Jiro Hikida scite author profile

A novel Ru complex bearing both an acridine group and anchoring phosphonate groups was immobilized on a surface in order to capture double-stranded DNAs (dsDNAs) from solution. At low surface coverage, the atomic force microscopy (AFM) image revealed the "molecular dot" morphology with the height of the Ru complex ( approximately 2.5 nm) on a mica surface, indicating that four phosphonate anchor groups keep the Ru complex in an upright orientation on the surface. Using a dynamic molecular combing method, the DNA capture efficiency of the Ru complex on a mica surface was examined in terms of the effects of the number of molecular dots and surface hydrophobicity. The immobilized surface could capture DNAs; however, the optimal number of molecular dots on the surface as well as the optimal pull-up speed exist to obtain the extended dsDNAs on the surface. Applying this optimal condition to a Au-patterned Si/SiO 2 (Au/SiO 2) surface, the Au electrode was selectively covered with the Ru complex by orthogonal self-assembly of 4-mercaptbutylphosphonic acid (MBPA), followed by the formation of a Zr (4+)-phosphonate layer and the Ru complex. At the same time, the remaining SiO 2 surface was covered with octylphosphonic acid (OPA) by self-assembly. The selective immobilization of the Ru complex only on the Au electrode was identified by time-of-flight secondary-ion mass spectrometry (TOF-SIMS) imaging on the chemically modified Au/SiO 2 surface. The construction of DNA nanowires on the Au/SiO 2 patterned surface was accomplished by the molecular combing method of the selective immobilized Ru complex on Au electrodes. These interconnected nanowires between Au electrodes were used as a scaffold for the modification of Pd nanoparticles on the DNA. Furthermore, Cu metallization was achieved by electroless plating of Cu metal on a priming of Pd nanoparticles on the Pd-covered DNA nanowires. The resulting Cu nanowires showed a metallic behavior with relatively high resistance.

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Preparation of Patternable High Resolution and High Refractive Index Materials for AR/VR

Hikida¹,

Chisaka²,

Ijima³

et al. 2020

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P‐57: Preparation of Patternable High Resolution and High Refractive Index Materials for AR/VR

Hikida

Chisaka

Ijima

et al. 2020

Symp Digest of Tech Papers

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P‐54: Development of Heat Free / Low Temperature Process High Refractive Index Materials for Display

Urakawa

Chisaka

Hikida

et al. 2022

Symp Digest of Tech Papers

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Jiro Hikida

Fabrication of DNA Nanowires by Orthogonal Self-Assembly and DNA Intercalation on a Au Patterned Si/SiO₂ Surface

Preparation of Patternable High Resolution and High Refractive Index Materials for AR/VR

P‐57: Preparation of Patternable High Resolution and High Refractive Index Materials for AR/VR

P‐54: Development of Heat Free / Low Temperature Process High Refractive Index Materials for Display

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Jiro Hikida

Fabrication of DNA Nanowires by Orthogonal Self-Assembly and DNA Intercalation on a Au Patterned Si/SiO2 Surface

Preparation of Patternable High Resolution and High Refractive Index Materials for AR/VR

P‐57: Preparation of Patternable High Resolution and High Refractive Index Materials for AR/VR

P‐54: Development of Heat Free / Low Temperature Process High Refractive Index Materials for Display

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Product

Resources

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Fabrication of DNA Nanowires by Orthogonal Self-Assembly and DNA Intercalation on a Au Patterned Si/SiO₂ Surface