Although Pampus minor has been classified as a new species, it still remains controversial. Was used a DNA barcoding technique based on homologous sequence analysis of the16S and CO1 genes to clarify the confusion ove...Although Pampus minor has been classified as a new species, it still remains controversial. Was used a DNA barcoding technique based on homologous sequence analysis of the16S and CO1 genes to clarify the confusion over the identification of this species. Among 12 individuals whose genetic distance was 0.002, two haplotypes were found. According to the 16S sequences, the genetic distances ranged from 0.121 to 0.133 between P. minor and other Pampus species. Although the same the genetic distance between the two P minor haplotypes was generated using CO1 sequences, the haplotype of Pm22-23, Pm28, and Pm32-33 was the same as that of Pci EF607462 and EF607466, while the haplotype of Pm24-27 and Pm29-31 was the same as that of Pci EF607461 and EF607463-65. In addition, the genetic distance ranged only from 0.002 to 0.005 between P minor and Pa EF607460 and EF607458. Apart from this, the interspecies genetic distances varied from 0.135 to 0.143 between P minor and other t'ampus species according to the C01 sequences. Phylogenetic trees, using combined 16S and CO1 data, strongly support the viewpoint that all the P. minor individuals form one clade that is in a sister position to Pampus sp. individuals (EU357803, FJ434342-FJ434343, and FJ652423-FJ652427).展开更多
Arrays of chemical vapor sensors based on graphene field effect transistors functionalized with single-stranded DNA have been demonstrated. Standard photolithographic processing was adapted for use on large-area graph...Arrays of chemical vapor sensors based on graphene field effect transistors functionalized with single-stranded DNA have been demonstrated. Standard photolithographic processing was adapted for use on large-area graphene by including a metal protection layer, which protected the graphene from contamination and enabled fabrication of high quality field-effect transistors (GFETs). Processed graphene devices had hole mobilities of 1,640 ± 250 cm2.V-1.s-1 and Dirac voltages of 15 ± 10 V under ambient conditions. Atomic force microscopy was used to verify that the graphene surface remained uncontaminated and therefore suitable for controlled chemical functionalization. Single-stranded DNA was chosen as the functionalization layer due to its affinity to a wide range of target molecules and π-π stacking interaction with graphene, which led to minimal degradation of device characteristics. The resulting sensor arrays showed analyte- and DNA sequence-dependent responses down to parts-per-billion concentrations. DNA/GFET sensors were able to differentiate among chemically similar analytes, including a series of carboxylic acids, and structural isomers of carboxylic acids and pinene. Evidence for the important role of electrostatic chemical gating was provided by the observation of understandable differences in the sensor response to two compounds that differed only by the replacement of a (deprotonating) hydroxyl group by a neutral methyl group. Finally, target analytes were detected without loss of sensitivity in a large background of a chemically similar, volatile compound. These results motivate further development of the DNA/graphene sensor family for use in an electronic olfaction system.展开更多
Single-walled carbon nanotubes(SWNTs)are regarded as one of the most promising candidates as building blocks in the next generation electronics.The most advanced opportunities demand the ability to form perfectly al...Single-walled carbon nanotubes(SWNTs)are regarded as one of the most promising candidates as building blocks in the next generation electronics.The most advanced opportunities demand the ability to form perfectly aligned,horizontal arrays of SWNTs with a uniform structure.However,synthesizing them by conventional chemical vapor deposition(CVD)methods would result in poorly-aligned nanotubes with a variety of chiral species,展开更多
基金Supported by National Natural Science Foundation of China (No. 40676085)
文摘Although Pampus minor has been classified as a new species, it still remains controversial. Was used a DNA barcoding technique based on homologous sequence analysis of the16S and CO1 genes to clarify the confusion over the identification of this species. Among 12 individuals whose genetic distance was 0.002, two haplotypes were found. According to the 16S sequences, the genetic distances ranged from 0.121 to 0.133 between P. minor and other Pampus species. Although the same the genetic distance between the two P minor haplotypes was generated using CO1 sequences, the haplotype of Pm22-23, Pm28, and Pm32-33 was the same as that of Pci EF607462 and EF607466, while the haplotype of Pm24-27 and Pm29-31 was the same as that of Pci EF607461 and EF607463-65. In addition, the genetic distance ranged only from 0.002 to 0.005 between P minor and Pa EF607460 and EF607458. Apart from this, the interspecies genetic distances varied from 0.135 to 0.143 between P minor and other t'ampus species according to the C01 sequences. Phylogenetic trees, using combined 16S and CO1 data, strongly support the viewpoint that all the P. minor individuals form one clade that is in a sister position to Pampus sp. individuals (EU357803, FJ434342-FJ434343, and FJ652423-FJ652427).
基金This research was supported by the Nano/Bio Interface Center through the National Science Foundation Nanoscale Science and Engineering Center (NSEC) DMR08-32802, and the work involved use of its facilities. Support from Lockheed Martin is also gratefully acknowledged. M.L. acknowledges the support of the Science, Mathematics, And Research for Transformation (SMART) Fellowship.
文摘Arrays of chemical vapor sensors based on graphene field effect transistors functionalized with single-stranded DNA have been demonstrated. Standard photolithographic processing was adapted for use on large-area graphene by including a metal protection layer, which protected the graphene from contamination and enabled fabrication of high quality field-effect transistors (GFETs). Processed graphene devices had hole mobilities of 1,640 ± 250 cm2.V-1.s-1 and Dirac voltages of 15 ± 10 V under ambient conditions. Atomic force microscopy was used to verify that the graphene surface remained uncontaminated and therefore suitable for controlled chemical functionalization. Single-stranded DNA was chosen as the functionalization layer due to its affinity to a wide range of target molecules and π-π stacking interaction with graphene, which led to minimal degradation of device characteristics. The resulting sensor arrays showed analyte- and DNA sequence-dependent responses down to parts-per-billion concentrations. DNA/GFET sensors were able to differentiate among chemically similar analytes, including a series of carboxylic acids, and structural isomers of carboxylic acids and pinene. Evidence for the important role of electrostatic chemical gating was provided by the observation of understandable differences in the sensor response to two compounds that differed only by the replacement of a (deprotonating) hydroxyl group by a neutral methyl group. Finally, target analytes were detected without loss of sensitivity in a large background of a chemically similar, volatile compound. These results motivate further development of the DNA/graphene sensor family for use in an electronic olfaction system.
文摘Single-walled carbon nanotubes(SWNTs)are regarded as one of the most promising candidates as building blocks in the next generation electronics.The most advanced opportunities demand the ability to form perfectly aligned,horizontal arrays of SWNTs with a uniform structure.However,synthesizing them by conventional chemical vapor deposition(CVD)methods would result in poorly-aligned nanotubes with a variety of chiral species,
