Abstract: A semiconducting graphene structure may include a graphene material and a graphene-lattice matching material over at least a portion of the graphene material, wherein the graphene-lattice matching material has a lattice constant within about ±5% of a multiple of the lattice constant or bond length of the graphene material. The semiconducting graphene structure may have an energy band gap of at least about 0.5 eV. A method of modifying an energy band gap of a graphene material may include forming a graphene-lattice matching material over at least a portion of a graphene material, the graphene-lattice matching material having a lattice constant within about ±5% of a multiple of the lattice constant or bond length of the graphene material.

Abstract: Cross-point memory cells, non-volatile memory arrays, methods of reading a memory cell, methods of programming a memory cell, and methods of writing to and reading from a memory cell are described. In one embodiment, a cross-point memory cell includes a word line extending in a first direction, a bit line extending in a second direction different from the first direction, the bit line and the word line crossing without physically contacting each other, and a capacitor formed between the word line and the bit line where such cross. The capacitor comprises a dielectric material configured to prevent DC current from flowing from the word line to the bit line and from the bit line to the word line.

Abstract: A semiconducting graphene structure may include a graphene material and a graphene-lattice matching material over at least a portion of the graphene material, wherein the graphene-lattice matching material has a lattice constant within about ±5% of a multiple of the lattice constant or bond length of the graphene material. The semiconducting graphene structure may have an energy band gap of at least about 0.5 eV. A method of modifying an energy band gap of a graphene material may include forming a graphene-lattice matching material over at least a portion of a graphene material, the graphene-lattice matching material having a lattice constant within about ±5% of a multiple of the lattice constant or bond length of the graphene material.

Abstract: Electronic devices may include a first substrate including circuitry components within the substrate, a microscale bond pad on a surface of the substrate, and a via electrically connecting the microscale bond pad to one of the circuitry components. A distance between centers of at least some adjacent circuitry components of the circuitry components may be a nanoscale distance. A second substrate may be electrically connected to the microscale bond pad. Methods of forming electronic devices may involve positioning a first substrate adjacent to a second substrate and electrically connecting the second substrate to a microscale bond pad on a surface of the first substrate. The first substrate may include circuitry components within the first substrate and a via electrically connecting the microscale bond pad to one of the circuitry components. A distance between centers of at least some adjacent circuitry components of the circuitry components may be a nanoscale distance.

Abstract: Some embodiments include methods of programming a memory cell. A plurality of charge carriers may be moved within the memory cell, with an average charge across the moving charge carriers having an absolute value greater than 2. Some embodiments include methods of forming and programming an ionic-transport-based memory cell. A stack is formed to have programmable material between first and second electrodes. The programmable material has mobile ions which are moved within the programmable material to transform the programmable material from one memory state to another. An average charge across the moving mobile ions has an absolute value greater than 2. Some embodiments include memory cells with programmable material between first and second electrodes. The programmable material includes an aluminum nitride first layer, and includes a second layer containing a mobile ion species in common with the first layer.

Abstract: A memcapacitor device includes a pair of opposing conductive electrodes. A semiconductive material including mobile dopants within a dielectric and a mobile dopant barrier dielectric material are received between the pair of opposing conductive electrodes. The semiconductive material and the barrier dielectric material are of different composition relative one another which is at least characterized by at least one different atomic element. One of the semiconductive material and the barrier dielectric material is closer to one of the pair of electrodes than is the other of the semiconductive material and the barrier dielectric material. The other of the semiconductive material and the barrier dielectric material is closer to the other of the pair of electrodes than is the one of the semiconductive material and the barrier dielectric material. Other implementations are disclosed, including field effect transistors, memory arrays, and methods.

Abstract: Electronic devices may include a first substrate bearing circuitry components at a nanoscale pitch within the first substrate. The first substrate may include microscale bond pads on a surface of the first substrate. A via may electrically connect one of the microscale bond pads to one of the circuitry components. A second substrate may be electrically connected to at least one of the microscale bond pads. Methods of forming electronic devices may include positioning a first substrate adjacent to a second substrate. The first substrate may bear circuitry components at a nanoscale pitch within the first substrate. The first substrate may include microscale bond pads on a surface of the first substrate. A via may electrically connect one of the microscale bond pads to one of the circuitry components. The second substrate may be electrically connected to at least one of the microscale bond pads.

Abstract: Some embodiments include photonic systems. The systems may include a silicon-containing waveguide configured to direct light along a path, and a detector proximate the silicon-containing waveguide. The detector may comprise a detector material which has a lower region and an upper region, with the lower region having a higher concentration of defects than the upper region. The detector material may comprise germanium in some embodiments. Some embodiments include methods of forming photonic systems.

Abstract: A memcapacitor device includes a pair of opposing conductive electrodes. A semiconductive material including mobile dopants within a dielectric and a mobile dopant barrier dielectric material are received between the pair of opposing conductive electrodes. The semiconductive material and the barrier dielectric material are of different composition relative one another which is at least characterized by at least one different atomic element. One of the semiconductive material and the barrier dielectric material is closer to one of the pair of electrodes than is the other of the semiconductive material and the barrier dielectric material. The other of the semiconductive material and the barrier dielectric material is closer to the other of the pair of electrodes than is the one of the semiconductive material and the barrier dielectric material. Other implementations are disclosed, including field effect transistors, memory arrays, and methods.

