Graphitic carbon nitride

Graphitic carbon nitride (g-C₃N₄) is a family of carbon nitride compounds with a general formula near to C₃N₄ (albeit typically with non-zero amounts of hydrogen) and two major substructures based on heptazine and poly(triazine imide) units which, depending on reaction conditions, exhibit different degrees of condensation, properties and reactivities.

Preparation

Graphitic carbon nitride can be made by

amino groups, is a highly ordered polymer. Further reaction leads to more condensed and less defective C₃N₄ species, based on tri-s-triazine (C₆N₇) units as elementary building blocks.^[2]

Graphitic carbon nitride can also be prepared by electrodeposition on Si(100) substrate from a saturated acetone solution of cyanuric trichloride and melamine (ratio =1: 1.5) at room temperature.^[3]

Well-crystallized graphitic carbon nitride nanocrystallites can also be prepared via benzene-thermal reaction between C₃N₃Cl₃ and NaNH₂ at 180–220 °C for 8–12 h.^[4]

Recently, a new method of syntheses of graphitic carbon nitrides by heating at 400-600 °C of a mixture of melamine and

alumina has been reported. Alumina favored the deposition of the graphitic carbon nitrides layers on the exposed surface. This method can be assimilated to an in situ chemical vapor deposition (CVD).^[5]

Characterization

Characterization of crystalline g-C₃N₄ can be carried out by identifying the

Fourier transform infrared spectroscopy (FTIR) spectrum (peaks at 800 cm⁻¹, 1310 cm⁻¹ and 1610 cm⁻¹).^[4]

Properties

Due to the special

trimerization reactions, and also the activation of carbon dioxide (artificial photosynthesis).^[2]

Uses

A commercial graphitic carbon nitride is available under the brand name Nicanite. In its micron-sized graphitic form, it can be used for tribological coatings, biocompatible medical coatings, chemically inert coatings, insulators and for energy storage solutions.^[6] Graphitic carbon nitride is reported as one of the best hydrogen storage materials.^[7]^[8] It can also be used as a support for catalytic nanoparticles.^[1]

Areas of interest

Due to their properties (primarily large, tuneable band gaps and efficient intercalation of salts) graphitic carbon nitrides are under research for a variety of applications:

Photocatalysts
- Decomposition of water to H₂ and O₂^[9]
- Degradation of pollutants
Large band gap semiconductor^[10]
Heterogeneous catalyst and support
- The significant resilience of carbon nitrides combined with surface and intralayer reactivities make them potentially useful catalysts relying on their labile protons and Lewis base functionalities. Modifications such as doping, protonation and molecular functionalisation can be exploited to improve selectivity and performance.^[11]
- Nanoparticle catalysts supported on gCN are under development for both
  proton exchange membrane fuel cells and water electrolyzers.^[10]
- Despite graphitic carbon nitride having some advantages, such as mild band gap (2.7 eV), absorption of visible light and flexibility, it still has limitations for practical applications due to low efficiency of visible light utilization, high recombination rate of the photo generated charge carriers, low electrical conductivity and small specific surface area (<10 m²g⁻¹).[12] To modify these shortages, one of the most attractive approaches is doping graphitic carbon nitride with carbon nanomaterials, such as carbon nanotubes. First, carbon nanotubes have large specific surface area, so they can provide more sites to separate the charge carriers, then decrease the recombination rate of the charge carriers and further increase the activity of reduction reaction.^[13] Second, carbon nanotubes show high electron conducting ability, which means they can improve graphitic carbon nitride with visible light response, efficient charge carrier separation and transfer, thereby improving its electronic properties.^[14] Third, carbon nanotubes can be regarded as a kind of narrow band semiconductor material, also known as a photosensitizer, which can extend the range of the light absorption of semiconductor photocatalytic material, thereby enhancing its utilization of visible light.^[15]
Energy Storage materials
- Due to the intercalation of Li being able to occur to more sites than for graphite due to intra layer voids in addition to intercalation between layers, gCN can store a large amount of Li^[16] making them potentially useful for rechargeable batteries.

References

^
PMID 27328834
.

^
S2CID 53124927
.

S2CID 198138645
.

^
doi:10.1016/j.cplett.2003.09.009
.

doi:10.1016/j.matchemphys.2011.08.041
.

^ "Nicanite, Graphitic Carbon Nitride". Carbodeon.

doi:10.1016/j.ijhydene.2014.12.065
.

doi:10.1021/acs.jpcc.6b01850
.

S2CID 205402078
.

^
hdl:10044/1/42293
.

S2CID 53124927
.

^ Niu P, Zhang L L, Liu G, Cheng H M et al. Graphene-Like Carbon Nitride Nanosheets for Improved Photocatalytic Activities[J]. Advanced Functional Materials, 2012, 22(22): 4763-4770.

