulfides in solar cells, photocatalytic water splitting, and electrochemical energy storage systems like batteries and supercapacitors has been the subject of several investigations. 20 Bi-metal sulfide thin films have been the subject of synthesis and characterization research that has shed important light on their electrochemical characteristics, which have been evaluated using methods like cyclic voltammetry. Notably, according to excellent specific capacitance values, this research has demonstrated the exceptional performance of metal sulfides in supercapacitance.…”

Section: Introductionmentioning

confidence: 99%

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Advancing energy and water solutions: Unleashing the potential of Nd₂S₃:Ni₉S₈ thin film for supercapacitors and sustainable water purification

Gul,

Ahmad,

Thomas

et al. 2023

Asia-Pacific J Chem Eng

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The research was done on the creation and use of bi‐metal sulfide thin film, Nd2S3:Ni9S8. 41 nm‐sized crystallites with 80% crystallinity were found in the material. The evaluated optical characteristics showed a 2.9 eV band gap energy. The presence of Nd3d, S2p, and Ni2p in the created material was confirmed by X‐ray photoelectron spectroscopy. Voltammetry tests were carried out to assess the electrochemical characteristics. With a value of 750 Fg−1, the findings obtained showed remarkable supercapacitive capability. Additionally, a thorough examination was done to learn more about the material's potential as a photocatalyst. Malachite green dye, fuberidazole, and phenol were used as environmental contaminants to test the thin films' photocatalytic degradation effectiveness. The highest degradation was found for fuberidazole with a rate constant of 2.46x10−2 min−1. The results demonstrated the versatility of thin films and their efficacy in degrading these pollutants, highlighting their potential for environmental remediation applications.

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Section: Introductionmentioning

confidence: 88%

Section: Introductionmentioning

confidence: 99%

Advancing energy and water solutions: Unleashing the potential of Nd₂S₃:Ni₉S₈ thin film for supercapacitors and sustainable water purification

Gul,

Ahmad,

Thomas

et al. 2023

Asia-Pacific J Chem Eng

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“…The distinctive characteristics of metal sulfides have positioned them as highly desirable materials with significant potential for technological advancements in various applications [16]. Synthesis and characterization studies, with a specific focus on trimetallic sulfide thin films, have provided valuable insights into their electrochemical properties, which have been evaluated utilizing techniques such as cyclic voltammetry (CV; [17]). Remarkably, investigations into metal sulfides have demonstrated their exceptional supercapacitive performance, as indicated by notable specific capacitance values [18].…”

Section: Introductionmentioning

confidence: 99%

Transforming energy and water landscapes with MnS₂:Ni₉S₈:Co₃S₄: A promising paradigm for a sustainable future

Gul,

Ahmad,

Thomas

et al. 2024

J Chinese Chemical Soc

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BackgroundConsiderable research efforts have been dedicated to comprehensively evaluate the electrochemical and photocatalytic properties of newly synthesized metal sulfides.AimsThis research aims to determine the viability of using metal sulfide, MnS2:Ni9S8:Co3S4 thin film with excellent energy retention capacities and amazing photocatalytic activities.Materials & MethodsSingle source precursor method was utilized for the synthesis of metal sulfide. Furthermore, deposition of thin film was performed through physical vapour deposition route. Detailed characterization was done by using UV‐visible spectrophotometry, Fourier transform infrared spectroscopy, scanning electron microscopy, X‐ray diffraction crystallography and X‐ray photoelectron spectroscopy. Electrochemical investigation was done through cyclic and linear sweep voltammetry while competence of the thin film in degrading various environmental pollutants, including crystal violet dye, fuberidazole and phenol, was evaluated by photocatalytic degradation.Results & DiscussionA crystallite size of 47 nm with 86.5% crystallinity was found along with a 3.4 eV bandgap energy. Round‐edged cubical structures in the composite were seen. X‐ray photoelectron spectroscopy revealed core level peaks of Mn 2p, Ni 2p, Co 2p and S 2p. A specific capacitance of 590 Fg−1 was observed from the electrochemical analysis showing the presence of electroactive sites that allow for effective electrochemical processes. After 60 minutes of exposure to the thin film, phenol showed the slowest rate of degradation, whereas crystal violet and fuberidazole showed significant percentages of deterioration.ConclusionThe findings highlight MnS2:Ni9S8:Co3S4 thin film's adaptability as viable compound for addressing the critical concerns of storing energy, production, and environmental cleanup. These significant findings highlight the versatility of tri‐metal sulfide thin films, opening up avenues for further research and technological advancements.

