about
Rapid structural analysis of nanomaterials in aqueous solutions.Roles of vacuum tunnelling and contact mechanics in single-molecule thermopower.Detecting Single-Nucleotides by Tunneling Current Measurements at Sub-MHz Temporal Resolution.Identifying molecular signatures in metal-molecule-metal junctions.Detection of post-translational modifications in single peptides using electron tunnelling currents.Discriminating single-bacterial shape using low-aspect-ratio pores.Identification of Individual Bacterial Cells through the Intermolecular Interactions with Peptide-Functionalized Solid-State Pores.Fast and low-noise tunnelling current measurements for single-molecule detection in an electrolyte solution using insulator-protected nanoelectrodes.Self-organized interconnect method for molecular devices.Polaron coupling in graphene field effect transistors on patterned self-assembled monolayer.Particle Trajectory-Dependent Ionic Current Blockade in Low-Aspect-Ratio Pores.Quantitative analysis of DNA with single-molecule sequencing.Remote heat dissipation in atom-sized contacts.Temporal Response of Ionic Current Blockade in Solid-State NanoporesSelective detections of single-viruses using solid-state nanoporesIdentifying Single Viruses Using Biorecognition Solid-State NanoporesMolecule-electrode bonding design for high single-molecule conductanceIdentifying single nucleotides by tunnelling currentInelastic electron tunneling spectroscopy of single-molecule junctions using a mechanically controllable break junctionCarrier control of graphene driven by the proximity effect of functionalized self-assembled monolayersParticle Capture in Solid-State MultiporesSmall-scale culture of Plasmodium falciparum using μ-Slide Angiogenesis followed by automatic infection rate counting to assess drug effects
P50
Q38901857-4DC3AACC-06FA-492B-AC84-5641172387D6Q41840706-AFBD2754-F7CF-4135-8513-525A360B40C8Q42280007-3517CC20-2E54-417C-8679-8BE1BAB30BBCQ42965051-2432D1BE-4A7F-4802-964D-4D68CEF2D6E0Q44239636-0899A932-95E4-4B0F-8E75-251ABF1E628FQ45943012-51318D4D-8661-4C1F-8192-EC5111DCF392Q48208043-007192DC-47CC-4516-8CC9-8D6F789D3F8AQ48319089-9C1BB7AC-06CC-472C-8D51-3BA33887F7BEQ51102004-FD11465A-2FF3-404F-A830-1F772007CEC7Q53634809-2292067C-B358-4EE8-965F-16C46E033190Q53806198-9C95E9B8-0EDB-44D6-BEAE-46416BF2BA65Q55008506-7D4B5EAB-610A-4B0F-88A3-13266EE7648DQ55293951-9E2A9D65-E6A5-49EA-8668-DEBBD370BA59Q57282478-3F0BEA8E-8EB3-43DB-B7E1-5BB714E5DC26Q58618164-12F00A54-6BBA-472B-9EAA-C2426816B804Q59350070-5D1EBE98-6281-43BA-B8DC-0456D7CE52A8Q82501639-3A46D60E-C1F2-490E-941F-642B9B7D7B26Q83378037-ED49F756-1B7D-470A-89F7-BD8FE3B9F123Q84625582-F63CE14C-63A1-4E41-8B84-B8AC51A9792FQ84780212-54F64FA4-3AA5-427E-B899-0270FC589A71Q93027788-6C7CAB87-8F30-4DC4-B5AE-3A5A13424670Q93370087-FCCB0F15-403F-4272-B907-07E36F6C521D
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Kazumichi Yokota
@ast
Kazumichi Yokota
@en
Kazumichi Yokota
@es
Kazumichi Yokota
@nl
type
label
Kazumichi Yokota
@ast
Kazumichi Yokota
@en
Kazumichi Yokota
@es
Kazumichi Yokota
@nl
prefLabel
Kazumichi Yokota
@ast
Kazumichi Yokota
@en
Kazumichi Yokota
@es
Kazumichi Yokota
@nl
P106
P31
P496
0000-0002-8590-2737