Innovation | Action | Excellence
Flying with Light

xenon light source氙灯

PLS-SXE300D/300DUV Xenon lamp source


PLS-SXE300D/300DUV Xenon lamp source
  • Introduction
  • Application
  • Literature
  • Maintenance

Key Features

● Utilizes professional imported power supplies, featuring low ripple, stability, and reliability, effectively extending the lifespan of the light source;

● Non-metallic lamp box helps to some extent in avoiding electrical safety risks in the laboratory;

● Compact structure with a small footprint, minimizing the requirements for experimental space;

● Patented axial air suction heat dissipation structure ensures effective cooling of the lamp box.


Application Areas

▲ Particularly Suitable    ● Moderately Suitable   ○ Can be Used

▲ Photocatalytic decomposition of water to produce hydrogen/oxygen     ▲ Photocatalytic full decomposition of water       ▲ Photocatalytic CO₂ reduction         ▲ Photodegradation of gaseous pollutants (e.g., VOCs, formaldehyde, nitrogen oxides, sulfur oxides, etc.)

● Photodegradation of liquid pollutants (e.g., dyes, benzene, and benzene derivatives)

○ Photoelectrochemical (PEC) experiments         ○ Photochromism          ○ Photosynthesis         ○ Membrane photocatalysis


Light Output Characteristics

● Total optical power: 50 W;

● Spectral range: 320~780 nm, extendable to 2500 nm;

● Compatible with filters: ultraviolet, visible, near-infrared, and narrowband;

● Light source emission angle: an average of 6°;

● Light spot diameter: Illumination distance 30~60 mm;


Light Source Stability

● Long-term irradiation instability: ≤±3%;

● Centralized digital power management control based on a micro-CPU;

● Original imported switch power supply, long bulb life, stable light source;

● Optional PLS-LA320A Xenon Lamp Light Source Homogenizer;


Control Mode

● Operating mode: Program control mode;

● Current limit value: 21 A;

● Bulb (consumable) lifespan: >1000 h (meets the light intensity requirements under normal photocatalysis conditions);

● Trigger mode: Integrated high-voltage trigger (two-stage voltage with no high-voltage transmission);



● Lamp-box-power connection cable without high-voltage transmission characteristics, fan failure protection, fan shutdown delay, overload and overcurrent automatic power-off protection;

● A heat dissipation structure based on integrated xenon lamp;


Basic Parameters

● Bulb power: 300 W;

● Power adjustment range: 150 W~300 W;

● Power ripple: 200 mVp-p (peak-to-peak) LED digital current display;


Representative References

PLS-SXE300D Light Source cited by Zhao Yufei's research group at Beijing University of Chemical Technology.png

PLS-SXE300D Light Source cited by Yin Shuangfeng's research group at Hunan University.png

PLS-SXE300D Light Source cited by East China University of Science and Technology.png

PLS-SXE300D Xenon Lamp Light Source cited by Liu Chao's team at East China Normal University.png

PLS-SXE300D Light Source cited by Lu Xiaoquan's team.png

PLS-SXE300D Xenon Lamp Light Source cited by Zhengzhou University Henan Advanced Technology Research Institute.png

PLS-SXE300D Light Source cited by Zhang Tierui's team at the Institute of Chemistry, Chinese Academy of Sciences.png

PLS-SXE300D Light Source cited by Zhang Tierui's team at the Institute of Chemistry, Chinese Academy of Sciences (1).png

PLS-SXE300D Light Source Quoted by Zhang Dou's Team at Central South University

PLS SXE300DUV Xenon Lamp Light Source Quoted by Academician Tang Junwang's Team at the European Academy of Sciences

PLS SXE300D Xenon Lamp Light Source Quoted by Zhang Gaoke's Team at Wuhan University of Technology

PLS SXE300D Xenon Lamp Light Source Quoted by Yu Jimui's Team at the Chinese University of Hong Kong

