The
growing requirement for high-performance energy-storage devices has
spurred the development of supercapacitors, but the low energy density
remains a technical hurdle. In this work, porous nitrogen-doped activated
carbon (NAC) is prepared on a large scale from commercial activated
carbon (AC) and inexpensive chemicals by a one-step method. The NAC
material with 3.1 wt % nitrogen has a high specific surface area of
1186 m2 g–1 and shows a specific capacitance
of 427 F g–1 in a symmetric cell with an aqueous
electrolyte. 98.2% of the capacity is reserved after 20 000
cycles at 20 A g–1. The energy densities of the
NAC are 17.2 and 87.8 Wh kg–1 in acidic and organic
electrolytes, respectively. Moreover, this simple process is readily
scalable to address commercial demand and can be extended to the motivation
of a variety of carbon-based materials with poor capacitances.
A topological insulator (TI) is a kind of novel material hosting a topological band structure and plenty of exotic topological quantum effects. Achieving quantized electrical transport, including the quantum Hall effect (QHE) and the quantum anomalous Hall effect (QAHE), is an important aspect of realizing quantum devices based on TI materials. Intense efforts are made in this field, in which the most essential research is based on the optimization of realistic TI materials. Herein, the TI material development process is reviewed, focusing on the realization of quantized transport. Especially, for QHE, the strategies to increase the surface transport ratio and decrease the threshold magnetic field of QHE are examined. For QAHE, the evolution history of magnetic TIs is introduced, and the recently discovered magnetic TI candidates with intrinsic magnetizations are discussed in detail. Moreover, future research perspectives on these novel topological quantum effects are also evaluated.
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