Abstract: A thin film semiconductor device has a semiconductor layer including a composite/blend/mixture of an amorphous/nanocrystalline semiconductor ionic metal oxide and an amorphous/nanocrystalline non-semiconducting covalent metal oxide. A pair of terminals is positioned in communication with the semiconductor layer and define a semiconductive channel, and agate terminal is positioned in communication with the semiconductive channel and further positioned to control conduction of the channel. The invention further includes a method of depositing the mixture including using nitrogen during the deposition process to control the carrier concentration in the resulting semiconductor layer.

Abstract: A thin film circuit includes a thin film transistor with a metal oxide semiconductor channel having a conduction band minimum (CBM) with a first energy level. The transistor further includes a layer of passivation material covering at least a portion of the metal oxide semiconductor channel. The passivation material has a conduction band minimum (CBM) with a second energy level. The second energy level being lower than, equal to, or no more than 0.5 eV above the first energy level. The circuit is used for an electronic device including any one of an AMLCD, AMOLED, AMLED, AMEPD.

Abstract: A process of fabricating a flexible TFT back-panel on a glass support includes a step of providing a flat glass support member sufficiently thick to prevent bending during the processing. A layer of etch stop material is positioned on the upper surface of the glass support member and an insulating buffer layer is positioned on the layer of etch stop material. A TFT back-panel is positioned on the insulating buffer layer and a flexible plastic carrier is affixed to the TFT back-panel. The glass support member is etched away, whereby a flexible TFT back-panel is provided. The TFT back-panel can include a matrix of either OLED cells or LCD cells.

Abstract: A method of fabricating a TFT and IPS with reduced masking operations includes a substrate, a gate, a layer of gate dielectric on the gate and surrounding substrate surface and a semiconducting metal oxide on the gate dielectric. A channel protection layer overlies the gate to define a channel area in the semiconducting metal oxide. A S/D metal layer is patterned on the channel protection layer and a portion of the exposed semiconducting metal oxide to define an IPS area. An organic dielectric material is patterned on the S/D terminals and at an opposed side of the IPS area. The S/D metal is etched to expose the semiconducting metal oxide defining a first IPS electrode. A passivation layer covers the first electrode and a layer of transparent conductive material is patterned on the passivation layer to define a second IPS electrode overlying the first electrode.

Abstract: A method of fabricating a pixelated projector display includes providing a wafer with a supporting substrate, a first semiconductive layer, an emission layer, and a second semiconductive layer. The wafer is patterned into an array of LEDs/LDs and a planarization layer is deposited over the array. One via for each LED/LD element is formed through the planarization layer. A MOTFT backplane is positioned on the planarization layer, one driver circuit in controlling electrical communication with each via through the planarization layer. A passivation layer is deposited over the MOTFT backplane and heat plugs are extended through the passivation layer, the MOTFT backplane, the planarization layer, and the III-V LED/LD wafer partially through the first semiconductive layer to thermally couple heat from the array of LEDs/LDs to the surface of the passivation layer. An upper end of the heat plugs is accessible for thermal coupling to a heat spreader and/or a heatsink.

Abstract: A method of forming ohmic source/drain contacts in a metal oxide semiconductor thin film transistor includes providing a gate, a gate dielectric, a high carrier concentration metal oxide semiconductor active layer with a band gap and spaced apart source/drain metal contacts in a thin film transistor configuration. The spaced apart source/drain metal contacts define a channel region in the active layer. An oxidizing ambient is provided adjacent the channel region and the gate and the channel region are heated in the oxidizing ambient to reduce the carrier concentration in the channel area. Alternatively or in addition each of the source/drain contacts includes a very thin layer of low work function metal positioned on the metal oxide semiconductor active layer and a barrier layer of high work function metal is positioned on the low work function metal.

Abstract: A thin film semiconductor device has a semiconductor layer including a mixture of an amorphous semiconductor ionic metal oxide and an amorphous insulating covalent metal oxide. A pair of terminals is positioned in communication with the semiconductor layer and define a conductive channel, and a gate terminal is positioned in communication with the conductive channel and further positioned to control conduction of the channel. The invention further includes a method of depositing the mixture including using nitrogen during the deposition process to control the carrier concentration in the resulting semiconductor layer.

