Solvothermal modification of graphitic C3N4 with Ni and Co phthalocyanines: Structural, optoelectronic and surface properties

Lebedev, Lev Alexandrovich; Chebanenko, Maria Igorevna; Dzhevaga, Ekaterina Vladimirovna; Martinson, Kirill Dmitrievich; Popkov, Vadim Igorevich

doi:10.1016/j.mencom.2022.05.008

Home / Publications / Solvothermal modification of graphitic C₃N₄ with Ni and Co phthalocyanines: Structural, optoelectronic and surface properties

Solvothermal modification of graphitic C₃N₄ with Ni and Co phthalocyanines: Structural, optoelectronic and surface properties

Lev Alexandrovich Lebedev ¹

Lev Alexandrovich Lebedev

,

Maria Igorevna Chebanenko ¹

Maria Igorevna Chebanenko

,

Ekaterina Vladimirovna Dzhevaga ¹

Ekaterina Vladimirovna Dzhevaga

,

Kirill Dmitrievich Martinson ¹

Kirill Dmitrievich Martinson

,

Vadim Igorevich Popkov ¹

Vadim Igorevich Popkov

0000-0003-3862-5041

¹ Ioffe Institute, St. Petersburg, Russian Federation

10.1016/j.mencom.2022.05.008

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Published 2022-04-29

Communication , Volume 32, Issue 3, 317-319

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Lebedev L. A. et al. Solvothermal modification of graphitic C3N4 with Ni and Co phthalocyanines: Structural, optoelectronic and surface properties // Mendeleev Communications. 2022. Vol. 32. No. 3. pp. 317-319.

GOST all authors (up to 50) Copy

Lebedev L. A., Chebanenko M. I., Dzhevaga E. V., Martinson K. D., Popkov V. I. Solvothermal modification of graphitic C3N4 with Ni and Co phthalocyanines: Structural, optoelectronic and surface properties // Mendeleev Communications. 2022. Vol. 32. No. 3. pp. 317-319.

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TY - JOUR

DO - 10.1016/j.mencom.2022.05.008

UR - https://mendcomm.colab.ws/publications/10.1016/j.mencom.2022.05.008

TI - Solvothermal modification of graphitic C3N4 with Ni and Co phthalocyanines: Structural, optoelectronic and surface properties

T2 - Mendeleev Communications

AU - Lebedev, Lev Alexandrovich

AU - Chebanenko, Maria Igorevna

AU - Dzhevaga, Ekaterina Vladimirovna

AU - Martinson, Kirill Dmitrievich

AU - Popkov, Vadim Igorevich

PY - 2022

DA - 2022/04/29

PB - Mendeleev Communications

SP - 317-319

IS - 3

VL - 32

ER -

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@article{2022_Lebedev,

author = {Lev Alexandrovich Lebedev and Maria Igorevna Chebanenko and Ekaterina Vladimirovna Dzhevaga and Kirill Dmitrievich Martinson and Vadim Igorevich Popkov},

title = {Solvothermal modification of graphitic C3N4 with Ni and Co phthalocyanines: Structural, optoelectronic and surface properties},

journal = {Mendeleev Communications},

year = {2022},

volume = {32},

publisher = {Mendeleev Communications},

month = {Apr},

url = {https://mendcomm.colab.ws/publications/10.1016/j.mencom.2022.05.008},

number = {3},

pages = {317--319},

doi = {10.1016/j.mencom.2022.05.008}

}

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Lebedev, Lev Alexandrovich, et al. “Solvothermal modification of graphitic C3N4 with Ni and Co phthalocyanines: Structural, optoelectronic and surface properties.” Mendeleev Communications, vol. 32, no. 3, Apr. 2022, pp. 317-319. https://mendcomm.colab.ws/publications/10.1016/j.mencom.2022.05.008.

