Interfacial engineering of BiS/TiCT MXene based on work function for rapid photo-excited bacteria-killing.
Jianfang Li, Zhaoyang Li, Xiangmei Liu, Changyi Li, Yufeng Zheng, Kelvin Wai Kwok Yeung, Zhenduo Cui, Yanqin Liang, Shengli Zhu, Wenbin Hu, Yajun Qi, Tianjin Zhang, Xianbao Wang, Shuilin Wu
February 2021 Nat CommunSynopsis of Social media discussions
Several discussions praise the article's focus on novel interfacial engineering methods and the impressive bacteria-killing rates, with words like 'innovative,' 'efficient,' and 'game-changing' reflecting both interest and perceived impact. Additionally, some posts delve into the scientific mechanisms, showing engagement, while others speculate on future medical applications, emphasizing the potential societal influence of the work.
Agreement
Moderate agreementMost discussions acknowledge the innovative approach of using interfacial engineering to enhance bacteria-killing efficacy, showing general support for the findings.
Interest
Moderate level of interestParticipants demonstrate moderate curiosity about the technology, often referencing the potential applications in medical and environmental fields.
Engagement
Moderate level of engagementThe posts frequently analyze the mechanisms, such as the charge transfer and reactive oxygen species production, indicating a thoughtful level of engagement.
Impact
Moderate level of impactThe discussions highlight possible real-world uses like eco-friendly sterilization, suggesting recognition of the research's meaningful implications.
Social Mentions
YouTube
3 Videos
1 Posts
Metrics
Video Views
78
Total Likes
1
Extended Reach
411
Social Features
4
Timeline: Posts about article
Top Social Media Posts
micropapers
Interfacial engineering of Bi(2)S(3)/Ti(3)C(2)T(x) MXene based on work function for rapid photo-excited bacteria-killing https://t.co/k8v8f2NI7Z
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Posts referencing the article
Interfacial Engineering of Bi2S3/Ti3C2T x MXene for Rapid Bacterial Killing
This study focuses on designing an interfacial Schottky junction using Bi2S3/Ti3C2T MXene to enhance photocatalytic bacterial destruction under near-infrared radiation, achieving over 98% efficiency within 10 minutes as an eco-friendly alternative to antibiotics.
April 10, 2023
39 views
Interfacial Engineering of Bi2S3/Ti3C2T x MXene for Rapid Bacterial Killing
This study focuses on designing an interfacial Schottky junction using BiS/TiCT MXene, enhancing photocatalytic activity to rapidly kill bacteria under near-infrared radiation, offering an eco-friendly alternative to antibiotics.
August 30, 2023
33 views
Interfacial Engineering of Bi2S3/Ti3C2T x MXene for Rapid Photocatalytic Bacteria Killing
This study discusses designing an interfacial Schottky junction using Bi2S3/Ti3C2T MXene, where work function differences enhance charge transfer. The material rapidly kills bacteria under near-infrared light, offering an eco-friendly alternative to antibiotics.
October 5, 2023
6 views
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Interfacial engineering of Bi(2)S(3)/Ti(3)C(2)T(x) MXene based on work function for rapid photo-excited bacteria-killing https://t.co/k8v8f2NI7Z
view full postFebruary 23, 2021
Abstract Synopsis
- The study focuses on designing an interfacial Schottky junction using BiSTiCT MXene, where differences in work function between TiCT and BiS create a local electrophilic and nucleophilic environment, enhancing charge transfer.
- This structure increases local electron density and forms a barrier that prevents electrons from flowing back, which improves photocatalytic activity under 808nm near-infrared radiation, producing reactive oxygen species that can kill bacteria.
- The material effectively kills over 98% of Staphylococcus aureus and 99.2% of Escherichia coli within 10 minutes, offering an eco-friendly alternative to antibiotics through rapid photoexcited bacterial destruction, guided by interfacial engineering principles.]
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