Subnanometer structure and function from ion beams through complex fluidics to fluorescent particles

The vertical dimensions of complex nanostructures determine the functions of diverse nanotechnologies. In this paper, we investigate the unknown limits of such structure-function relationships at subnanometer scales. We begin with a quantitative evaluation of measurement uncertainty from atomic forc...

Full description

Saved in:
Bibliographic Details
Published in:Lab on a chip 2017-12, Vol.18 (1), p.139-152
Main Authors: Liao, Kuo-Tang, Schumacher, Joshua, Lezec, Henri J, Stavis, Samuel M
Format: Article
Language:English
Subjects:
Atomic force microscopy
Atomic structure
Fluidics
Fluorescent indicators
Gallium
Hard materials
Ion beams
Microscopy
Nanofluids
Nanoparticles
Optical microscopy
Particle beams
Particle tracking
Particulate emissions
Quantitative analysis
Rapid prototyping
Reference materials
Silicon dioxide
Silicon nitride
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The vertical dimensions of complex nanostructures determine the functions of diverse nanotechnologies. In this paper, we investigate the unknown limits of such structure-function relationships at subnanometer scales. We begin with a quantitative evaluation of measurement uncertainty from atomic force microscopy, which propagates through our investigation from ion beam fabrication to fluorescent particle characterization. We use a focused beam of gallium ions to subtractively pattern silicon surfaces, and silicon nitride and silicon dioxide films. Our study of material responses quantifies the atomic limits of forming complex topographies with subnanometer resolution of vertical features over a wide range of vertical and lateral dimensions. Our results demonstrate the underutilized capability of this standard system for rapid prototyping of subnanometer structures in hard materials. We directly apply this unprecedented dimensional control to fabricate nanofluidic devices for the analytical separation of colloidal nanoparticles by size exclusion. Optical microscopy of single nanoparticles within such reference materials establishes a subnanometer limit of the fluidic manipulation of particulate matter and enables critical-dimension particle tracking with subnanometer accuracy. After calibrating for optical interference within our multifunctional devices, which also enables device metrology and integrated spectroscopy, we reveal an unexpected relationship between nanoparticle size and emission intensity for common fluorescent probes. Emission intensity increases supervolumetrically with nanoparticle diameter and then decreases as nanoparticles with different diameters photobleach to similar values of terminal intensity. We propose a simple model to empirically interpret these surprising results. Our investigation enables new control and study of structure-function relationships at subnanometer scales.
ISSN:1473-0197
1473-0189
DOI:10.1039/c7lc01047h