Nanoporous silver(NPS) with a ligament size ranging from 15 to 40 nm was fabricated by de-alloying(Cu_(50)Zr_(50))_(100-x)Agx(x = 10at%, 20at%, 30at%, and 40at%) amorphous ribbons in a mixed aqueous soluti...Nanoporous silver(NPS) with a ligament size ranging from 15 to 40 nm was fabricated by de-alloying(Cu_(50)Zr_(50))_(100-x)Agx(x = 10at%, 20at%, 30at%, and 40at%) amorphous ribbons in a mixed aqueous solution of hydrofluoric(HF) acid and nitric acid under free corrosion conditions. Nanoporous silver ligaments and pore sizes were able to be fine-tuned through tailoring the chemical composition, corrosion conditions, and de-alloying time. The ligament size increases with an increase in Ag content and de-alloying time, but decreases with an increase in HF concentration. This phenomenon may be attributed to the dissolution of Zr/Cu and the diffusion, aggregation, nucleation, and recrystallization of Ag, leading to an oriented attachment of adjacent nanocrystals as revealed by TEM analysis.展开更多
In recent years, bio-nanopore and solid-state nanopore have been greatly improved for molecule bio-sensing. Whereas, the development of this scientific field seems to have encountered a bottleneck due to their respect...In recent years, bio-nanopore and solid-state nanopore have been greatly improved for molecule bio-sensing. Whereas, the development of this scientific field seems to have encountered a bottleneck due to their respective limitations. The small pore size of the former impedes the detection of large single molecule, and the latter is difficult to achieve similar accuracy and functional control. DNA origami plays a novel role to bring more opportuni- ties for the development of nanopore technology since it is relatively easy to synthesize and modify. This review mainly focuses on introducing the DNA origami nanopore fabrication methods, characterization and application. Meanwhile, the challenges in the present DNA origami nanopore research are also discussed.展开更多
Nanopores for DNA sequencing have drawn much attention due to their potentials to achieve amplification-free, low-cost, and high-throughput analysis of nuclei acids. The material configuration and fabrication of the n...Nanopores for DNA sequencing have drawn much attention due to their potentials to achieve amplification-free, low-cost, and high-throughput analysis of nuclei acids. The material configuration and fabrication of the nanopore has become one important consideration in the nanopore based DNA sequencing research. Among various materials, the newly emerged graphene has brought more opportunities to the development of sequencing technology because of its unique structures and properties. This review mainly focuses on the experimental aspects of graphene nanopore research including the nanopore fabrication methods and processes. Meanwhile, the challenges in the present graphene nanopore research including hydrophobicity, translocation velocity and noise are also addressed and discussed.展开更多
基金financially supported by the National Natural Science Foundation of China(No.51101004)
文摘Nanoporous silver(NPS) with a ligament size ranging from 15 to 40 nm was fabricated by de-alloying(Cu_(50)Zr_(50))_(100-x)Agx(x = 10at%, 20at%, 30at%, and 40at%) amorphous ribbons in a mixed aqueous solution of hydrofluoric(HF) acid and nitric acid under free corrosion conditions. Nanoporous silver ligaments and pore sizes were able to be fine-tuned through tailoring the chemical composition, corrosion conditions, and de-alloying time. The ligament size increases with an increase in Ag content and de-alloying time, but decreases with an increase in HF concentration. This phenomenon may be attributed to the dissolution of Zr/Cu and the diffusion, aggregation, nucleation, and recrystallization of Ag, leading to an oriented attachment of adjacent nanocrystals as revealed by TEM analysis.
文摘In recent years, bio-nanopore and solid-state nanopore have been greatly improved for molecule bio-sensing. Whereas, the development of this scientific field seems to have encountered a bottleneck due to their respective limitations. The small pore size of the former impedes the detection of large single molecule, and the latter is difficult to achieve similar accuracy and functional control. DNA origami plays a novel role to bring more opportuni- ties for the development of nanopore technology since it is relatively easy to synthesize and modify. This review mainly focuses on introducing the DNA origami nanopore fabrication methods, characterization and application. Meanwhile, the challenges in the present DNA origami nanopore research are also discussed.
基金supported by the National Natural Science Foundation of China (81471697)the Key Technology R&D Program of Hubei Province (2014BBB003)+1 种基金Yellow Crane Talent (Science & Technology) Program of Wuhan City and Applied Basic Research Program of Wuhan City (2016060101010044, 2016060101010048)the Fundamental Research Funds for the Central Universities (2016YXMS253)
文摘Nanopores for DNA sequencing have drawn much attention due to their potentials to achieve amplification-free, low-cost, and high-throughput analysis of nuclei acids. The material configuration and fabrication of the nanopore has become one important consideration in the nanopore based DNA sequencing research. Among various materials, the newly emerged graphene has brought more opportunities to the development of sequencing technology because of its unique structures and properties. This review mainly focuses on the experimental aspects of graphene nanopore research including the nanopore fabrication methods and processes. Meanwhile, the challenges in the present graphene nanopore research including hydrophobicity, translocation velocity and noise are also addressed and discussed.
