3 research outputs found
Additional file 2: Table S1. of Exome QTL-seq maps monogenic locus and QTLs in barley
Provisional exome sequences (PESs) based on Morex loci [3]. Table S2. RNA-seq data of Haruna Nijo used to restructure the pseudo reference sequence (PRS) in the QTL-seq analysis. Table S3. Number of aligned RNA-seq reads with PESs and detected SNPs against PES. Table S4. Number of reads and sequences used and mapped in the QTL-seq analysis of Blp. Table S5. Number of reads and sequences used and mapped in the QTL-seq analysis of net blotch resistance genes. (DOCX 32Ă‚Â kb
Additional file 1: Figure S1. of Exome QTL-seq maps monogenic locus and QTLs in barley
Kernel color in the haploid mapping population. Figure S2. Depth of the mapped reads on the PRS in the exome-captured QTL-seq analysis for Blp mapping. Figure S3. Plots showing the SNP index of each chromosome generated by exome-captured QTL-seq analysis for Blp mapping in barley. Figure S4. Plots of the ΔSNP index of chromosome 1H generated by exome-captured QTL-seq analysis for Blp mapping. Figure S5. Infected leaf phenotypes. Figure S6. Depth of the mapped reads on PRS in the exome-captured QTL-seq analysis for net blotch resistance. Figure S7. Plots of the SNP index of each chromosome generated by exome-captured QTL-seq analysis for mapping of net blotch resistance. Figure S8. Plots of the ΔSNP index of chromosome 3H (left) and 6H (right) generated by exome-captured QTL-seq analysis for net blotch resistance. (DOCX 5291 kb
Vapor-Phase Synthesis of ZIF‑8 MOF Thick Film by Conversion of ZnO Nanorod Array
ZIF-8
metal organic framework “micrometer-thick”
films were constructed from ZnO precursor by a vapor-phase synthesis.
The ZnO-to-ZIF-8 crystal transformation proceeded in the presence
of 2-methylimidazole (Hmim) vapor. Continuous coatings of intergrown
ZIF-8 crystals require control of a nucleation density. The dependence
of ZnO crystal plane on the ZnO-to-ZIF-8 crystal transformation was
investigated using four bulk ZnO single crystals: <i>a</i>-plane (11–20), <i>c</i>-plane (0001), <i>m</i>-plane (10–10), and <i>r</i>-plane (10–11).
It was revealed that the <i>m</i>-plane (10–10) of
ZnO is more effectively transformed into ZIF-8. In this work, highly
oriented ZnO nanorod array film was used to provide the transport
pathway of Hmim molecules and volume expansion space of ZnO-to-ZIF-8
crystal transformation for nucleation and crystal intergrowth. The
high conversion of ZnO nanorod array into ZIF-8 in a short time could
be achieved because (1) such mass transfer is easy due to the uniform
internanorod distance being maintained during reaction and (2) the
surface of the nanorod array is dominated by the highly reactive <i>m</i>-plane (10–10)