Abstract: A metal oxide thin film transistor includes a metal oxide semiconductor channel with the metal oxide semiconductor having a conduction band with a first energy level. The transistor further includes a layer of passivation material covering at least a portion of the metal oxide semiconductor channel. The passivation material has a conduction band with a second energy level equal to, or less than 0.5 eV above the first energy level.

Abstract: A method of fabricating a high mobility semiconductor metal oxide thin film transistor including the steps of depositing a layer of semiconductor metal oxide material, depositing a blanket layer of etch-stop material on the layer of MO material, and patterning a layer of source/drain metal on the blanket layer of etch-stop material including etching the layer of source/drain metal into source/drain terminals positioned to define a channel area in the semiconductor metal oxide layer. The etch-stop material being electrically conductive in a direction perpendicular to the plane of the blanket layer at least under the source/drain terminals to provide electrical contact between each of the source/drain terminals and the layer of semiconductor metal oxide material. The etch-stop material is also chemical robust to protect the layer of semiconductor metal oxide channel material during the etching process.

Abstract: A thin film semiconductor device has a semiconductor layer including a mixture of an amorphous semiconductor ionic metal oxide and an amorphous insulating covalent metal oxide. A pair of terminals is positioned in communication with the semiconductor layer and define a conductive channel, and a gate terminal is positioned in communication with the conductive channel and further positioned to control conduction of the channel. The invention further includes a method of depositing the mixture including using nitrogen during the deposition process to control the carrier concentration in the resulting semiconductor layer.

Abstract: A method of fabricating metal oxide TFTs on transparent substrates includes the steps of positioning an opaque gate metal area on the front surface of the substrate, depositing transparent gate dielectric and transparent metal oxide semiconductor layers overlying the gate metal and a surrounding area, depositing transparent passivation material on the semiconductor material, depositing photoresist on the passivation material, exposing and developing the photoresist to remove exposed portions, etching the passivation material to leave a passivation area defining a channel area, depositing transparent conductive material over the passivation area, depositing photoresist over the conductive material, exposing and developing the photoresist to remove unexposed portions, and etching the conductive material to leave source and drain areas on opposed sides of the channel area.

Abstract: A method of fabricating a pixelated imager includes providing a substrate with bottom contact layer and sensing element blanket layers on the contact layer. The blanket layers are separated into an array of sensing elements by trenches isolating adjacent sensing elements. A sensing element electrode is formed adjacent each sensing element overlying a trench and defining a TFT. A layer of metal oxide semiconductor (MOS) material is formed on a dielectric layer overlying the electrodes and on an exposed upper surface of the blanket layers defining the sensing element adjacent each TFT. A layer of metal is deposited on each TFT and separated into source/drain electrodes on opposite sides of the sensing element electrode. The metal forming one of the S/D electrodes contacts the MOS material overlying the exposed surface of the semiconductor layer, whereby each sensing element in the array is electrically connected to the adjacent TFT by the MOS material.

Abstract: A method of forming a gate dielectric in each MOTFT of an active matrix includes depositing a layer of gate metal on a substrate and patterning the gate metal to define a matrix of MOTFTs each including a gate electrode with all gate electrodes in each column connected together by a gate metal line and the line in each column connected at one end to the line in the next adjacent column by a gate metal bridging portion. The gate metal is anodized to form a layer of gate dielectric material. A layer of semiconductor metal oxide is deposited over the anodized gate metal and patterned to define an active layer for each MOTFT. Source/drain electrodes are formed on the layer of metal oxide for each MOTFT, and a laser is used to cut the bridging portion electrically connecting each gate metal line to the next adjacent gate metal line.