  • Photocatalytic Hydrogen/Oxygen Production from Water
  • Photocatalytic Complete Water Splitting
  • Photocatalytic CO2 Reduction
  • Photodegradation of Gaseous Pollutants
  • Photodegradation of Liquid Pollutants
  • PEC (Photoelectrochemical) Water Splitting
  • Photoinduced Color Change
  • Photosynthesis
  • Membrane Photocatalysis
  • [1] Wang Zhuangzhuang, Zhang Gaoke. Carbon dots modified bismuth antimonate for broad spectrum photocatalytic degradation of organic pollutants:Boosted charge separation, DFT calculations and mechanism unveiling. Chemical Engineering Journal, 2021, 418: 129460.
  • [2] Ji Jiahui, Xing Mingyang. Tuning redox reactions via defects on CoS2-xfor sustainable degradation of organic pollutants. Angewandte Chemie International Edition, 2021, 60:2903-2908.
  • [3]Li Jun. Interfacial engineering of Bi19Br3S27 Nanowires promotes metallic photocatalytic CO2 reduction activity under near-infrared light irradiation. Journal of the American Chemical Society2021, 143: 6551-6559.
  • [4]Liu Chao, Yu Chengzhong. Ternary MOF-on-MOF heterostructures with controllable architectural and compositional complexity via multiple selective assembly. Nature Communications2020, 11: 4971.
  • [5] Ning Xingming, Lu Xiaoquan. Plasmon‐enhanced charge separation and surface reactions based on Ag‐loaded transition‐metal hydroxide for photoelectrochemical water oxidation. Advanced Energy Materials, 2021, 11: 2100405.
  • [6] Pan Jinbo, Yin Shuangfeng. Activity and stability boosting of an oxygen-vacancy-rich BiVO4 photoanode by NiFe-MOFs thin layer for water oxidation. Angewandte Chemie International Editionl2021, 60: 1433-1440.
  • [7] Wang Jigeng, Zhao Yufei. Highly selective photo-hydroxylation of phenol using ultrathin NiFe-layered double hydroxide nanosheets under visible-light up to 550 nm. Green Chemistry, 2020, 22: 8604-8613.
  • [8] Xiao Kemeng, Wong Pokeung. Wong Po Keung. Interfacing iodine-doped hydrothermally carbonized carbon with escherichia coli through an“Add-on” mode for enhanced light-driven hydrogen production. Advanced Energy Materials2021, 11: 2100291.
  • [9] Zong, Xupeng, Sun Zaicheng. Constructing creatinine-derived moiety as donor block for carbon nitride photocatalyst with extended absorption and spatial charge separation. Applied Catalysis B: Environmental2021, 291: 120099.
  • [10] J. Yuan, X. Yi, Y. Tang, et al., Efficient Photocatalytic Nitrogen Fixation: Enhanced Polarization, Activation, and Cleavage by Asymmetrical Electron Donation to NN Bond, Advanced Functional Materials, 2019, 30, 1906983.
  • [11] S. Chen, Z. Sun, W. Xiang, et al., Plasmonic wooden flower for highly efficient solar vapor generation, Nano Energy, 2020, 76, 104998.
  • [12] Y. Song, H. Wang, Z. Wang, et al., Selective Photocatalytic Synthesis of Haloanilines from Halonitrobenzenes over Multifunctional AuPt/Monolayer Titanate Nanosheet, ACS Catalysis, 2018, 8, 9656-9664.
  • [13] Ming-Yu Qi, Yue-Hua Li, Masakazu Anpo, Zi-Rong Tang, and Yi-Jun Xu*,Efficient Photoredox-Mediated C–C Coupling Organic Synthesis andHydrogen Production over Engineered Semiconductor Quantum Dots, ACS Catalysis, 2020, 10, 14327–14335.
  • [14] Jin-Bo Pan,Bing-Hao Wang,Jin-Bo Wang,Hong-Zhi Ding,Wei Zhou,Xuan Liu,Jin-Rong Zhang,Dr. Sheng Shen,Dr. Jun-Kang Guo,Dr. Lang Chen,Prof. Dr. Chak-Tong Au,Prof. Dr. Li-Long Jiang,Prof. Dr. Shuang-Feng Yin,Activity and Stability Boosting of an Oxygen-Vacancy-Rich BiVO4 Photoanode by NiFe-MOFs Thin Layer for Water Oxidation,Angewandte Chemie International Edition, DOI: 10.1002/anie.202012550.
