Abstract
A qubit device includes a crystal immobilized on a substrate and in contact with electrodes. The crystal exhibits a charge pair symmetry and with an electron current moving clockwise, counter clockwise, or both. The current in can be placed in a state of superposition wherein the current is unknown until it is measured, and the direction of the current is measured to produce a binary output corresponding to a logical zero or a logical one. A state of the qubit device is monitored by measuring a voltage, a current, or a magnetic field and assigning a superposition or base state depending on a threshold value.
Claims
1. A qubit device comprising: a nanocrystal immobilized on a substrate; a back electrode in contact with or in apposition to a bottom face of the nanocrystal; and an electron current sensing means configured to measure an electron current in the nanocrystal wherein: the nanocrystal has a superposition state or a base state of an electron current associated with the nanocrystal; the nanocrystal comprises a charge pair symmetry and the electron current moves in a direction that is clockwise, counter clockwise, or both in a habit plane separating a top face and a bottom face of the nanocrystal; the current in the nanocrystal can be placed in a state of superposition using the back electrode such that the electron current is unknown until it is measured by said electron current sensing means; and the direction of the electron current in the nanocrystal can be sensed by said electron current sensing means to produce a binary output corresponding to a logical zero or logical one.
2. The qubit device of claim 1, wherein the electron current sensing means comprises: a first electrode in contact with or in apposition to a first location on a top face of the nanocrystal and a second electrode in contact with or in apposition to a second location on a top face of the nanocrystal wherein: said first and second electrodes are configured to sense a direction of the electron current.
3. The qubit device of claim 1, wherein said nanocrystal comprises a transition metal dichalcogenide (TMD).
4. The qubit device of claim 3, further comprising metal dopant nanoparticles formed along a central, outside edge of the nanocrystal, wherein said metal is selected from the group consisting of copper, silver, gold, and combinations thereof.
5. The qubit device of claim 1, wherein said superposition state is generated from said base state at a temperature of between −80° C. and 25° C.
6. The qubit device of claim 1, further comprising two or more additional electrical leads in contact with or in apposition to the nanocrystal providing a functional connection with a controller and/or a sensing element.
7. A quantum register comprising a plurality of qubit devices according to claim 1, said qubit devices being quantum entangled via coupling between charge quanta of said qubits, wherein said qubit devices are not directly physically connected.
Description
BRIEF DESCRIPTION OF THE DRAWINGS
(1) The elements of the drawings are not necessarily to scale relative to each other, with emphasis placed instead upon clearly illustrating the principles of the disclosure. Like reference numerals designate corresponding parts throughout the several views of the drawings in which:
(2) FIG. 1A is a top view transmission electron micrograph of a transition metal dichalcogenide (TMD) nanoplatelet (or nanocrystal) of the type used to create a qubit;
(3) FIG. 1B is a top view scanning electron micrograph of a TMD nanoplatelet with nanoparticles of silver bonded to the edges of the nanoparticle along its central plane;
(4) FIG. 1C shows two comparative enlarged scale images of an interface between a metal nanoparticle and TMD nanoplatelet;
(5) FIGS. 2A-2E show a sequence of events during the formation of a TMD nanoplatelet and a TMD nanoplatelet comprising metal nanoparticles;
(6) FIG. 3 is a schematic showing the basic structure of one embodiment of a qubit;
(7) FIG. 4 is a photograph of a qubit comprising a nanoplatelet of the type shown in FIG. 1;
(8) FIG. 5 is a graph showing measured voltages on a qubit of the invention;
(9) FIG. 6 is a combined atomic force and confocal microscope (AFM/CFM) graph showing profile of a nanoplatelet edge; and
(10) FIG. 7 is a graph comparing top and bottom side currents vs. decohering time.
DETAILED DESCRIPTION OF THE INVENTION
(11) Specific embodiments of the invention are described with reference to the accompanying drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. In the drawings, like numbers refer to like elements.
(12) All art specific terms are intended to have their art accepted meaning unless otherwise specified. All non art specific words are intended to have their plain language meanings in the context with which they are used, unless otherwise specified.
(13) As used herein, a nanoparticle or nanoplatelet is a particle having at least one dimension that is less than 1,000 nanometers, or 1 micrometer, in length.
