摘要:
A sensor for biomolecules includes a silicon fin comprising undoped silicon; a source region adjacent to the silicon fin, the source region comprising heavily doped silicon; a drain region adjacent to the silicon fin, the drain region comprising heavily doped silicon of a doping type that is the same doping type as that of the source region; and a layer of a gate dielectric covering an exterior portion of the silicon fin between the source region and the drain region, the gate dielectric comprising a plurality of antibodies, the plurality of antibodies configured to bind with the biomolecules, such that a drain current flowing between the source region and the drain region varies when the biomolecules bind with the antibodies.
摘要:
A method for sensing biomolecules in an electrolyte includes exposing a gate dielectric surface of a sensor comprising a silicon fin to the electrolyte, wherein the gate dielectric surface comprises a dielectric material and antibodies configured to bind with the biomolecules; applying a gate voltage to an electrode immersed in the electrolyte; and measuring a change in a drain current flowing in the silicon fin; and determining an amount of the biomolecules that are present in the electrolyte based on the change in the drain current.
摘要:
A method of using a sensor comprising a field effect transistor (FET) embedded in a nanopore includes placing the sensor in an electrolyte comprising at least one of biomolecules and deoxyribonucleic acid (DNA); placing an electrode in the electrolyte; applying a gate voltage in the sub-threshold regime to the electrode; applying a drain voltage to a drain of the FET; applying a source voltage to a source of the FET; detecting a change in a drain current in the sensor in response to the at least one of biomolecules and DNA passing through the nanopore.
摘要:
A sensor for biomolecules or charged ions includes a substrate; a first node, a second node, and a third node located in the substrate; a gate dielectric located over the substrate, the first node, the second node, and the third node; a first field effect transistor (FET), the first FET comprising a control gate located on the gate dielectric, and the first node and the second node; and a second FET, the second FET comprising a sensing surface located on the gate dielectric, and the second node and the third node, wherein the sensing surface is configured to specifically bind the biomolecules or charged ions that are to be detected.
摘要:
A compound metal comprising MOxNy which is a p-type metal having a workfunction of about 4.75 to about 5.3, preferably about 5, eV that is thermally stable on a gate stack comprising a high k dielectric and an interfacial layer is provided as well as a method of fabricating the MOxNy compound metal. Furthermore, the MOxNy metal compound of the present invention is a very efficient oxygen diffusion barrier at 1000° C. allowing very aggressive equivalent oxide thickness (EOT) and inversion layer thickness scaling below 14 Å in a p-metal oxide semiconductor (pMOS) device. In the above formula, M is a metal selected from Group IVB, VB, VIB or VIIB of the Periodic Table of Elements, x is from about 5 to about 40 atomic % and y is from about 5 to about 40 atomic %.
摘要:
A compound metal comprising TiC which is a p-type metal having a workfunction of about 4.75 to about 5.3, preferably about 5, eV that is thermally stable on a gate stack comprising a high k dielectric and an interfacial layer is provided as well as a method of fabricating the TiC compound metal. Furthermore, the TiC metal compound of the present invention is a very efficient oxygen diffusion barrier at 1000° C. allowing very aggressive equivalent oxide thickness (EOT) and inversion layer thickness scaling below 14 Å in a p-metal oxide semiconductor (pMOS) device.
摘要:
A compound metal comprising TiC which is a p-type metal having a workfunction of about 4.75 to about 5.3, preferably about 5, eV that is thermally stable on a gate stack comprising a high k dielectric and an interfacial layer is provided as well as a method of fabricating the TiC compound metal. Furthermore, the TiC metal compound of the present invention is a very efficient oxygen diffusion barrier at 1000° C. allowing very aggressive equivalent oxide thickness (EOT) and inversion layer thickness scaling below 14 Å in a p-metal oxide semiconductor (pMOS) device.