  • [15] Jikang Wang, Yanqi Xu, Jiaxin Li, Xiaodong Ma, Si-Min Xu, Rui Gao, Yufei Zhao * and Yu-Fei Song.* Highly Selective Photo-hydroxylation of Phenol Using Ultrathin NiFe-layered Double Hydroxide Nanosheets under Visible-light up to 550 nm. Green Chem., 2020, DOI: 10.1039/d0gc02786c.
  • [16] Wei Bi, et al, Revealing the Sudden Alternation in Pt@h-BN Nanoreactors for Nearly 100% CO2-to-CH4 Photoreduction, Adv. Funct. Mater. 2021
  • [17] Liu C, Mao S, Wang H, et al. Peroxymonosulfate-assisted for facilitating photocatalytic degradation performance of 2D/2D WO3/BiOBr S-scheme heterojunction[J]. Chemical Engineering Journal, 2022, 430: 132806.
  • [18] Yang, Lang, et al. "Photo-thermal synergy for boosting photo-Fenton activity with rGO-ZnFe2O4: Novel photo-activation process and mechanism toward environment remediation." Applied Catalysis B: Environmental 292 (2021): 120198.
  • [19] Liu Qiong., Zhai Di., Xiao Zhida., Tang Chen., Sun Qiwei., Luo Hang., Zhang Dou. Piezo-photoelectronic coupling effect of BaTiO3@TiO2 nanowires for highly concentrated dye degradation. Nano Energy. 2022; 92. 
  • [20] ShanshanLiu, HeyuanLiu, LiShen, ZuoxuXiao, YujiaHu,JunZhou, XiangyangWang, ZhaobinLiu, ZhiLi, XiyouLi, Applying triplet-triplet annihilation upconversion in degradation of oxidized lignin model with good selectivity,Chemical Engineering Journal,10.1016/j.cej.2021.133377
  • [21] Jin Ye, Jiating Xu, Chunsheng Li, et al. Novel N-Black In2O3-x/InVO4 heterojunction for efficient photocatalytic fixation: Synergistic effect of exposed (321) facet and oxygen vacancy, Journal of Materials Chemistry A, 2021, 9, 24600-24612.
  • [22] Qian Dong, Zhiwu Chen, Bo Zhao,Yizeng Zhang, Zhenya Lu, Xin Wang, Jinliang Li, Wei Chen. In situ fabrication of niobium pentoxide/graphitic carbon nitride type-II heterojunctions for enhanced photocatalytic hydrogen evolution reaction, Journal of Colloid and Interface Science, 608 (2022) 1951–1959.
  • [23] Zhiwen Wang, Huan Wang, Ling Wu, et. al. CuPd alloy decorated SnNb2O6 nanosheets as a multifunctional photocatalyst for semihydrogenation of phenylacetylene under visible light. Chemical Engineering Journal, 2021, 429, 132018. 
  • [24] Cooperative hydrogen production and C−C coupling organic synthesis in one photoredox cycle Applied Catalysis B: Environmental 2021, 120812.
  • [25] Yingzhang Shi, Huan Wang, Zhiwen Wang, Cheng Liu, Mingchuang Shen, Taikang Wu, Ling Wu*,Surface functionalized Pt/SnNb2O6 nanosheets for visible-light-driven the precise hydrogenation of furfural to furfuryl alcohol. Journal of Energy Chemistry 2022, 66, 566–575.
  • [26] Liu C, Mao S, Shi M, et al. Peroxymonosulfate activation through 2D/2D Z-scheme CoAl-LDH/BiOBr photocatalyst under visible light for ciprofloxacin degradation [J]. Journal of Hazardous Materials, 2021, 420:126613.
  • [27] Wang C, Liu N, et al. Fluoro-Substituted Covalent Organic Framework Particles Anchored on TiO2 Nanotube Arrays for Photoelectrochemical Determination of Dopamine. ACS Appl. Nano Mater. 2021.
  • [28] Zhenhua Li, Xin Zhang, Jinjia Liu, Run Shi,* Geoffrey I.N. Waterhouse, Xiao-Dong Wen, and Tierui Zhang*. Titania-Supported Ni2P/Ni Catalysts for Selective Solar-Driven CO Hydrogenation.