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“…[ 18 ] Widespread researches are conducted to discover the capabilities of metal sulfides in energy conversion such as photovoltaic cells and photocatalytic water splitting as well as electrochemical energy‐storage devices, such as batteries and supercapacitors. [ 19 ] Research on metal sulfides has demonstrated remarkable supercapacitive performance, as evidenced by significant specific capacitance values. [ 20 ] These findings underscore the probable significant applications of metal sulfides, particularly bimetallic configurations, as promising candidates for advancing energy‐conversion and energy‐storage systems.…”

Section: Introductionmentioning

confidence: 99%

Exploring the Photocatalytic and Supercapacitive Potential of CuZr₂S₄ Thin Films: A Key to Cleaner and Safer Environments

Gul,

Ahmad,

Thomas

et al. 2024

Physica Status Solidi (a)

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In this research, an extensive exploration of bimetallic sulfide, CuZr2S4, is delved into. It involves the utilization of diethyldithiocarbamate as a sulfur source. The resulting thin film exhibits a well‐defined crystalline structure, characterized by an average crystallite size of 33 nm, indicating a commendable crystallinity of 87%. Bandgap energy through optical characterization is unveiled to be 2.5 eV, shedding light on the metal sulfide optical behavior. Furthermore, the elemental composition and chemical bonding of the thin film are elucidated using X‐ray photoelectron spectroscopy, revealing distinctive core‐level peaks associated with Cu 2p, Zr 3d, and S 2p. Electrochemical evaluations employing voltammetry measurements showcase remarkable specific capacitive performance, achieving an impressive value of 479 Fg−1. The thin film demonstrates exceptional stability over multiple cycles, underscoring its immense potential for diverse energy‐storage applications. A thorough assessment of the synthesized material's photocatalytic capabilities, namely its ability to degrade several types of environmental contaminants, is conducted.

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Efficacious performance of photoactive electrode In:SnO2/Er2S3:In2S3 in a photoelectrochemical system

Cited by 13 publications

References 61 publications

Advancing energy and water solutions: Unleashing the potential of Nd₂S₃:Ni₉S₈ thin film for supercapacitors and sustainable water purification

Advancing energy and water solutions: Unleashing the potential of Nd₂S₃:Ni₉S₈ thin film for supercapacitors and sustainable water purification

Transforming energy and water landscapes with MnS₂:Ni₉S₈:Co₃S₄: A promising paradigm for a sustainable future

Exploring the Photocatalytic and Supercapacitive Potential of CuZr₂S₄ Thin Films: A Key to Cleaner and Safer Environments

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Efficacious performance of photoactive electrode In:SnO2/Er2S3:In2S3 in a photoelectrochemical system

Cited by 13 publications

References 61 publications

Advancing energy and water solutions: Unleashing the potential of Nd2S3:Ni9S8 thin film for supercapacitors and sustainable water purification

Advancing energy and water solutions: Unleashing the potential of Nd2S3:Ni9S8 thin film for supercapacitors and sustainable water purification

Transforming energy and water landscapes with MnS2:Ni9S8:Co3S4: A promising paradigm for a sustainable future

Exploring the Photocatalytic and Supercapacitive Potential of CuZr2S4 Thin Films: A Key to Cleaner and Safer Environments

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Product

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Advancing energy and water solutions: Unleashing the potential of Nd₂S₃:Ni₉S₈ thin film for supercapacitors and sustainable water purification

Advancing energy and water solutions: Unleashing the potential of Nd₂S₃:Ni₉S₈ thin film for supercapacitors and sustainable water purification

Transforming energy and water landscapes with MnS₂:Ni₉S₈:Co₃S₄: A promising paradigm for a sustainable future

Exploring the Photocatalytic and Supercapacitive Potential of CuZr₂S₄ Thin Films: A Key to Cleaner and Safer Environments