(14) FIGS. 1A and 1B are top view transmission and scanning electron micrographs of a chiral, self-assembled, bipyramidal Sb.sub.2Te.sub.3 transition metal dichalcogenide (TMD) nanoplatelet/nanocrystal (10). FIGS. 2A-2E illustrate the process of forming a TMD nanoplatelet (10). The nanocrystal (10) comprises a top, or front, face (11, FIG. 3) and a back, or bottom, face (12, FIG. 3) and sidewalls (13) extending between them. The nanocrystals (10) may be produced using solvent engineering processes for making self-assembled nanoparticles disclosed in WO 2018/190919 A9, which are incorporated herein by reference, especially methods for making MoS.sub.2, Sb.sub.2Te3.sub.3 and Bi.sub.2Te.sub.33 self-assembled nanoparticles. During the process, a crystal lattice forms around a central axis (14, FIG. 2A) and forms sequential layers (15) growing in opposite directions with opposite chiralities, with clockwise and counter clockwise turns moving axially from the center along the central axis upwards and downwards, respectively. Not to be bound by theory, it is believed that the complex topology of the nanoplatelet (10) results in conduction channels with properties not reflected in the basic band structure of the nanoplatelet. FIG. 6 is a graph from AFM/CFM measurements showing slight raising of edges (13) of sequential layers (15) not seen in previously reported bulk grown spirals. The areas that appear raised show an unexpected electron density of a particular topological nature. A magnetic moment calculated using AFM/EFM (electrostatic force microscopy) measurements indicates that a field strength sufficient to effect entanglement at room temperature for the TMD nanoplatelets (10).
(15) A characteristic of these sub-micron sized TMD nanocrystals (10) is that they can be defined by the spiral topological path for current flow along the edge of the upper and lower half of the nanoparticle/nanoplatelet (10) (FIG. 3). This provides a unique way of establishing two state superpositions at much higher temperatures than existing systems. A topological current runs along the spiral of the top face (11) from the basal habit plane (37) to the top and back along the central dislocation (not shown). This current does not cross the habit plane (37) onto the lower half (12) because this would break charge-parity symmetry. The topological states are charge parity invariant so mirror currents are established in the two halves. While the object is electrically neutral, one current direction dominates for any given measurement so that any measurement of current along the outside edges (13) will give a + or − current following the spiral but never zero. This established bistability using topology to make the state is not currently predicted by theories of topological quantum computing.
(16) FIGS. 2D and 2E show the formation of metal nanoparticles (21) along the central, outside edge (22) of the nanoparticle from metal ions (20). The presence of nanoparticle dopants such as silver, gold, platinum, copper and other Group IVA-VIIIA and Group IB metals may be used to form metallic nanoparticles bonded to at least a portion of the outside edge (22) or other side walls (13) and establishing a metal semiconductor junction that may be used to increase electron density. For example, Bi.sub.2Te.sub.3 and Sb.sub.2Te.sub.3 nanoplatelets may be decorated or doped with Ag nanoparticles by dispersing the nanoparticles in ethylene glycol and mixed with silver nitrate overnight at room temperature. The Ag decorated TMD nanoparticles may be recovered by washing with ethanol. Bi.sub.2Te.sub.3 and Sb.sub.2Te.sub.3 nanoplatelets (10) may be decorated or doped with Cu nanoparticles by dispersing the nanoparticles in ethylene glycol and mixed with cuprous iodide and cuprous chloride overnight at 60° C. The Cu decorated TMD nanoparticles may be recovered by washing with ethanol. Enlarged views of Ag nanoparticles on a Sb.sub.2Te.sub.3 nanoplatelets are shown in FIG. 1C.
(17) Coherence across the structure means that the wavefunction for electrons at the surface are symmetric or antisymmetric across the habit plane (37) (FIG. 3). The topological complexity of these chiral nanoparticles/nanoplatelets (10) result in charge-parity protected states that are interacted to yield stable entanglement between the top and bottom halves or faces (11,12) of the nanocrystal (10), each of which have either a central up current or down current. Consequently, the nanocrystal (10) behaves as one entangled object with two halves or faces (top spiral and bottom spiral in FIG. 3) entangled, making the nanocrystal (10) useful for a quantum bit, or qubit, for quantum computing. A moment projection at the central axis can be ↑ or η. For counterclockwise topological current, the result is ↑ and V.sub.SD=+1 (for example). This means ↓ is associated with clockwise current flow and V.sub.SD=−1. However, the top and bottom are correlated and when a back gate (33) coupled to the bottom of the nanoparticle (10) is used to force a large magnetic field or electric field across the whole structure, then top and bottom faces (11,12) must be in an entangled state.