  • [29] Rongdi Tang, Daoxin Gong, Yaocheng Deng, Sheng Xiong, Jiangfu Zheng, Ling Li, Zhanpeng Zhou, Long Su, Jia Zhao,π-π stacking derived from graphene-like biochar/g-C3N4 with tunable band structure for photocatalytic antibiotics degradation via peroxymonosulfate activation,Journal of Hazardous Materials,10.1016/j.jhazmat.2021.126944
  • [30] Jin Ye, Jiating Xu, et. al, Efficient photocatalytic reduction of CO2 by a rhenium-doped TiO2-x/SnO2 inverse opal S-scheme heterostructure assisted by the slow-phonon effect. Separation and Purification Technology, 277, 2021, 119431 
  • [31] R. Tang, D. Gong, Y. Deng, S. Xiong, J. Deng et. al. π-π Stacked step-scheme PDI/g-C3N4/TiO2@Ti3C2 photocatalyst with enhanced visible photocatalytic degradation towards atrazine via peroxymonosulfate activation. Chem. Eng. J. 2022, 427, 131809 
  • [32] Chang-Long Tan, Ming-Yu Qi, Zi-Rong Tang, Yi-Jun Xu, Cocatalyst decorated ZnIn2S4 composites for cooperative alcohol conversion and H2evolution, Applied Catalysis B: Environmental, 2021, 298, 120541. 
  • [33] Zhao H, Li C F, Hu Z Y, et al. Size effect of bifunctional gold in hierarchical titanium oxide-gold-cadmium sulfide with slow photon effect for unprecedented visible-light hydrogen production. Journal of Colloid and Interface Science, 2021, 604: 131-139. 
  • [34] J. Shen, L. Qian, J. Huang, Y. Guo, Z. Zhang, Enhanced degradation toward Levofloxacin under visible light with S-scheme heterojunction In2O3/Ag2CO3 :Internal electric field, DFT calculation and degradation mechanism, Separation and Purification Technology 275 (2021). 
  • [35] Huang, Z.; Wan, Y.; Liang, J.; Xiao, Y.; Li, X.; Cui, X.; Tian, S.; Zhao, Q.; Li, S.; Lee, C.-S. ACS Applied Materials & Interfaces 2021.
  • [36] S. Bai, T. Li, et al., Scale-up synthesis of monolayer layered double hydroxide nanosheetsvia separate nucleation and aging steps method for efficient CO2 photoreduction. Chem. Eng. J., 2021, 419, 129390. 
  • [37] Z. Huang, J. Wei, Y. Wan, P. Li, J. Yu, J. Dong, S. Wang, S. Li, C.-S. Lee, Small, n/a, 2101487.2021, 564, 150432
  • [38] Xi Yamin, Zhang Xingwei, Shen Yue, et al. Aspect ratio dependent photocatalytic enhancement of CsPbBr3 in CO2 reduction with two-dimensional metal organic framework as a cocatalyst. Applied Catalysis B: Environmental 2021, 297, 120411.
  • [39] J.L. Zhang, H. Tao, S. Wu, J. Yang, M. Zhu, Enhanced durability of nitric oxide removal on TiO2 (P25) under visible light: Enabled by the direct Z-scheme mechanism and enhanced structure defects through coupling with C3N5, Appl. Catal. B-Environ., 296 (2021) 120372.
  • [40] Dan Yin, Xingming Ning, Peiyao Du*, Dongxu Zhang, Qi Zhang, Xiaoquan Lu*. Cascaded multiple-step hole transfer for enhancing photoelectrochemical water splitting. Appl. Catal. B: Environ. 2021, 296, 120313.
  • [41] Jun Li, Wenfeng Pan, Qiaoyun Liu*, Zhiquan Chen, Zhijie Chen, Xuezhen Feng, and Hong Chen*,Interfacial Engineering of Bi19Br3S27 Nanowires Promotes Metallic Photocatalytic CO2 Reduction Activity under Near-Infrared Light Irradiation,J. Am. Chem. Soc. 2021, 143, 17, 6551–6559
  • [42] Hang Xie, Yanmei Zheng, Xinli Guo, et al. Rapid Microwave Synthesis of Mesoporous Oxygen-Doped g-C3N4 with Carbon Vacancies for Efficient Photocatalytic H2O2 Production [J]. ACS Sustainable Chemistry & Engineering, 2021, 9, 19, 6788–6798.
