International Business Machines Corporation

Globalfoundries Inc.

Deqiang Wang

Gustavo Alejandro Stolovitzky

Chao Wang

Hongbo Peng

Qinghuang Lin

Ali Afzali-Ardakani

Binquan Luan

Ajay K Royyuru

Stephen Mark Rossnagel

Shu-Jen Han

George Frederick Walker

Stefan Harrer

Jingwei Bai

Gustavo A Stolovitky

A device for passing a biopolymer molecule includes a nanochannel formed between a surface relief structure, a patterned layer forming sidewalls of the nanochannel and a sealing layer formed over the patterned layer to encapsulate the nanochannel. The surface relief structure includes a three-dimensionally rounded surface that reduces a channel dimension of the nanochannel at a portion of nanochannel and gradually increases the dimension along the nanochannel toward an opening position, which is configured to receive a biopolymer.

Nanofluidic channels with gradual depth change for reducing entropic barrier of biopolymers

A mechanism is provided for reducing entropy of a polyelectrolyte before the polyelectrolyte moves through a nanopore. A free-standing membrane has the nanopore formed through the membrane. An agarose gel is formed onto either and/or both sides of the nanopore in the membrane. The agarose gel is a porous material. The polyelectrolyte is uncoiled by driving the polyelectrolyte through the porous material of the agarose gel via an electric field. Driving the polyelectrolyte, having been uncoiled and linearized by the agarose gel, into the nanopore is for sequencing.

Reduction of entropic barrier of polyelectrolyte molecules in a nanopore device with agarose gel

A technique includes forming a gradient channel with width and depth gradients. A mask is disposed on top of a substrate. The mask is patterned with at least one elongated channel pattern having different elongated channel pattern widths. A channel is etched in the substrate in a single etching step, the channel having a width gradient and a corresponding depth gradient both simultaneously etched in the single etching step according to the different elongated channel pattern widths in the mask.

Nanochannel device with three dimensional gradient by single step etching for molecular detection

Techniques for increasing the capture zone in nano and microchannel-based polymer testing structures using concentric arrangements of nanostructures, such as nanopillars are provided. In one aspect, a testing structure for testing polymers is provided that includes a first fluid reservoir and a second fluid reservoir formed in an electrically insulating substrate; at least one channel formed in the insulating substrate that interconnects the first fluid reservoir and the second fluid reservoir; and an arrangement of nanostructures within either the first fluid reservoir or the second fluid reservoir wherein the nanostructures are arranged so as to form multiple concentric circles inside either the first fluid reservoir or the second fluid reservoir with each of the concentric circles being centered at an entry point of the channel. A method of analyzing a polymer using the testing structure is also provided.

Increasing the capture zone by nanostructure patterns

A technique for a nanodevice is provided. The nanodevice includes a fluidic cell, and a membrane dividing the fluidic cell. A nanopore is formed through the membrane, and the nanopore is coated with an organic compound. A first part of the organic compound binds to a surface of the nanopore and a second part of the organic compound is exposed freely inside of the nanopore. The second part of the organic compound is configured to be switched among a first neutral hydrophilic end group, a second negatively charged hydrophilic end group, and a third neutral hydrophobic end group based on a switching mechanism.

Functionally switchable self-assembled coating compound for controlling translocation of molecule through nanopores

A technique is provided for a structure. A substrate has a nanopillar vertically positioned on the substrate. A bottom layer is formed beneath the substrate. A top layer is formed on top of the substrate and on top of the nanopillar, and a cover layer covers the top layer and the nanopillar. A window is formed through the bottom layer and formed through the substrate, and the window ends at the top layer. A nanopore is formed through the top layer by removing the cover layer and the nanopillar.

Fabricating self-formed nanometer pore array at wafer scale for DNA sequencing

A mechanism is provided for forming a nanodevice. A reservoir is filled with a conductive fluid, and a membrane is formed to separate the reservoir in the nanodevice. The membrane includes an electrode layer having a tunneling junction formed therein. The membrane is formed to have a nanopore formed through one or more other layers of the membrane such that the nanopore is aligned with the tunneling junction of the electrode layer. The tunneling junction of the electrode layer is narrowed to a narrowed size by electroplating or electroless deposition. When a voltage is applied to the electrode layer, a tunneling current is generated by a base in the tunneling junction to be measured as a current signature for distinguishing the base. When an organic coating is formed on an inside surface of the tunneling junction, transient bonds are formed between the electrode layer and the base.

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Ossining, NY, United States of America

Deqiang Wang