Valleytronics is an emergent discipline in condensed matter physics and offers a new way to encode and manipulate information based on the valley degree of freedom in materials. Among the various materials being studi...Valleytronics is an emergent discipline in condensed matter physics and offers a new way to encode and manipulate information based on the valley degree of freedom in materials. Among the various materials being studied, Kekulé distorted graphene has emerged as a promising material for valleytronics applications. Graphene can be artificially distorted to form the Kekulé structures rendering the valley-related interaction. In this work, we review the recent progress of research on Kekulé structures of graphene and focus on the modified electronic bands due to different Kekulé distortions as well as their effects on the transport properties of electrons. We systematically discuss how the valley-related interaction in the Kekulé structures was used to control and affect the valley transport including the valley generation, manipulation, and detection. This article summarizes the current challenges and prospects for further research on Kekulé distorted graphene and its potential applications in valleytronics.展开更多
Nucleic acid amplification test is a reliable method for primary human immunodeficiency virus (HIV) infection diagnosis. Herein, a novel fluorescent method for sequence-specific recognition of DNA fragment of HIV-1 ...Nucleic acid amplification test is a reliable method for primary human immunodeficiency virus (HIV) infection diagnosis. Herein, a novel fluorescent method for sequence-specific recognition of DNA fragment of HIV-1 was established based upon nicking-assisted strand displacement amplification (SDA) and triplex DNA. In the presence of target dsDNA, nicking-assisted SDA process generated a lot of ssDNA, which hybridized with molecular beacon to produce signal. The fluorescence intensity was proportional to the concentration of target dsDNA within the range from 5 to 1000 pmol/L, with a detection limit of 1.4 pmol/L. Moreover, it successfully distinguished target dsDNA from the nucleic acid extractive of human blood. Thus this method has the merit of high sensitivity, and it is suitable for sequence-specific recognition of target dsDNA in complex matrices, which made it a potential application in diagnosis of acquired immunodeflciency syndrome (AIDS) in the future.展开更多
基金Project supported by the National Natural Science Foundation of China (Grant Nos.12174051 and 12304069)。
文摘Valleytronics is an emergent discipline in condensed matter physics and offers a new way to encode and manipulate information based on the valley degree of freedom in materials. Among the various materials being studied, Kekulé distorted graphene has emerged as a promising material for valleytronics applications. Graphene can be artificially distorted to form the Kekulé structures rendering the valley-related interaction. In this work, we review the recent progress of research on Kekulé structures of graphene and focus on the modified electronic bands due to different Kekulé distortions as well as their effects on the transport properties of electrons. We systematically discuss how the valley-related interaction in the Kekulé structures was used to control and affect the valley transport including the valley generation, manipulation, and detection. This article summarizes the current challenges and prospects for further research on Kekulé distorted graphene and its potential applications in valleytronics.
基金supported by the National Natural Science Foundation of China(21375153)
文摘Nucleic acid amplification test is a reliable method for primary human immunodeficiency virus (HIV) infection diagnosis. Herein, a novel fluorescent method for sequence-specific recognition of DNA fragment of HIV-1 was established based upon nicking-assisted strand displacement amplification (SDA) and triplex DNA. In the presence of target dsDNA, nicking-assisted SDA process generated a lot of ssDNA, which hybridized with molecular beacon to produce signal. The fluorescence intensity was proportional to the concentration of target dsDNA within the range from 5 to 1000 pmol/L, with a detection limit of 1.4 pmol/L. Moreover, it successfully distinguished target dsDNA from the nucleic acid extractive of human blood. Thus this method has the merit of high sensitivity, and it is suitable for sequence-specific recognition of target dsDNA in complex matrices, which made it a potential application in diagnosis of acquired immunodeflciency syndrome (AIDS) in the future.
