Molecular electronic component used to construct nanoelectronic circuits, molecular electronic component, electronic circuit and method for producing the same
First Claim
1. A molecular electronic device for constructing nanoelectronic circuits, having a redox-active moiety having an electron donor (D) and an electron acceptor (A), the electron donor and the electron acceptor (A) having a respective contact spot (K1, K2) for forming connections with other devices, and the contact spots (K 1, K2) facilitating charge transport to the device and away from the device, wherein the respective contact spot (K 1, K2) of electron donor (D) and electron acceptor (A) is a permanent contact spot for mediating the charge transport across a permanent chemical bond, the contact spot respectively comprising one of the binding partners of the chemical bond-. and wherein the permanent contact spots are adapted to forming a nucleic acid interaction a stable interaction between proteins, or an antigen-antibody interaction.
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Accused Products
Abstract
A molecular electronic device for constructing nanoelectronic circuits comprises a redox-active moiety having an electron donor (D) and an electron acceptor (A), the electron donor and the electron acceptor (A) having a respective contact spot (K1, K2) for forming connections with other devices, and the contact spots (K1, K2) facilitating charge transport to the device and away from the device. In particular, the respective contact spot (K1, K2) of electron donor (D) and electron acceptor (A) is a permanent contact spot for mediating the charge transport across a permanent chemical bond, the contact spot respectively comprising one of the binding partners of the chemical bond. Multiple such devices can be combined via the contact spots to form a module or an electronic circuit.
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Citations
36 Claims
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1. A molecular electronic device for constructing nanoelectronic circuits, having a redox-active moiety having an electron donor (D) and an electron acceptor (A), the electron donor and the electron acceptor (A) having a respective contact spot (K1, K2) for forming connections with other devices, and the contact spots (K 1, K2) facilitating charge transport to the device and away from the device,
wherein the respective contact spot (K 1, K2) of electron donor (D) and electron acceptor (A) is a permanent contact spot for mediating the charge transport across a permanent chemical bond, the contact spot respectively comprising one of the binding partners of the chemical bond-. and wherein the permanent contact spots are adapted to forming a nucleic acid interaction a stable interaction between proteins, or an antigen-antibody interaction.
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2. A molecular electronic device for constructing nanoelectronic circuits, having a redox-active moiety having an electron donor (D) and an electron acceptor (A), the electron donor (D) and the electron acceptor (A) having a respective contact spot (K1, K2) for forming connections with other devices, and the contact spots (K1, K2) facilitating charge transport to the device and away from the device,
wherein a first one of the contact spots ( FIG. 3 a:- K2) of electron donor (D) and electron acceptor (A) is a permanent contact spot for mediating the charge transport across a permanent chemical bond, the first contact spot comprising one of the binding partners of the chemical bond, and wherein a second one of the contact spots (
FIG. 3 a;
K1) of electron donor (D) and electron acceptor (A) is a temporary contact spot for mediating the charge transport without permanently attaching a substance to the contact spot. - View Dependent Claims (3, 4)
- K2) of electron donor (D) and electron acceptor (A) is a permanent contact spot for mediating the charge transport across a permanent chemical bond, the first contact spot comprising one of the binding partners of the chemical bond, and wherein a second one of the contact spots (
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33. A method for producing an electronic circuit, wherein
a conductive surface is provided, and in solution at least one first component part is added and connected to the conductive surface, at least one further component part is added, the first and the further component part having a respective permanent contact spot with mutually assigned binding partners, such that the first and the further component part connect in the solution at the corresponding contact spots, the step of adding further component parts is repeated, the further component part and one of the already connected component parts having a respective permanent contact spot with corresponding binding partners, such that the component parts connect in the solution at the corresponding contact spots, until a number of predetermined component parts is connected.
Specification