Voltage-biased solid-state nanopores are well established in their ability to detect and characterize single polymers, such as DNA, in electrolytes. The addition of a pressure gradient across the nanopore yields a second molecular driving force that provides new freedom for studying molecules in nanopores. In this work, we show that opposing pressure and voltage bias enables nanopores to detect and resolve very short DNA molecules, as well as to detect near-neutral polymers
Reports ofDNAtranslocation measurements have been increasing rapidly in recent years due to advancem...
This thesis describes experimental work on a novel type of devices capable of detecting single-(bio)...
Single molecule sensors in which nanoscale pores within biological or artificial membranes act as me...
Charged single molecules of DNA can be detected and characterized with a voltage-biased solid-state ...
Voltage biased solid-state nanopores are used to detect and characterize individual single stranded ...
Nanopores offer sensors for a broad range of nanoscale materials, in particular ones of biological o...
A mong the variety of roles for nanopores in biology, an important one is enabling polymer transport...
In the last two decades, new techniques that monitor ionic current modulations as single molecules p...
Biological molecules can be forced to pass through an aperture in a thin membrane of only several na...
Solid-state nanopores have emerged as possible candidates for next-generation DNA sequencing devices...
Solid-state nanopores have emerged as possible candidates for next-generation DNA sequencing devices...
Over the last five years, solid state nanopore technology advanced to rival biological pores as a pl...
AbstractSolid-state nanopores have received increasing interest over recent years because of their p...
Single nanopores attract a great deal of scientific interest as a basis for biosensors and as a syst...
It has recently been recognized that solid-state nanopores in single-atomic-layer graphene membranes...
Reports ofDNAtranslocation measurements have been increasing rapidly in recent years due to advancem...
This thesis describes experimental work on a novel type of devices capable of detecting single-(bio)...
Single molecule sensors in which nanoscale pores within biological or artificial membranes act as me...
Charged single molecules of DNA can be detected and characterized with a voltage-biased solid-state ...
Voltage biased solid-state nanopores are used to detect and characterize individual single stranded ...
Nanopores offer sensors for a broad range of nanoscale materials, in particular ones of biological o...
A mong the variety of roles for nanopores in biology, an important one is enabling polymer transport...
In the last two decades, new techniques that monitor ionic current modulations as single molecules p...
Biological molecules can be forced to pass through an aperture in a thin membrane of only several na...
Solid-state nanopores have emerged as possible candidates for next-generation DNA sequencing devices...
Solid-state nanopores have emerged as possible candidates for next-generation DNA sequencing devices...
Over the last five years, solid state nanopore technology advanced to rival biological pores as a pl...
AbstractSolid-state nanopores have received increasing interest over recent years because of their p...
Single nanopores attract a great deal of scientific interest as a basis for biosensors and as a syst...
It has recently been recognized that solid-state nanopores in single-atomic-layer graphene membranes...
Reports ofDNAtranslocation measurements have been increasing rapidly in recent years due to advancem...
This thesis describes experimental work on a novel type of devices capable of detecting single-(bio)...
Single molecule sensors in which nanoscale pores within biological or artificial membranes act as me...