Compact electrical switching devices with nanotube elements, and methods of making same
First Claim
1. An electrical device, comprising:
- a substrate having an upper surface;
a first active area in the substrate, comprising a first source region, a first drain region, and a first channel region disposed between the first source region and the first drain region;
a second active area in the substrate, comprising a second source region and the second drain region;
a first word line and a second word line disposed in a first plane positioned above the upper surface of the substrate, wherein the first word line is disposed over the first channel region, and the second word line is disposed over the second channel region;
a first bit line in electrical communication with the first active area, and a second bit line in electrical communication with the second active area, the first and second bit lines disposed in a second plane positioned above the first plane, wherein the first bit line is in electrical communication with the first drain region, and the second bit line is in electrical communication with the second drain region;
a first reference line disposed in a third plane positioned above the first plane; and
a first nanotube element disposed in a fourth plane positioned above the first and second planes, the first nanotube element having a first surface and extending laterally in the fourth plane parallel to a plane of the substrate,the first nanotube element being in electrical communication with the first active region, the second active region and the first reference line via electrical contacts at the first surface of the first nanotube element,the first nanotube element comprising a first region and a second region, the first and second regions having resistance states that are independently adjustable in response to electrical stimuli, the first and second regions nonvolatilely retaining said resistance states,a third active area in the substrate, the third active area comprising a third source region, the first drain region, and a third channel region disposed between the third source region and the first drain region;
a fourth active area in the substrate, the fourth active area comprising a fourth source region, the second drain region, and a fourth channel region disposed between the fourth source region and the second drain region;
a third word line disposed over the third channel region, and a fourth word line disposed over the fourth channel region, the third and fourth word lines being disposed in the first plane;
second and third reference lines disposed in the third plane;
a second nanotube element in electrical communication with the third source region and the second reference line, a resistance state of the second nanotube element being independently adjustable responsive to electrical stimulus on the third word line and at least one of the first bit line and the second reference line; and
a third nanotube element in electrical communication with the fourth source region and the third reference line, a resistance state of the third nanotube element being independently adjustable responsive to electrical stimulus on the fourth word line and at least one of the second bit line and the third reference line.
3 Assignments
0 Petitions
Accused Products
Abstract
An electrical device includes a substrate; first and second active areas; first and second word lines disposed in a first plane; first and second bit lines in a second plane and in electrical communication with first and second active areas; and a reference line disposed in a third plane. A nanotube element disposed in a fourth plane is in electrical communication with first and second active areas and the reference line via electrical connections at a first surface of the nanotube element. The nanotube element includes first and second regions having resistance states that are independently adjustable in response to electrical stimuli, wherein the first and second regions nonvolatilely retain the resistance states. Arrays of such electrical devices can be formed as nonvolatile memory devices. Methods for fabricating such devices are also disclosed.
-
Citations
8 Claims
-
1. An electrical device, comprising:
-
a substrate having an upper surface; a first active area in the substrate, comprising a first source region, a first drain region, and a first channel region disposed between the first source region and the first drain region; a second active area in the substrate, comprising a second source region and the second drain region; a first word line and a second word line disposed in a first plane positioned above the upper surface of the substrate, wherein the first word line is disposed over the first channel region, and the second word line is disposed over the second channel region; a first bit line in electrical communication with the first active area, and a second bit line in electrical communication with the second active area, the first and second bit lines disposed in a second plane positioned above the first plane, wherein the first bit line is in electrical communication with the first drain region, and the second bit line is in electrical communication with the second drain region; a first reference line disposed in a third plane positioned above the first plane; and a first nanotube element disposed in a fourth plane positioned above the first and second planes, the first nanotube element having a first surface and extending laterally in the fourth plane parallel to a plane of the substrate, the first nanotube element being in electrical communication with the first active region, the second active region and the first reference line via electrical contacts at the first surface of the first nanotube element, the first nanotube element comprising a first region and a second region, the first and second regions having resistance states that are independently adjustable in response to electrical stimuli, the first and second regions nonvolatilely retaining said resistance states, a third active area in the substrate, the third active area comprising a third source region, the first drain region, and a third channel region disposed between the third source region and the first drain region; a fourth active area in the substrate, the fourth active area comprising a fourth source region, the second drain region, and a fourth channel region disposed between the fourth source region and the second drain region; a third word line disposed over the third channel region, and a fourth word line disposed over the fourth channel region, the third and fourth word lines being disposed in the first plane; second and third reference lines disposed in the third plane; a second nanotube element in electrical communication with the third source region and the second reference line, a resistance state of the second nanotube element being independently adjustable responsive to electrical stimulus on the third word line and at least one of the first bit line and the second reference line; and a third nanotube element in electrical communication with the fourth source region and the third reference line, a resistance state of the third nanotube element being independently adjustable responsive to electrical stimulus on the fourth word line and at least one of the second bit line and the third reference line.
