Qubit device and a method for operating a qubit device

The invention claimed is: 1. A qubit device comprising: a semiconductor substrate layer; a set of control gates configured to define a row of electrostatically confined quantum dots along the substrate layer, each quantum dot being suitable for holding a qubit; and a set of nanomagnets arranged in a row over the substrate layer such that a nanomagnet is arranged above every other quantum dot of the row of quantum dots, wherein each nanomagnet has an out-of-plane magnetization with respect to the substrate layer and wherein said every other quantum dot is subjected to an out-of-plane magnetic field generated by a respective nanomagnet, such that a qubit spin resonance frequency of said every other quantum dot is shifted with respect to an adjacent quantum dot of the row of quantum dots, and wherein the set of control gates comprises barrier gates and plunger gates arranged alternatingly along a longitudinal direction of the row of quantum dots, wherein the barrier gates are configured to confine the quantum dots in a longitudinal direction of the row of quantum dots, the plunger gates are configured to control a potential of a respective quantum dot, and the set of nanomagnets are arranged above every other plunger gate. 2. A qubit device according to claim 1 , wherein said every other quantum dot have a same first qubit spin resonance frequency and every said adjacent quantum dot have a same second spin resonance frequency. 3. A qubit device according to claim 1 , wherein the set of control gates further comprises a pair of longitudinal confinement gates arranged at mutually opposite sides of the row of quantum dots to laterally confine the quantum dots. 4. A qubit device according to claim 1 , wherein the barrier gates have a same gate length and are arranged with a regular pitch, and wherein the plunger gates have a same gate length and each plunger gate is centred between a respective pair of barrier gates. 5. A qubit device according to claim 1 , wherein the set of nanomagnets are arranged at a common level, over the set of control gates. 6. A qubit device according to claim 1 , further comprising a dielectric layer structure arranged on the substrate layer and embedding the set of control gates, wherein the quantum dots are defined at an interface between the substrate layer and the dielectric layer structure. 7. A qubit device according to claim 1 , wherein the qubit device is configured to transfer a qubit to a selected quantum dot of said every other quantum dot, from an adjacent quantum dot, by varying a potential of a plunger gate associated with the selected quantum dot and a potential of a plunger gate associated with said adjacent quantum dot, and supply a radio-frequency electric or magnetic control field to a selected qubit at the selected quantum dot to control a spin state of the selected qubit. 8. A qubit device according to claim 1 , wherein the magnetic field generated by each nanomagnet induces, at the quantum dot underneath, a spatial magnetic gradient field with a non-zero in-plane component. 9. A qubit device according to claim 8 , wherein the qubit device is configured to control a spin state of a qubit held at a quantum dot by spatially oscillating the qubit within the magnetic gradient field along a direction transverse to a longitudinal direction of a row of qubits, using a pair of control gates arranged at opposite sides of the row of quantum dots. 10. A qubit device according to claim 1 , further comprising one or more radio-frequency resonators connected to plunger gates of the set of control gates. 11. A qubit device according to claim 10 , wherein the qubit device is configured to transfer a qubit to be read to a selected quantum dot associated with a plunger gate connected to a resonator, from an adjacent quantum dot, by varying a potential of the plunger gate associated with the selected quantum dot and a potential of a plunger gate associated with said adjacent quantum dot, and subsequently detect a resonance frequency of the resonator connected to the plunger gate associated with the selected quantum dot. 12. A qubit device according to claim 1 , further comprising an Electron spin resonance, ESR, transmission line extending along the row of quantum dots. 13. A qubit device according to claim 1 , further comprising a non-magnetic metal layer connected to the nanomagnets. 14. A qubit device according to claim 1 , wherein the row of electrostatically confined quantum dots is a single row. 15. A method for operating a qubit device, the method comprising: defining a row of electrostatically confined quantum dots along a substrate layer using a set of control gates, each quantum dot being suitable for holding a qubit, wherein every other quantum dot is defined under a respective nanomagnet of a set of nanomagnets arranged in a row over the substrate layer, wherein each nanomagnet has an out-of-plane magnetization with respect to the substrate layer, and wherein each one of said every other quantum dot is subjected to an out of plane magnetic field generated by the respective nanomagnet, such that a qubit spin resonance frequency of said every other quantum dot is shifted with respect to an adjacent quantum dot of the row of quantum dots, and wherein the set of control gates comprises barrier gates and plunger gates arranged alternatingly along a longitudinal direction of the row of quantum dots, wherein the barrier gates are configured to confine the quantum dots in a longitudinal direction of the row of quantum dots, the plunger gates are configured to control a potential of a respective quantum dot, and the set of nanomagnets are arranged above every other plunger gate. 16. A method for operating a qubit device according to claim 15 , wherein the set of control gates further comprises a pair of longitudinal confinement gates arranged at mutually opposite sides of the row of quantum dots to laterally confine the quantum dots. 17. A method for operating a qubit device according to claim 15 , further comprising transferring a qubit to a selected quantum dot of said every other quantum dot from an adjacent quantum dot by varying a potential of a plunger gate associated with the selected quantum dot and a potential of a plunger gate associated with said adjacent quantum dot, and supplying a radio-frequency electric or magnetic control field to a selected qubit at the selected quantum dot to control a spin state of the selected qubit. 18. A method for operating a qubit device according to claim 15 , wherein the row of electrostatically confined quantum dots is a single row.