^ Zhang L Q, He X, Xu X W et al. Highly active TiO2/g-C3N4/G photocatalyst with extended spectralresponse towards selective reduction of nitrobenzene[J]. Applied Catalysis B: Environmental. 2017, 203:65-71.

^ Dong F, Li Y H, Wang Z Y, Ho W K et al. Enhanced visible light photocatalytic activity and oxidation ability ofporous graphene-like g-C3N4nanosheets via thermal exfoliation[J]. Applied Surface Science, 2015, 358: 393–403.

^ Mishra A K, Mamba G et al. Graphic carbon nitride nanocomposites: A new and exciting generation of visible light driven photocatalysts for environmental pollution remediation[J]. Applied Catalysis B, 2016, 21: 351-371.

ISSN 1932-7447
.

v
t
e
Salts and covalent derivatives of the nitride ion

NH₃
N₂H₄
+H
HN²⁻
H₂N⁻ He(N₂)₁₁

Li₃N
LiN₃ Be₃N₂
Be(N₃)₂ BN
-B C₄N₂
C₂N₂
β-C₃N₄
g-C₃N₄
C_$x$N_$y$ N₂ N_$x$O_$y$
+O N₃F
N₂F₂
N₂F₄
NF₃
+F Ne

Na₃N
NaN₃ Mg₃N₂
Mg(N₃)₂ AlN Si₃N₄
-Si PN
P₃N₅
-P S_$x$N_$y$
SN
S₂N₂
S₄N₄
SN₂H₂ NCl₃
ClN₃
+Cl Ar

K₃N
KN₃ Ca₃N₂
Ca(N₃)₂ ScN TiN
Ti₃N₄ VN CrN
Cr₂N Mn_$x$N_$y$ Fe_$x$N_$y$ Co₃N Ni₃N Cu₃N Zn₃N₂ GaN Ge₃N₄
-Ge AsN
+As Se₄N₄ Br₃N
BrN₃
+Br Kr

RbN₃ Sr₃N₂
Sr(N₃)₂ YN ZrN NbN β-Mo₂N Tc Ru Rh PdN Ag₃N Cd₃N₂ InN Sn SbN Te₄N₄? I₃N
IN₃
+I Xe

CsN₃ Ba₃N₂
Ba(N₃)₂ * LuN HfN
Hf₃N₄ TaN WN Re_$x$N_$y$ Os Ir Pt Au Hg₃N₂ Tl₃N (PbNH) BiN Po At Rn

Fr Ra₃N₂ ** Lr Rf Db Sg Bh Hs Mt Ds Rg Cn Nh Fl Mc Lv Ts Og

* LaN CeN PrN NdN PmN SmN EuN GdN TbN DyN HoN ErN TmN YbN

** Ac
Th_$x$N_$y$
PaN U_$x$N_$y$ NpN PuN AmN CmN BkN Cf Es Fm Md No

Authority control databases: National
United States
Israel

Retrieved from "https://en.wikipedia.org/w/index.php?title=Graphitic_carbon_nitride&oldid=1298093473"

[r1-1] 
PMID 27328834
.

[Thomas-2] 
S2CID 53124927
.

[3] S2CID 198138645
.

[Guo-4] 
doi:10.1016/j.cplett.2003.09.009
.

[5] :10.1016/j.matchemphys.2011.08.041
.

[6] "Nicanite, Graphitic Carbon Nitride". Carbodeon.

[7] :10.1016/j.ijhydene.2014.12.065
.

[8] :10.1021/acs.jpcc.6b01850
.

[9] S2CID 205402078
.

[:0-10] 
hdl:10044/1/42293
.

[11] S2CID 53124927
.

[12] Niu P, Zhang L L, Liu G, Cheng H M et al. Graphene-Like Carbon Nitride Nanosheets for Improved Photocatalytic Activities[J]. Advanced Functional Materials, 2012, 22(22): 4763-4770.

[13] Zhang L Q, He X, Xu X W et al. Highly active TiO2/g-C3N4/G photocatalyst with extended spectralresponse towards selective reduction of nitrobenzene[J]. Applied Catalysis B: Environmental. 2017, 203:65-71.

[14] Dong F, Li Y H, Wang Z Y, Ho W K et al. Enhanced visible light photocatalytic activity and oxidation ability ofporous graphene-like g-C3N4nanosheets via thermal exfoliation[J]. Applied Surface Science, 2015, 358: 393–403.

[15] Mishra A K, Mamba G et al. Graphic carbon nitride nanocomposites: A new and exciting generation of visible light driven photocatalysts for environmental pollution remediation[J]. Applied Catalysis B, 2016, 21: 351-371.

[16] ISSN 1932-7447
.

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