Methods for reducing and directly controlling the speed of DNA through a nanopore are
needed to enhance sensing performance for direct strand sequencing and …

Example devices include a cis well associated with a cis electrode, a trans well associated
with a trans electrode, and a field effect transistor (FET) positioned between the cis well and …

Fabricating a nanopore sensor includes depositing a first and second oxide layers on first
and second sides of a sapphire substrate. The second oxide layer is patterned to form an …

Devices and methods of using the devices are disclosed which can provide scalability,
improved sensitivity and reduced noise for sequencing polynucleotide. Examples of the …

The present disclosure provides a fluid sensor and a method for fabricating a fluid sensor.
The fluid sensor includes a substrate including a first material and having a first surface and …

Example devices include a cis well associated with a cis electrode, a trans well associated
with a trans electrode, and a field effect transistor (FET) positioned between the cis well and …

Methods are provided for manufacturing well-controlled, solid-state nanopores and arrays of
well-controlled, solid-state nanopores by a cyclic process including atomic layer deposition …

Described herein are nanopore devices as well as methods for assembling a nanopore
device including one or more nanopores that can be used to detect molecules such as …

The fabrication process is shown in Figure S1 (also presented elsewhere 1, 2). First, a three
film stack was deposited on one side of a 4 inch silicon wafer: 400nm-thick LPCVD SiN …