(18) FIG. 3 is a drawing showing components of a qubit (30) according to one embodiment of the invention. A voltage source lead (31) and a voltage drain lead (36) are placed in contact with, or almost touching the surface of the top face (11) of the nanoplatelet (10). These leads (31,36) function as a current sensing element (300) for sensing the direction of the electron current on the top face (11) of the nanocrystal (10). A back gate lead/electrode (33) placed in contact with, or almost touching the surface of the bottom face (12) of the nanoplatelet (10). The back gate electrode (33) can be pulsed to place the nanocrystal onto a state of superposition with respect to electron current. The direction of current is conveniently determined using an electrical field measurement such as the direction of a voltage drop using electrodes (31,36). Additionally or alternatively, the direction of current may be measured using other current sensing means (300) such as a superconductor or magnet placed in apposition to the top of the nanoparticle to measure a magnetic field induced by the current. Additionally or alternatively, the current sensing means (300) may comprise electromagnetic sensors for measuring absorbance or reflectance of circularly polarized light by the electric and/or magnetic field induced by the electron current.
(19) FIG. 4 is a photograph of an actual qubit comprising a TMD nanocrystal (10) anchored on an insulating layer (41, not shown) that is formed over a gate electrode (33) on a nonconducting substrate (40), which may be made of silicon with an oxide surface or other suitable non-conducting material. In this example, a back gate electrode (33) is in contact with the bottom face (12) of the nanocrystal (10). A first electrode providing a voltage source (33) is in contact with a first position on an outer edge on the top face (11) of the nanoparticle (10) and a second electrode providing a voltage drain (36) is in contact with a second position on an outer edge on the top face (11) of the nanoparticle (10). A third electrode providing a voltage source (34) is in contact with a first position on an outer edge on the bottom face (12) of the nanoparticle (10) and a second electrode providing a voltage drain (35) is in contact with a second position on an outer edge on the bottom face (12) of the nanoparticle (10). The direction of the electron current in each of the top and bottom faces (11,12) may be measured simultaneously by adding a shift in phase when voltage is applied and locating spikes in measured voltage in one or the other direction as shown in FIG. 5.
(20) The functions of electrodes may be changed by changing applied voltages and the positions of leads (33) and (36) on the top half of the nanoparticle may be changed. Additional electrodes (32, 34, 35) are optional and may be used to apply and measure directional voltages, including phase shifted voltages, on the nanoparticle (10), to provide redundancy of function, or to provide connections to additional qubits, sensors, and/or a microprocessor controller for coordinating resetting and measurement times.
(21) The minimum current required to measure voltage depends on the sensitivity of the measuring device. The presence of silver nanoparticles or other nanoparticle (21) dopants such as gold, platinum, copper and other Group IVA-VIIIA and Group IB metals may be used to form metallic nanoparticles bonded to at least a portion of the outside edge (22) or other side walls and establishing a metal semiconductor junction that may be used to increase electron density, if needed, to provide reliable measurable voltages. FIG. 1C shows a close up view of silver nanoparticles 21 on the edge 22 of a TMD nanocrystal (10). For any given qubit design, one may make a Hall measurement to determine detectable levels of current using a pico ammeter and adjust the presence or absence or type or amount of dopant as needed to achieve detectable levels of current.
(22) FIG. 7 shows the results of measurements made using a qubit device similar to that shown in FIG. 4 in which measurements were made simultaneously on both the top and the bottom faces (11,12) of the nanocrystal (10). The back gate (33) was pulsed by a microprocessor control element to put the nanocrystal into a superposition state and measurements between two top mounted leads (31,36) and two bottom mounted leads (34,35) were made. The LHC/RHC ratio of 1:1 was maintained up to 100 ms after superposition, indicating a coherence time at room temperature of 100 ms.
(23) Qubits according to the invention may be made, for example, by forming a gate electrode (33) on a nonconducting substrate (40), forming an insulating layer (41) over the gate (33), immobilizing a semiconductor nanocrystal (10) onto the insulating layer (41) in contact with or in apposition to the gate electrode (33), and placing electrodes (31,36) on or in apposition to the top half (11) of the crystal. Additional leads (34,35) may also be formed on the nonconducting substrate (40) prior to immobilizing the semiconductor nanocrystal (10) onto the insulating layer (41).
(24) The qubit devices may be combined to form a quantum register comprising a plurality of qubit devices entangled via coupling between charge quanta of said qubits. The qubit devices are not directly physically connected and the states of each of the qubit devices is read simultaneously. The qubit devices may be used to make quantum gates, including Pauli gates and quantum logic gates, and for making quantum circuits. A tremendous advantage of a qubit comprising a doped TMD nanocrystal is that cooling to cryogenic temperatures is not required because the qubits function at temperatures up to and including room temperature, for example −80° C., −40° C. −20° C., 0° C., 10° C., 20° C., and 25° C.