  • [43] S.-H. Li, M.-Y. Qi, et. al. Modulating photon harvesting through dynamic non-covalent interactions for enhanced photochemical CO2 reduction. Appl. Catal., B 2021, 292, 120157.
  • [44] Xuejun Ren, Meichao Gao, Yanfeng Zhang*, Zizhong Zhang, Xingzhong Cao*, Baoyi Wang, Xuxu Wang*, Photocatalytic reduction of CO2 on BiOX:Effect of halogen element type and surface oxygen vacancy mediated mechanism. Applied Catalysis B: Environmental 274 (2020) 119063.
  • [45] Zhenhua Li, Run Shi, Jiaqi Zhao, and Tierui Zhang. Ni-based catalysts derived from layered-double-hydroxide nanosheets for efficient photothermal CO2 reduction under flow-type system.Nano Research 2021.
  • [46] Xingming Ning, Dan Yin, Yiping Fan, Qi Zhang, Peiyao Du,* Dongxu Zhang, Jing Chen, and Xiaoquan Lu*. Plasmon-Enhanced Charge Separation and Surface Reactions Based on Ag-Loaded Transition-Metal Hydroxide for Photoelectrochemical Water Oxidation. Adv. Energy Mater. 2021, 2100405.
  • [47] Hengli Qian, Guanjie Yu, Qidong Hou et. al. Ingenious control of adsorbed oxygen species to construct dual reaction centers photo-Fenton catalyst with high-speed electron transmission channel for PPCPs degradation. Applied Catalysis B: Environmental, 2021.
  • [48] Zhao H, Liu P, Wu X, et al. Plasmon Enhanced Glucose Photoreforming for Arabinose and Gas Fuel Co-production over 3DOM TiO2-Au. Applied Catalysis B: Environmental, 2021: 120055.
  • [49] Yu-Xuan Tan, Lang Chen, Sheng Shen, Jun-Kang Guo, Shuang-Feng Yin et. al. Boosted Photocatalytic Oxidation of Toluene into Benzaldehyde on CdIn2S4-CdS: Synergetic Effect of Compact Heterojunction and S-Vacancy. ACS Catal 2021, 11, 2492-2503.
  • [50] Changhai Lu, Xinru Li, Qian Wu, Juan Li, Long Wen, Ying Dai, Baibiao Huang, Baojun Li and Zaizhu Lou*. Constructing Surface Plasmon Resonance on Bi2WO6 to Boost High-Selective CO2 Reduction for Methane ACS Nano 2020,
  • [51] Syed Jalil Shah, Ruimeng Wang, Zhu Gao, Yaseen Muhammad, Hanzhuo Zhang, Zhengsheng Zhang, Zhe Chu, Zhongxing Zhao, Zhenxia Zhao. IL-assisted Synthesis of Defect-rich Polyaniline/NH2-MIL-125 Nanohybrids with Strengthened Interfacial Contact for Ultra-fast Photocatalytic Degradation of Acetaldehyde under High Humidity. Chemical Engineering Journal 411 (2021) 128590.
  • [52]Zhiling Guan, Xiaoming Li,You Wu; Zhuo Chen,Xiaoding Huang, Dongbo Wang, Qi Yang, Jiale Liu, Suhong Tian, Xiyu Chen,Hui Zhao ,AgBr nanoparticles decorated 2D/2D GO/Bi2WO6 photocatalyst with enhanced photocatalytic performance for the removal of tetracycline hydrochloride.Chemical Engineering Journal .
  • [53] Renli Yin, Mingshan Zhu et al. Peroxydisulfate bridged photocatalysis of covalent triazine framework for carbamazepine degradation. Chemical Engineering Journal  2022, 427, 131613.
  • [54] Z. Li, J. Hu, Z. Lou, L. Zeng, M. Zhu*, Molecularly imprinted photoelectrochemical sensor for detecting tetrabromobisphenol A in indoor dust and water, Microchimica Acta, 2021, 188, 320.
  • [55] Yeran Li, Xin Jin, Wei Li et. al. Biomimetic hydrophilic foam with micro/nano-scale porous hydrophobic surface for highly efficient solar-driven vapor generation. Sci. China Mater. (2021).
  • [56] Jing Wang, Ling Yuan, Chaoqi Zhang, Shumin Li, Guozhong Wang, Jingjing Wan, Chao Liu,* Chengzhong Yu*, Metal-Organic Frameworks Derived Titanium Oxides via Soft Interface Adaptive Transformation, Advanced Functional Materials, 2021, 31, 2107260.
