Ultra-high temperature ceramics (UHTCs) are generally referred to the carbides, nitrides, and borides of the transition metals, with the Group IVB compounds (Zr & Hf) and TaC as the main focus. The UHTCs are endowed with ultra-high melting points, excellent mechanical properties, and ablation resistance at elevated temperatures. These unique combinations of properties make them promising materials for extremely environmental structural applications in rocket and hypersonic vehicles, particularly nozzles, leading edges, and engine components, etc. In addition to bulk UHTCs, UHTC coatings and fiber reinforced UHTC composites are extensively developed and applied to avoid the intrinsic brittleness and poor thermal shock resistance of bulk ceramics. Recently, highentropy UHTCs are developed rapidly and attract a lot of attention as an emerging direction for ultra-high temperature materials. This review presents the state of the art of processing approaches, microstructure design and properties of UHTCs from bulk materials to composites and coatings, as well as the future directions.
Free‐standing paper‐like thin‐film electrodes have great potential to boost next‐generation power sources with highly flexible, ultrathin, and lightweight requirements. In this work, silver‐quantum‐dot‐ (2–5 nm) modified transition metal oxide (including MoO3 and MnO2) paper‐like electrodes are developed for energy storage applications. Benefitting from the ohmic contact at the interfaces between silver quantum dots and MoO3 nanobelts (or MnO2 nanowires) and the binder‐free nature and 0D/1D/2D nanostructured 3D network of the fabricated electrodes, substantial improvements on the electrical conductivity, efficient ionic diffusion, and areal capacitances of the hybrid nanostructure electrodes are observed. With this proposed strategy, the constructed asymmetric supercapacitors, with Ag quantum dots/MoO3 “paper” as anode, Ag quantum dots/MnO2 “paper” as cathode, and neutral Na2SO4/polyvinyl alcohol hydrogel as electrolyte, exhibit significantly enhanced energy and power densities in comparison with those of the supercapacitors without modification of Ag quantum dots on electrodes; present excellent cycling stability at different current densities and good flexibility under various bending states; offer possibilities as high‐performance power sources with low cost, high safety, and environmental friendly properties.
SiOC/HfO2‐based ceramic nanocomposites with in situ formed HfO2 nanoparticles were prepared via a single‐source precursor (SSP) approach starting from a polymethylsilsesquioxane (PMS) modified by Hf‐ and Ti‐alkoxides. By varying the alkyl‐group of the employed Hf‐alkoxides, SiOC/HfO2‐based ceramic nanocomposites with different HfO2 polymorphs formed via thermal decomposition of the SSP under the same heat‐treatment conditions. Using PMS chemically modified by Hf(OnBu)4, tetragonal HfO2 phase was formed after the synthesis at 1100°C in Ar, whereas both, tetragonal and monoclinic HfO2 nanocrystals, were analyzed when replacing Hf(OnBu)4 by Hf(OiPr)4. After oxidation of the synthesized nanocomposites in air at 1500°C, a facile formation of oxidation‐resistant HfSiO4 (hafnon) phase occurred by the reaction of HfO2 nanocrystals with silica present in the SiOC nanocomposite matrix derived from Hf(OiPr)4‐modified SSPs. Moreover the amount of hafnon is dramatically increased by the additional modification of the polysiloxane with Ti‐alkoxides. In contrast, ceramic nanocomposites derived from Hf(OnBu)4‐modified SSPs, almost no HfSiO4 is detected after oxidation at 1500°C even though in the case of Ti‐alkoxide‐modified single‐source precursor.
Materials
with low density, exceptional thermal and corrosion resistance,
and ultrahigh mechanical and electromagnetic interference (EMI) shielding
performance are urgently demanded for aerospace and military industries.
Efficient design of materials’ components and microstructures
is crucial yet remains highly challenging for achieving the above
requirements. Herein, a strengthened reduced graphene oxide (SrGO)-reinforced
multi-interfacial carbon–silicon carbide (C-SiC)
n
matrix (SrGO/(C-SiC)
n
) composite is reported, which is fabricated by depositing a carbon-strengthening
layer into rGO foam followed by alternate filling of pyrocarbon (PyC)
and silicon carbide (SiC) via a precursor infiltration
pyrolysis (PIP) method. By increasing the number of alternate PIP
sequences (n = 1, 3 and 12), the mechanical, electrical,
and EMI shielding properties of SrGO/(C-SiC)
n
composites are significantly increased. The optimal composite
exhibits excellent conductivity of 8.52 S·cm–1 and powerful average EMI shielding effectiveness (SE) of 70.2 dB
over a broad bandwidth of 32 GHz, covering the entire X-, Ku-, K-,
and Ka-bands. The excellent EMI SE benefits from the massive conduction
loss in highly conductive SrGO skeletons and polarization relaxation
of rich heterogeneous PyC/SiC interfaces. Our composite features low
density down to 1.60 g·cm–3 and displays robust
compressive properties (up to 163.8 MPa in strength), owing to the
uniformly distributed heterogeneous interfaces capable of consuming
great fracture energy upon loadings. Moreover, ultrahigh thermostructural
stability (up to 2100 °C in Ar) and super corrosion resistance
(no strength degradation after long-term acid and alkali immersion)
are also discovered. These excellent comprehensive properties, along
with ease of low-cost and scalable production, could potentially promote
the practical applications of the SrGO/(C-SiC)
n
composite in the near future.
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