Abstract: Some embodiments include methods of programming a memory cell. A plurality of charge carriers may be moved within the memory cell, with an average charge across the moving charge carriers having an absolute value greater than 2. Some embodiments include methods of forming and programming an ionic-transport-based memory cell. A stack is formed to have programmable material between first and second electrodes. The programmable material has mobile ions which are moved within the programmable material to transform the programmable material from one memory state to another. An average charge across the moving mobile ions has an absolute value greater than 2. Some embodiments include memory cells with programmable material between first and second electrodes. The programmable material includes an aluminum nitride first layer, and includes a second layer containing a mobile ion species in common with the first layer.

Abstract: Some embodiments include methods of forming electrical components. First and second exposed surface configurations are formed over a first structure, and material is then formed across the surface configurations. The material is sub-divided amongst two or more domains, with a first of the domains being induced by the first surface configuration, and with a second of the domains being induced by the second surface configuration. A second structure is then formed over the material. The first domains of the material are incorporated into electrical components. The second domains may be replaced with dielectric material to provide isolation between adjacent electrical components, or may be utilized as intervening regions between adjacent electrical components.

Abstract: Methods, devices, and systems associated with memory cell operation are described. One or more methods of operating a memory cell include charging a capacitor coupled to the memory cell to a particular voltage level and programming the memory cell from a first state to a second state by controlling discharge of the capacitor through a resistive switching element of the memory cell.

Abstract: Some embodiments include photonic systems. The systems may include a silicon-containing waveguide configured to direct light along a path, and a detector proximate the silicon-containing waveguide. The detector may comprise a detector material which has a lower region and an upper region, with the lower region having a higher concentration of defects than the upper region. The detector material may comprise germanium in some embodiments. Some embodiments include methods of forming photonic systems.

Abstract: Some embodiments include photonic systems. The systems may include a silicon-containing waveguide configured to direct light along a path, and a detector proximate the silicon-containing waveguide. The detector may comprise a detector material which has a lower region and an upper region, with the lower region having a higher concentration of defects than the upper region. The detector material may comprise germanium in some embodiments. Some embodiments include methods of forming photonic systems.

Abstract: Methods, devices, and systems associated with memory cell operation are described. One or more methods of operating a memory cell include charging a capacitor coupled to the memory cell to a particular voltage level and programming the memory cell from a first state to a second state by controlling discharge of the capacitor through a resistive switching element of the memory cell.

Abstract: Electronic devices may include a first substrate bearing circuitry components at a nanoscale pitch within the first substrate. The first substrate may include microscale bond pads on a surface of the first substrate. A via may electrically connect one of the microscale bond pads to one of the circuitry components. A second substrate may be electrically connected to at least one of the microscale bond pads. Methods of forming electronic devices may include positioning a first substrate adjacent to a second substrate. The first substrate may bear circuitry components at a nanoscale pitch within the first substrate. The first substrate may include microscale bond pads on a surface of the first substrate. A via may electrically connect one of the microscale bond pads to one of the circuitry components. The second substrate may be electrically connected to at least one of the microscale bond pads.

Abstract: Some embodiments include methods of programming a memory cell. A plurality of charge carriers may be moved within the memory cell, with an average charge across the moving charge carriers having an absolute value greater than 2. Some embodiments include methods of forming and programming an ionic-transport-based memory cell. A stack is formed to have programmable material between first and second electrodes. The programmable material has mobile ions which are moved within the programmable material to transform the programmable material from one memory state to another. An average charge across the moving mobile ions has an absolute value greater than 2. Some embodiments include memory cells with programmable material between first and second electrodes. The programmable material includes an aluminum nitride first layer, and includes a second layer containing a mobile ion species in common with the first layer.

Abstract: Electronic devices comprise a first substrate and a second substrate. The first substrate comprises circuitry including a plurality of conductive traces at least substantially parallel to each other through at least a portion of the first substrate. A plurality of bond pads is positioned on a surface of the first substrate and comprises a width extending over at least two of the plurality of conductive traces. A plurality of vias extends from adjacent at least some of the conductive traces to the plurality of bond pads. The second substrate is bonded to the first substrate and comprises support circuitry coupled to the plurality of bond pads on the first substrate with a plurality of conductive bumps. Memory devices and related methods of forming electronic devices and memory devices are also disclosed, as are electronic systems.

Abstract: Some embodiments include methods of programming a memory cell. A plurality of charge carriers may be moved within the memory cell, with an average charge across the moving charge carriers having an absolute value greater than 2. Some embodiments include methods of forming and programming an ionic-transport-based memory cell. A stack is formed to have programmable material between first and second electrodes. The programmable material has mobile ions which are moved within the programmable material to transform the programmable material from one memory state to another. An average charge across the moving mobile ions has an absolute value greater than 2. Some embodiments include memory cells with programmable material between first and second electrodes. The programmable material includes an aluminum nitride first layer, and includes a second layer containing a mobile ion species in common with the first layer.

Abstract: A memcapacitor device includes a pair of opposing conductive electrodes. A semiconductive material including mobile dopants within a dielectric and a mobile dopant barrier dielectric material are received between the pair of opposing conductive electrodes. The semiconductive material and the barrier dielectric material are of different composition relative one another which is at least characterized by at least one different atomic element. One of the semiconductive material and the barrier dielectric material is closer to one of the pair of electrodes than is the other of the semiconductive material and the barrier dielectric material. The other of the semiconductive material and the barrier dielectric material is closer to the other of the pair of electrodes than is the one of the semiconductive material and the barrier dielectric material. Other implementations are disclosed, including field effect transistors, memory arrays, and methods.