-
-
2. An electrical device, comprising:
-
a substrate having an upper surface; a first active area in the substrate; a second active area in the substrate; a first word line and a second word line disposed in a first plane positioned above the upper surface of the substrate; a first bit line in electrical communication with the first active area, and a second bit line in electrical communication with the second active area, the first and second bit lines disposed in a second plane positioned above the first plane, wherein at least a portion of each of first and second bit lines is arranged at an obtuse angle relative to the first and second word lines; a first reference line disposed in a third plane positioned above the first plane; and a first nanotube element disposed in a fourth plane positioned above the first and second planes, the first nanotube element having a first surface and extending laterally in the fourth plane parallel to a plane of the substrate, the first nanotube element being in electrical communication with the first active region, the second active region and the first reference line via electrical contacts at the first surface of the first nanotube element, the first nanotube element comprising a first region and a second region, the first and second regions having resistance states that are independently adjustable in response to electrical stimuli, the first and second regions nonvolatilely retaining said resistance states. - View Dependent Claims (3, 4, 5, 6)
-
-
7. An electrical device, comprising:
-
a substrate having an upper surface; a first active area in the substrate; a second active area in the substrate; a first word line and a second word line disposed in a first plane positioned above the upper surface of the substrate; a first bit line in electrical communication with the first active area, and a second bit line in electrical communication with the second active area, the first and second bit lines disposed in a second plane positioned above the first plane; a first reference line disposed in a third plane positioned above the first plane; and a first nanotube element disposed in a fourth plane positioned above the first and second planes, the first nanotube element having a first surface and extending laterally in the fourth plane parallel to a plane of the substrate, the first nanotube element being in electrical communication with the first active region, the second active region and the first reference line via electrical contacts at the first surface of the first nanotube element, the first nanotube element comprising a first region and a second region, the first and second regions having resistance states that are independent adjustable in response to electrical stimuli, the first and second regions nonvolatilely retaining said resistance states, wherein the first nanotube element extends over the first and second active areas, the first and second word lines, and the first and second bit lines.
-
-
8. A method of making an electrical device, the method comprising:
-
providing a substrate; forming first and second active areas in the substrate, where the first active area comprises a first source region, a first drain region, and a first channel region disposed between the first source region and the first drain region, and the second active are comprises a second source region, a second drain region, and a second channel region disposed between the second source region and the second drain region, the method comprising forming the first word line over the first channel region, and forming the second word line over the second channel region; forming a first word line and a second word line in a first plane positioned above the upper surface of the substrate; forming first and second bit lines in a second plane positioned above the first plane; forming a first reference line in a third plane positioned above the upper surface of the substrate; forming a first nanotube element in a fourth plane positioned above the first and second planes, the first nanotube element having a first surface and extending laterally in the fourth plane parallel to a pane of the substrate; and forming electrical connections between the first bit line and the first active area, between the second bit line and the second active area, between the first nanotube element and the first reference line, between the first nanotube element and the first active region, and between the first nanotube element and the second active region, such that the first nanotube element is in electrical communication with the first active region, the second active region and the first reference line via electrical contacts at the first surface of the first nanotube element; forming third and fourth active areas in the substrate, the third active area comprising a third source region, the first drain region, and a third channel region disposed between the third source region and the first drain region, the fourth active area comprising a fourth source region, the second drain region, and a fourth channel region disposed between the fourth source region and the second drain region; forming a third word line over the third channel region, and forming a fourth word line over the fourth channel region, the third and fourth word lines being disposed in the first plane; forming second and third reference lines disposed in the third plane; forming second and third nanotube elements disposed in the fourth plane; and forming electrical connections between the second nanotube element and the third source region, between the second nanotube element and the second reference line, between the third nanotube element and the fourth source region, and between the third nanotube element and the third reference line.
-
Specification