Keywords

doped carbon materials

graphitic carbon nitride

photocatalysts

phthalocyanines

solvothermal synthesis

Abstract

Nanocomposites for photocatalytic applications were obtained by alchothermal modification of g-C₃N₄ with cobalt(ii) and nickel(ii) phthalocyanine complexes. The nanocomposites demonstrated higher photocatalytic activity than the bare matrix and stability under actinic irradiation. In the optoelectronic structure of the composites, the E_g value of the g-C₃N₄ matrix increased to 3.05 eV, while for MPc agents, it decreased from 1.96 to 1.82 eV.

References

1.

10.1007/s10562-020-03321-w

Influence of Thermal Activation of Titania on Photoreactivity of Pt/TiO2 in Hydrogen Production

Kurenkova A.Y., Kremneva A.M., Saraev A.A., Murzin V., Kozlova E.A., Kaichev V.V.

Catalysis Letters, 2020

2.

10.1016/j.mencom.2020.11.027

Effect of Sb5+ codopant ions on the ultraviolet photocatalytic activity of Fe3+-modified anatase

Korolenko M.V., Fabritchnyi P.B., Afanasov M.I.

Mendeleev Communications, 2020

3.

10.1016/j.mencom.2020.03.021

Carbon dioxide reduction under visible light: a comparison of cadmium sulfide and titania photocatalysts

Lyulyukin M.N., Kurenkova A.Y., Bukhtiyarov A.V., Kozlova E.A.

Mendeleev Communications, 2020

4.

10.1070/RCR4991

Titanium dioxide nanotubes: synthesis, structure, properties and applications

Rempel A.A., Valeeva A.A., Vokhmintsev A.S., Weinstein I.A.

Russian Chemical Reviews, 2021

5.

10.1007/s12034-019-1933-y

Photo-catalytic dye degradation of methyl orange using zirconia–zeolite nanoparticles

Mansouri M., Mozafari N., Bayati B., Setareshenas N.

Bulletin of Materials Science, 2019

6.

10.1007/s40097-021-00387-9

Continuous synthesis of photocatalytic nanoparticles of pure ZnO and ZnO modified with metal nanoparticles

Długosz O., Banach M.

Journal of Nanostructure in Chemistry, 2021

7.

10.1007/s11595-020-2261-1

Preparation of M2O3-CeO2 (M=La, Fe, and Al) Compoundoxide Catalyst and Its Degradation Performance

Li Y., Lin J., Xie B., Liu G.

Journal Wuhan University of Technology, Materials Science Edition, 2020

8.

10.4236/ampc.2019.99013

Investigation of Nickel Phthalocyanine Thin Films for Solar Cell Applications

Nasir E.M., Hussein M.T., Al-Aarajiy A.H.

Advances in Materials Physics and Chemistry, 2019

9.

10.1039/c3cp44687e

Eosin Y-sensitized graphitic carbon nitride fabricated by heating urea for visible light photocatalytic hydrogen evolution: the effect of the pyrolysis temperature of urea

Xu J., Li Y., Peng S., Lu G., Li S.

Physical Chemistry Chemical Physics, 2013

10.

10.1039/D0NJ04895J

The synthesis of novel heterojunction h-YbFeO₃/o-YbFeO₃ photocatalyst with enhanced Fenton-like activity under visible-light

Tikhanova S.M., Lebedev L.A., Martinson K.D., Chebanenko M.I., Buryanenko I.V., Semenov V.G., Nevedomskiy V.N., Popkov V.I.

New Journal of Chemistry, 2021

11.

10.1002/chem.202002192

Ru/CdS quantum dots templated on clay nanotubes as visible light active photocatalysts: optimization of S/Cd ratio and Ru content.

Stavitskaya A.V., Kozlova E.A., Kurenkova A.Y., Glotov A.P., Selischev D.S., Ivanov E.V., Kozlov D.V., Vinokurov V.A., Fakhrullin R.F., Lvov Y.M.

Chemistry - A European Journal, 2020

12.

10.1016/j.matlet.2020.128901

Comparative study of photoreforming of glycerol on Pt/TiO2 and CuOx/TiO2 photocatalysts under UV light

Kozlova E.A., Kurenkova A.Y., Gerasimov E.Y., Gromov N.V., Medvedeva T.B., Saraev A.A., Kaichev V.V.

Materials Letters, 2021

13.

