Abstract: An electrically actuated device includes a first electrode, a second electrode, and an active region disposed between the first and second electrodes. The device further includes at least one of dopant initiators or dopants localized at an interface between i) the first electrode and the active region, or ii) the second electrode and the active region, or iii) the active region and each of the first and second electrodes.

Abstract: Methods for inputting a data-value pattern into a nanowire crossbar, for inputting a data-value pattern into a nanowire crossbar that support computer instructions stored in a computer-readable medium, and for distributing a received data value to each of a set of nanowires that support control logic implemented in logic circuits are provided. First and second nanoscale shift registers are employed, the first having output signal lines that form or interconnect with a first parallel set of nanowire-crossbar nanowires and the second having output signal lines that form or interconnect with a second parallel set of nanowire-crossbar nanowires. A first pattern of values is stored in the first shift register and a second pattern of values is stored in the second shift register using voltage signals below the WRITE voltage for junctions of the crossbar. Voltage signals greater than or equal to the WRITE threshold are applied for junctions of the crossbar to write the pattern of data values into the crossbar.

Abstract: One embodiment of the present invention is a method for fabricating a nanoscale shift register. In a described embodiment, a nanoimprinting-resist layer applied above a silicon-on-insulator substrate is nanoimprinted to form troughs and trough segments. The silicon layer exposed at the bottom of the troughs and trough segments is then etched, and a conductive material is deposited into the troughs to form nanowires and into the trough segments to form nanowire segments. The exposed surfaces of nanowires are coated with a protective coating, and the conductive material of the nanowire segments is then removed to produce trough segments etched through the nanoimprinting resist and the silicon layer.

Abstract: An analyte stage for use in a spectroscopy system includes a tunable resonant cavity that is capable of resonating electromagnetic radiation having wavelengths less than about 10,000 nanometers, a substrate at least partially disposed within the cavity, and a Raman signal-enhancing structure at least partially disposed within the tunable resonant cavity. A spectroscopy system includes such an analyte stage, a radiation source, and a radiation detector. Methods for performing Raman spectroscopy include using such analyte stages and systems to tune a resonant cavity to resonate Raman scattered radiation that is scattered by an analyte.

Abstract: A molecular crossbar latch is provided, comprising two control wires and a signal wire that crosses the two control wires at a non-zero angle to thereby form a junction with each control wire. Each junction forms a switch and the junction has a functional dimension in nanometers. The signal wire selectively has at least two different voltage states, ranging from a 0 state to a 1 state, wherein there is an asymmetry with respect to the direction of current flow from the signal wire through one junction compared to another junction such that current flowing through one junction into (out of) the signal wire can open (close) while current flowing through the other junction out of (into) the signal wire can close (open) the switch, and wherein there is a voltage threshold for switching between an open switch and a closed switch. Further, methods are provided for latching logic values onto nanowires in a logic array, for inverting a logic value, and for restoring a voltage value of a signal in a nano-scale wire.

Abstract: A molecular crossbar latch is provided, comprising two control wires and a signal wire that crosses the two control wires at a non-zero angle to thereby form a junction with each control wire. Each junction forms a switch and the junction has a functional dimension in nanometers. The signal wire selectively has at least two different voltage states, ranging from a 0 state to a 1 state, wherein there is an asymmetry with respect to the direction of current flow from the signal wire through one junction compared to another junction such that current flowing through one junction into (out of) the signal wire can open (close) while current flowing through the other junction out of (into) the signal wire can close (open) the switch, and wherein there is a voltage threshold for switching between an open switch and a closed switch. Further, methods are provided for latching logic values onto nanowires in a logic array, for inverting a logic value, and for restoring a voltage value of a signal in a nano-scale wire.