Exploring the Origin of High Dechlorination Activity in Polar Materials M2B5O9Cl (M = Ca, Sr, Ba, Pb) with Built-In Electric Field

Fan, Xiaoyun; Wu, Zhi Peng; Wang, Lichang; Wang, Chuanyi

doi:10.1021/acs.chemmater.6b04082

“…On the basis of the alignment of the above energy levels, we confirmed the possibility of the oxidation mechanism proposed in Figure 6. Generally, active species, including super radical anion• ( ), free hydroxyl radical• (OH), and photo-induced holes (ℎ ), are related to the photocatalytic degradation reaction [26]. Photo-induced electrons ( ) and holes (ℎ ) can transfer to the surface of crystals and then react with molecular oxygen (O2) and H2O molecules to produce superoxide radical anion (• ) and free hydroxyl radical (• OH), respectively.…”

Section: Resultsmentioning

confidence: 99%

High-Efficiency Visible Light Responsive Sulfide KSb5S8 Photocatalyst with a Layered Crystal Structure

Li

¹

,

Wu

²

,

Wang

³

et al. 2019

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The development of efficient photocatalysts for degrading environmental pollutants in wastewater has drawn considerable attention due to their great potential in industrial applications. Herein, we used a solvothermal method to prepare KSb5S8 with a layered crystal structure. The crystal structure of the as-synthesized samples was characterized by powder X-ray diffraction and transmission electron microscope imaging. Our UV-vis diffuse reflectance spectroscopy results indicated that KSb5S8 could absorb visible light, and its optical band gap was 1.62 eV. The photocatalytic activity of KSb5S8 was evaluated in the degradation of methyl orange. A degradation of 73% within 180 min was achieved under visible light irradiation, which was considerably higher than that of commercial P25 and g-C3N4. Theoretical calculations demonstrated that KSb5S8 was an indirect band gap semiconductor. The estimated effective mass of holes ( m h * ) was approximately two times greater than that of electrons ( m e * ) . The large ratio of m h * / m e * might promote separation of photo-induced carriers during the photocatalytic process. On the basis of the layered crystal structure and large m h * / m e * value, KSb5S8 was a high-performance photocatalyst capable of harvesting visible light. This study provides valuable insight that will aid the design of improved sulfide photocatalytic materials with layered crystal structures.

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“…Given the absence of symmetric centers in crystal structures,t he accumulation of microcosmic polarization from polar units of NCS materials can result in al arge macroscopic polarization as adriving force for charge transfer and separation, thus benefitting photocatalytic activity.N onlinear optical (NLO) materials with NCS crystal structures produce ap olarization electric field caused by an intrinsic dipole moment, and they were recently reported as efficient [10] K 3 B 6 O 10 X( X = Cl and Br), [11] Na 3 VO 2 B 6 O 11 , [12] M 2 B 5 O 9 Cl (M = Ca, Sr, Ba, Pb), [13] Bi 2 O 2 [BO 2 (OH)], [14] Ag 6 Si 2 O 7 , [15] and Ag 9 (SiO 4 ) 2 NO 3 . [16] wherem is the local dipole moment, n is the total number of electrons, e is the charge of an electron, andr is the difference between the "centroids" of the positive and negative charges.…”

Section: Macroscopic Polarization Promoted Bulk Charge Separationmentioning

confidence: 99%

The Role of Polarization in Photocatalysis

Chen

¹

,

Huang

²

,

Guo

³

et al. 2019

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Semiconductor photocatalysis as a desirable technology shows great potential in environmental remediation and renewable energy generation, but its efficiency is severely restricted by the rapid recombination of charge carriers in the bulk phase and on the surface of photocatalysts. Polarization has emerged as one of the most effective strategies for addressing the above‐mentioned issues, thus effectively promoting photocatalysis. This review summarizes the recent advances on improvements of photocatalytic activity by polarization‐promoted bulk and surface charge separation. Highlighted is the recent progress in charge separation advanced by different types of polarization, such as macroscopic polarization, piezoelectric polarization, ferroelectric polarization, and surface polarization, and the related mechanisms. Finally, the strategies and challenges for polarization enhancement to further enhance charge separation and photocatalysis are discussed.

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“…Given the absence of symmetric centers in crystal structures, the accumulation of microcosmic polarization from polar units of NCS materials can result in a large macroscopic polarization as a driving force for charge transfer and separation, thus benefitting photocatalytic activity. Nonlinear optical (NLO) materials with NCS crystal structures produce a polarization electric field caused by an intrinsic dipole moment, and they were recently reported as efficient photocatalysts: BiOIO 3 , BiOI 0.926 V 0.074 O 3 , Bi 2 O 2 (OH)(NO 3 ), K 3 B 6 O 10 X (X=Cl and Br), Na 3 VO 2 B 6 O 11 , M 2 B 5 O 9 Cl (M=Ca, Sr, Ba, Pb), Bi 2 O 2 [BO 2 (OH)], Ag 6 Si 2 O 7 , and Ag 9 (SiO 4 ) 2 NO 3 . The local dipole moment generated by this particular type of structure can be calculated from the Debye equation [Eq.…”

Section: Polarization‐promoted Bulk Charge Separationmentioning

confidence: 99%

The Role of Polarization in Photocatalysis

Chen

¹

,

Huang

²

,

Guo

³

et al. 2019

View full text Add to dashboard Cite

Semiconductor photocatalysis as a desirable technology shows great potential in environmental remediation and renewable energy generation, but its efficiency is severely restricted by the rapid recombination of charge carriers in the bulk phase and on the surface of photocatalysts. Polarization has emerged as one of the most effective strategies for addressing the above‐mentioned issues, thus effectively promoting photocatalysis. This review summarizes the recent advances on improvements of photocatalytic activity by polarization‐promoted bulk and surface charge separation. Highlighted is the recent progress in charge separation advanced by different types of polarization, such as macroscopic polarization, piezoelectric polarization, ferroelectric polarization, and surface polarization, and the related mechanisms. Finally, the strategies and challenges for polarization enhancement to further enhance charge separation and photocatalysis are discussed.

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Exploring the Origin of High Dechlorination Activity in Polar Materials M₂B₅O₉Cl (M = Ca, Sr, Ba, Pb) with Built-In Electric Field

Cited by 57 publications

References 48 publications

High-Efficiency Visible Light Responsive Sulfide KSb5S8 Photocatalyst with a Layered Crystal Structure

High-Efficiency Visible Light Responsive Sulfide KSb5S8 Photocatalyst with a Layered Crystal Structure

The Role of Polarization in Photocatalysis

The Role of Polarization in Photocatalysis

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