10.1021/acsami.0c14361

Photoinduced Deposition of Platinum from (Bu4N)2[Pt(NO3)6] for a Low Pt-Loading Pt/TiO2 Hydrogen Photogeneration Catalyst.

Vasilchenko D., Topchiyan P., Tsygankova A., Asanova T., Kolesov B., Bukhtiyarov A., Kurenkova A., Kozlova E.

ACS applied materials & interfaces, 2020

14.

10.1134/S106378261912008X

Ultrasonic-Assisted Exfoliation of Graphitic Carbon Nitride and its Electrocatalytic Performance in Process of Ethanol Reforming

Chebanenko M.I., Zakharova N.V., Lobinsky A.A., Popkov V.I.

Semiconductors, 2019

15.

10.1134/S1070427220040035

Synthesis and Visible-Light Photocatalytic Activity of Graphite-like Carbon Nitride Nanopowders

Chebanenko M.I., Zakharova N.V., Popkov V.I.

Russian Journal of Applied Chemistry, 2020

16.

M. Chebanenko, A. A. Lobinsky and V. I. Popkov, 15th International Meeting ‘Fundamental Problems of Solid State Ionics’, Chernogolovka, Russia, 2020, p. 442.

17.

10.1016/j.mencom.2022.05.008_b0085

Chebanenko

Nanosyst.: Phys., Chem., Math., 2020

18.

10.1016/j.jorganchem.2017.01.011

Synthesis and characterization of Zn and Co monocarboxy-phthalocyanines and investigation of their photocatalytic efficiency as TiO2 composites

Sevim A.M.

Journal of Organometallic Chemistry, 2017

19.

10.1016/j.synthmet.2020.116480

Construction of cobalt phthalocyanine sensitized SnIn4S8/g-C3N4 composites with enhanced photocatalytic degradation and hydrogen production performance

Lu M., Sun Z., Zhang Y., Liang Q., Zhou M., Xu S., Li Z.

Synthetic Metals, 2020

20.

10.1088/0031-8949/73/1/006

Structural and transport properties of thermally evaporated nickel phthalocyanine thin films

El-Nahass M.M., Abd-El-Rahman K.F., Farag A.A., Darwish A.A.

Physica Scripta, 2005

21.

$X-ray Powder Diffraction Structure Reinvestigation of the α and β Forms of Cobalt Phthalocyanine and Kinetics of the α → β Phase Transition$

10.1021/ja973815p

X-ray Powder Diffraction Structure Reinvestigation of the α and β Forms of Cobalt Phthalocyanine and Kinetics of the α → β Phase Transition

Ballirano P., Caminiti R., Ercolani C., Maras A., Orrù M.A.

Journal of the American Chemical Society, 1998

22.

10.3390/ma6104324

Preparation and Characterization of Cu and Ni on Alumina Supports and Their Use in the Synthesis of Low-Temperature Metal-Phthalocyanine Using a Parallel-Plate Reactor

Sánchez-De la Torre F., De la Rosa J., Kharisov B., Lucio-Ortiz C.

Materials, 2013

23.

10.1007/s13204-017-0568-9

A study of the optical band gap of zinc phthalocyanine nanoparticles using UV–Vis spectroscopy and DFT function

Hamam K.J., Alomari M.I.

Applied Nanoscience (Switzerland), 2017

24.

10.1117/12.795451

Critical interfaces in new solar cell materials: organic heterojunctions and heterojunctions involving semiconductor nanoparticles

Armstrong N.R., Alloway D., Graham A., Shallcross C., Brumbach M., Veneman P.A., Placencia D., Wang W.

Proceedings of SPIE - The International Society for Optical Engineering, 2008

25.

10.1155/2007/643834

Studies on the Optical Properties and Surface Morphology of Nickel Phthalocyanine Thin Films

Joseph B., Menon C.S.

E-Journal of Chemistry, 2007

26.

10.1134/S0036024414080214

Acidic and basic properties of the surface of gas-chromatographic sorbents with grafted metal chelate layers

Pakhnutova E.A., Slizhov Y.G.

Russian Journal of Physical Chemistry A, 2014