The
interest in two-dimensional (2D) nanomaterials has been increased
rapidly after the discovery of graphene. The 2D graphene analogs (2DGAs)
with ultrathin-layered feature exhibit a unique property which their
bulk counterparts cannot possess. Among various 2D nanomaterials,
the transition metal dichalcogenides (TMDs) and transition metal oxides
(TMOs) have attracted considerable attention from scientific communities.
The availability of various transition metals and their binding states
in 2D TMDs and TMOs enable them to show a wide spectrum of properties
such as metals to wide band gap semiconductors. Although properties
of 2D TMDs and TMOs are excellent, further enhancement of their properties
is still required for cutting-edge applications. The surface functionalization
of 2DGAs is a potential route for enhancing their properties. The
surfaces of 2D TMDs and TMOs could be functionalized with various
types of organic or inorganic nanomaterials via covalent or non-covalent
interactions. The functionalization may alter the Fermi level of 2D
nanomaterials, also having this potential to add extra functionalities
to the basis of the fabricated devices using them. In this review,
we first introduce and specify the characteristics of 2D TMDs and
TMOs as two important 2DGAs. Then, we discuss their limitations and
how surface functionalization may enhance their performance. The covalent
and non-covalent modes of surface functionalization with organic and
inorganic nanomaterials on both 2D TMDs and TMOs are then considered.
The current state and challenge of the functionalized 2D TMDs and
TMOs are also discussed by their application point of view in energy
storage and conversion, sensing, biomedical, catalytic combustion,
and (opto)electronic devices.
2D and 3D graphene-based hybrid composites are the most promising materials for a broad range of high-efficiency energy storage and conversion devices.
Ceramic matrix composites made of carbon fibres and carbon matrix (C/C) are generally used for aircraft structures and brake discs due to their low density, and good thermal, mechanical, and tribological properties. Silicon carbide (SiC) can be introduced to the matrix to improve the performance of C/C composites, because it increases the hardness and thermal stability, and decreases the chemical reactivity, which leads to the improvement of tribological properties of C/C composites. Thus carbon-carbon silicon carbide (C/C-SiC) composites can be used at high temperature for the application of brake discs, friction clutches, etc. C/C-SiC composites are fabricated by three different methods: (i) chemical vapour infiltration (CVI), (ii) polymer infiltration and pyrolysis (PIP), and (iii) liquid silicon infiltration (LSI), among which LSI method is widely used for the fabrication of C/C-SiC composites due to higher mechanical and thermal properties.
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