  • [57] Xueying Cheng, Renquan Guan, Yunning Chen et. al. The unique TiO2(B)/BiOCl0.7I0.3-P Z-scheme heterojunction effectively degrades and mineralizes the herbicide fomesafen. Chemical Engineering Journal 2022, 431, 134021.
  • [58] Z.H. Liu, M.X. Ji, J.Z. Zhao, Y. Zhang, X. Sun, Y.F. Shao, H.M. Li, S. Yin, J.X. Xia, Dual modulation steering electron reducibility and transfer of bismuth molybdate nanoparticle to boost carbon dioxide photoreduction to carbon monoxide, Journal of Colloid and Interface Science.
  • [59] Wang X, Wang X, et al. nterfacial engineering improved internal electric field contributing to direct Z-scheme-dominated mechanism over CdSe/SL-ZnIn2S4/MoSe₂ heterojunction for efficient photocatalytic hydrogen. Chemical Engineering Journal 431 (2022) 134000
  • [60] Yan-Yang Li, Jun-Sheng Fan, Rong-Qing Tan, et. al. Selective Photocatalytic Reduction of CO2 to CH4 Modulated by Chloride Modification on Bi2WO6 Nanosheets. ACS Appl. Mater. Interfaces 2020, DOI: 10.1021/acsami.0c11551.
  • [61] Lei Luo, et al. Binary Au–Cu Reaction Sites Decorated ZnO for Selective Methane Oxidation to C1 Oxygenates with Nearly 100% Selectivity at Room Temperature. Journal of the American Chemical Society, 2021, 10.1021/jacs.1c09141.
  • [62] HaijiaoLu,Yi-MingZhao,Sandra ElizabethSaji,XinmaoYin,AryWibowo,Chi SinTang,ShiboXi,PengfeiCao,MikeTebyetekerwa,BoruiLiu,MarcHeggen,Rafal E.Dunin-Borkowski,AntonioTricoli,Andrew T.S.Wee,Hieu T.Nguyen,Qing-BoYan,ZongyouYin,All room-temperature synthesis, N2 photofixation and reactivation over 2D cobalt oxides,Applied Catalysis B: Environmental,2022, 121001
  • [63] Unique Insights into Photocatalytic VOCs Oxidation over WO3/Carbon Dots Nanohybrids Assisted by Water Activation and Electron Transfer at Interfaces. Journal of Hazardous Materials, 2021. 
  • [64] Lejing Li,Liangpang Xu,Zhuofeng Hu,Jimmy C. Yu,Enhanced Mass Transfer of Oxygen through a Gas–Liquid–Solid Interface for Photocatalytic Hydrogen Peroxide Production,Advanced Functional Materials,2021,2106120
  • [65] Chuanwang Xing, Guiyang Yu,* Ting Chen, Shanshan Liu, Qiqi Sun, Qi Liu, Yujia Hu, Heyuan Liu, Xiyou Li,* Perylenetetracarboxylic diimide covalently bonded with mesoporous g-C3N4 to construct direct Z-scheme heterojunctions for efficient photocatalytic oxidative coupling of amines. Appl. Catal., B, 2021, DOI: 10.1016/j.apcatb.2021.120534
  • [66] X. Xu, J. Wang, T. Chen, N. Yang, S. Wang, X. Ding, H. Chen, Deep insight into ROS mediated direct and hydroxylated dichlorination process for efficient photocatalytic sodium pentachlorophenate mineralization, Appl. Catal. B- Environ., 296 (2021) 120352.
  • [67] Marriage of 2D Covalent–Organic Framework and 3D Network as Stable Solar-Thermal Stillfor Efficient Solar Steam Generation, Small methods. 2021, 202100036.
  • [68] Z. Z. Wang, Q. Cheng, X. T. Wang, J. M. Li, W. X. Li, Y. Li, G. K. Zhang, Carbon dots modified bismuth antimonate for broad spectrum photocatalytic degradation of organic pollutants:Boosted charge separation, DFT calculations and mechanism unveiling, Chem. Eng. J., DOI: 10.1016/j.cej.2021.129460.
  • [69] Huining Huang, Run Shi, Zhenhua Li, Jiaqi Zhao, Chenliang Su, and Tierui Zhang,Triphase Photocatalytic CO2 Reduction over Silver-Decorated Titanium Oxide at a Gas-Water Boundary,Angew. Chem. Int. Ed. 2022, e202200802.
Related Products