A surface of a copper (Cu) electrode is modified by a combination of preliminary oxidation treatment and grafting of a bifunctional self-assembled monolayer based on fluorobiphenylthiol (FBPS) or biphenylthiol (BPS). Under these conditions, a dinaphtho[2,3-b:2′,3′-f]thieno[3,2-b]thiophene (DNTT)-based diode exhibits high mobility (0.35 cm.sup.2.Math.V.sup.−1.Math.s.sup.−1) due to the formation of an organized assembly of FBPS on copper oxide that has been partially reduced to Cu.sub.2O. This organization controls that of a semiconductor film. On the other hand, the same treatment of a copper electrode with BPS molecules does not function due to the disorganization of both the BPS self-assembled monolayer (SAM) and the DNTT film. These results suggest that a monolayer of dipole-oriented molecules lowers an injection barrier and determines the semiconductor organization, thereby improving the performance of derived electronic parts.

A surface of a copper (Cu) electrode is modified by a combination of preliminary oxidation treatment and grafting of a bifunctional self-assembled monolayer based on fluorobiphenylthiol (FBPS) or biphenylthiol (BPS). Under these conditions, a dinaphtho[2,3-b:2′,3′-f]thieno[3,2-b]thiophene (DNTT)-based diode exhibits high mobility (0.35 cm.sup.2.Math.V.sup.−1.Math.s.sup.−1) due to the formation of an organized assembly of FBPS on copper oxide that has been partially reduced to Cu.sub.2O. This organization controls that of a semiconductor film. On the other hand, the same treatment of a copper electrode with BPS molecules does not function due to the disorganization of both the BPS self-assembled monolayer (SAM) and the DNTT film. These results suggest that a monolayer of dipole-oriented molecules lowers an injection barrier and determines the semiconductor organization, thereby improving the performance of derived electronic parts.

A Schottky diode comprises: a first electrode; a second electrode; and a body of semiconductive material connected to the first electrode at a first interface and connected to the second electrode at a second interface, wherein the first interface comprises a first planar region lying in a first plane and the first electrode has a first projection onto the first plane in a first direction normal to the first plane, the second interface comprises a second planar region lying in a second plane and the second electrode has a second projection onto the first plane in said first direction, at least a portion of the second projection lies outside the first projection, said second planar region is offset from the first planar region in said first direction, and one of the first interface and the second interface provides a Schottky contact.

Provided are an optical sensor including graphene quantum dots and an image sensor including an optical sensing layer. The optical sensor may include a graphene quantum dot layer that includes a plurality of first graphene quantum dots bonded to a first functional group and a plurality of second graphene quantum dots bonded to a second functional group that is different from the first functional group. An absorption wavelength band of the optical sensor may be adjusted based on types of functional groups bonded to the respective graphene quantum dots and/or sizes of the graphene quantum dots.

A thin film transistor includes a gate electrode, a insulating medium layer and at least one Schottky diode unit. The at least one Schottky diode unit is located on a surface of the insulating medium layer. The at least one Schottky diode unit includes a first electrode, a semiconductor structure and a second electrode. The semiconductor structure comprising a first end and a second end. The first end is laid on the first electrode, the second end is located on the surface of the insulating medium layer. The semiconducting structure includes a nano-scale semiconductor structure. The second electrode is located on the second end.

A nanostructure device is provided and performs dual functions as a nano-switching/sensing device. The nanostructure device includes a doped semiconducting substrate, an insulating layer disposed on the doped semiconducting substrate, an electrode formed on the insulating layer, and at least one polymer nanofiber deposited on the electrode. The at least one polymer nanofiber provides an electrical connection between the electrode and the substrate and is the electroactive element in the device.

A Schottky diode comprises: a first electrode; a second electrode; and a body of semiconductive material connected to the first electrode at a first interface and connected to the second electrode at a second interface, wherein the first interface comprises a first planar region lying in a first plane and the first electrode has a first projection onto the first plane in a first direction normal to the first plane, the second interface comprises a second planar region lying in a second plane and the second electrode has a second projection onto the first plane in said first direction, at least a portion of the second projection lies outside the first projection, said second planar region is offset from the first planar region in said first direction, and one of the first interface and the second interface provides a Schottky contact.

A Schottky diode comprises: a first electrode; a second electrode; and a body of semiconductive material connected to the first electrode at a first interface and connected to the second electrode at a second interface, wherein the first interface comprises a first planar region lying in a first plane and the first electrode has a first projection onto the first plane in a first direction normal to the first plane, the second interface comprises a second planar region lying in a second plane and the second electrode has a second projection onto the first plane in said first direction, at least a portion of the second projection lies outside the first projection, said second planar region is offset from the first planar region in said first direction, and one of the first interface and the second interface provides a Schottky contact.

Provided are an optical sensor including graphene quantum dots and an image sensor including an optical sensing layer. The optical sensor may include a graphene quantum dot layer that includes a plurality of first graphene quantum dots bonded to a first functional group and a plurality of second graphene quantum dots bonded to a second functional group that is different from the first functional group. An absorption wavelength band of the optical sensor may be adjusted based on types of functional groups bonded to the respective graphene quantum dots and/or sizes of the graphene quantum dots.

The present disclosure is directed toward carbon based diodes, carbon based resistive change memory elements, resistive change memory having resistive change memory elements and carbon based diodes, methods of making carbon based diodes, methods of making resistive change memory elements having carbon based diodes, and methods of making resistive change memory having resistive change memory elements having carbons based diodes. The carbon based diodes can be any suitable type of diode that can be formed using carbon allotropes, such as semiconducting single wall carbon nanotubes (s-SWCNT), semiconducting Buckminsterfullerenes (such as C60 Buckyballs), or semiconducting graphitic layers (layered graphene). The carbon based diodes can be pn junction diodes, Schottky diodes, other any other type of diode formed using a carbon allotrope. The carbon based diodes can be placed at any level of integration in a three dimensional (3D) electronic device such as integrated with components or wiring layers.