Quantum dot gate FETs and circuits configured as biosensors and gene sequencers
First Claim
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1. A bio sensor device comprising:
- a field-effect transistor (FET) structure having a source, a drain, a gate region and a semiconductor substrate, wherein the semiconductor substrate includes a transport channel between the source and the drain and wherein the transport channel is configured to be controlled via a voltage applied to the gate region, andwherein the gate region includes a multilayer structure having;
a first layer located adjacent to the transport channel, wherein the first layer is at least one of an insulator, a wide energy gap lattice matched semiconductor and a pseudomorphic semiconductor layer, wherein the multilayer structure includes at least one layer of cladded quantum dots having an outer cladding layer, wherein the at least one layer of cladded quantum dots is constructed from the group comprised of SiOx-cladded Si nanocrystal quantum dots and GeOx-cladded Ge nanocrystal quantum dots, wherein the outer cladding layer is functionalized with a chemical group,wherein the chemical group is bonded to recognition elements selected from a group comprising DNA, RNA, miRNA and antibodies, and wherein the recognition elements are bonded with target biomarkers including at least one of proteins, enzymes, and analytes; and
a top gate electrode fixed above the outer cladding layer to be in contact with a solution containing at least one target molecule.
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Abstract
Quantum dot (QD) gate FETs and the use of quantum dot (QD) gate FETs for the purpose of sensing analytes and proteins is disclosed and described. Analytes, proteins, miRNAs, and DNAs functionalized to the QDs change the charge density in the gate and hence the current-voltage characteristics. In one embodiment, QD-FETs, such as 3-state configurations, the binding of chemical and biological species change the drain current-gate voltage characteristics resulting in detection. In one embodiment, DNA sensing is done by its binding to an existing reference DNA functionalized on to quantum dots which are located in the gate region of the FET.
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Citations
5 Claims
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1. A bio sensor device comprising:
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a field-effect transistor (FET) structure having a source, a drain, a gate region and a semiconductor substrate, wherein the semiconductor substrate includes a transport channel between the source and the drain and wherein the transport channel is configured to be controlled via a voltage applied to the gate region, and wherein the gate region includes a multilayer structure having; a first layer located adjacent to the transport channel, wherein the first layer is at least one of an insulator, a wide energy gap lattice matched semiconductor and a pseudomorphic semiconductor layer, wherein the multilayer structure includes at least one layer of cladded quantum dots having an outer cladding layer, wherein the at least one layer of cladded quantum dots is constructed from the group comprised of SiOx-cladded Si nanocrystal quantum dots and GeOx-cladded Ge nanocrystal quantum dots, wherein the outer cladding layer is functionalized with a chemical group, wherein the chemical group is bonded to recognition elements selected from a group comprising DNA, RNA, miRNA and antibodies, and wherein the recognition elements are bonded with target biomarkers including at least one of proteins, enzymes, and analytes; and a top gate electrode fixed above the outer cladding layer to be in contact with a solution containing at least one target molecule. - View Dependent Claims (2)
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3. A biosensor device configured as a field effect transistor (FET) structure having a 3-state behavior, the biosensor device comprising:
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a source, a drain and a gate region over a semiconductor substrate, a transport channel located between the source and the drain and under the gate region, wherein the gate region is a multilayer structure having; a first layer, identified as a barrier layer, located adjacent the transport channel and selected from the group consisting of a thin insulator, a wide energy gap semiconductor and a lattice-matched pseudomorphic semiconductor layer, wherein the multilayer structure includes a first layer and a second layer of SiOx-cladded Si nanocrystal quantum dots having an outer cladding layer, wherein the first layer and second layer of SiOx-cladded Si nanocrystal quantum dots have a thin cladding of about 1-2 nm, and Si cores of about 2-8 nm, wherein the outer cladding layer of the second layer is functionalized with a chemical group, that is bonded to recognition elements constructed from at least one of DNA, RNA, miRNA and antibodies, wherein the recognition elements are bonded with target biomarkers including at least one of proteins, enzymes, DNA, RNA, miRNAs, and analytes, a top gate electrode located above the second layer in a solution containing at least one target molecule, wherein the top gate-electrode is located over the functionalized outer cladding layer of the second layer, which is configured to controls the amount of charge located in the first layer and second layer of SiOx-cladded Si nanocrystal quantum dots, thereby rendering the field-effect transistor to serve as a 3-state device manifesting an intermediate state ‘
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in the transfer (drain current-gate voltage) characteristic. - View Dependent Claims (4)
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5. A field-effect transistor structure having a 3-state behavior and comprising a coupled quantum well channel in a spatial wavefunction switched configuration, comprising:
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a source, a drain, and a gate region, wherein the gate region comprises a multilayer structure, a first thin layer comprising of SiO2, or a wide energy gap lattice-matched semiconductor layer comprising of ZnMgS or ZnBeMgSSe of 10-100 Å
in thickness, wherein the first thin layer is adjacent to a semiconductor region between the source and drain regions, wherein the multilayer structure has at least two layers of cladded quantum dots deposited on it, a top surface of the at least two layers of cladded quantum dots has a gate semiconductor or metal layer, the at least two layers of cladded quantum dots comprised of SiOx-cladded Si nanocrystals, and the semiconductor region under the first thin layer comprises the coupled quantum well channel,wherein the coupled quantum well channel is comprised of a strained Si layer serving as well #1, a SiGe barrier, and second Si quantum well #2, a second barrier layer located under the Si quantum well #2 which is constructed from SiGe and on a Si substrate, wherein an outer cladding layer of one of the at least two layers of cladded quantum dots is functionalized with a chemical group bonded to recognition elements constructed from at least one of DNA, RNA, miRNA and antibodies, wherein the recognition elements are bonded with target biomarkers that include at least one of proteins, enzymes, and analytes, a top gate electrode located above the functionalized outer cladding layer in a solution containing target molecules, and a gate control electrode over the functionalized outer cladding layer, which is configured to controls the amount of charge located in the at least two layers of cladded quantum dots, thereby rendering the field-effect transistor to serve as a sensor configured to use changes in drain current-gate voltage or drain current-drain voltage characteristics.
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Specification