Abstract: Two-terminal electronic devices, such as photodetectors, photovoltaic devices and electroluminescent devices, are provided. The devices include a first electrode residing on a substrate, wherein the first electrode comprises a layer of metal; an I-layer comprising an inorganic insulating or broad band semiconducting material residing on top of the first electrode, and aligned with the first electrode, wherein the inorganic insulating or broad band semiconducting material is a compound of the metal of the first electrode; a semiconductor layer, preferably comprising a p-type semiconductor, residing over the I-layer; and a second electrode residing over the semiconductor layer, the electrode comprising a layer of a conductive material. The band gap of the material of the semiconductor layer, is preferably smaller than the band gap of the I-layer material. The band gap of the material of the I-layer is preferably greater than 2.5 eV.

Abstract: A thin film semiconductor device has a semiconductor layer including a mixture of an amorphous semiconductor ionic metal oxide and an amorphous insulating covalent metal oxide. A pair of terminals is positioned in communication with the semiconductor layer and define a conductive channel, and a gate terminal is positioned in communication with the conductive channel and further positioned to control conduction of the channel. The invention further includes a method of depositing the mixture including using nitrogen during the deposition process to control the carrier concentration in the resulting semiconductor layer.

Abstract: A method of fabricating a stable high mobility amorphous MOTFT includes a step of providing a substrate with a gate formed thereon and a gate dielectric layer positioned over the gate. A carrier transport structure is deposited by sputtering on the gate dielectric layer. The carrier transport structure includes a layer of amorphous high mobility metal oxide adjacent the gate dielectric and a relatively inert protective layer of material deposited on the layer of amorphous high mobility metal oxide both deposited without oxygen and in situ. The layer of amorphous metal oxide has a mobility above 40 cm2/Vs and a carrier concentration in a range of approximately 1018 cm?3 to approximately 5×1019 cm?3. Source/drain contacts are positioned on the protective layer and in electrical contact therewith.

Abstract: A full-color AM OLED includes a transparent substrate, a color filter positioned on an upper surface of the substrate, and a metal oxide thin film transistor backpanel positioned in overlying relationship on the color filter and defining an array of pixels. An array of OLEDs is formed on the backpanel and positioned to emit light downwardly through the backpanel, the color filter, and the substrate in a full-color display. Light emitted by each OLED includes a first emission band with wavelengths extending across the range of two of the primary colors and a second emission band with wavelengths extending across the range of the remaining primary color. The color filter includes for each pixel, two zones separating the first emission band into two separate primary colors and a third zone passing the second emission band.

Abstract: A metal oxide thin film transistor includes a metal oxide semiconductor channel with the metal oxide semiconductor having a conduction band with a first energy level. The transistor further includes a layer of passivation material covering at least a portion of the metal oxide semiconductor channel. The passivation material has a conduction band with a second energy level equal to, or less than 0.5 eV above the first energy level.

Abstract: A method of fabricating a pixelated imager includes providing a substrate with bottom contact layer and sensing element blanket layers on the contact layer. The blanket layers are separated into an array of sensing elements by trenches isolating adjacent sensing elements. A sensing element electrode is formed adjacent each sensing element overlying a trench and defining a TFT. A layer of metal oxide semiconductor (MOS) material is formed on a dielectric layer overlying the electrodes and on an exposed upper surface of the blanket layers defining the sensing element adjacent each TFT. A layer of metal is deposited on each TFT and separated into source/drain electrodes on opposite sides of the sensing element electrode. The metal forming one of the S/D electrodes contacts the MOS material overlying the exposed surface of the semiconductor layer, whereby each sensing element in the array is electrically connected to the adjacent TFT by the MOS material.

Abstract: A method of forming ohmic source/drain contacts in a metal oxide semiconductor thin film transistor includes providing a gate, a gate dielectric, a high carrier concentration metal oxide semiconductor active layer with a band gap and spaced apart source/drain metal contacts in a thin film transistor configuration. The spaced apart source/drain metal contacts define a channel region in the active layer. An oxidizing ambient is provided adjacent the channel region and the gate and the channel region are heated in the oxidizing ambient to reduce the carrier concentration in the channel area. Alternatively or in addition each of the source/drain contacts includes a very thin layer of low work function metal positioned on the metal oxide semiconductor active layer and a barrier layer of high work function metal is positioned on the low work function metal.