The invention discloses a physical system of strontium optical clock applied for space station, relating to the field of optical atomic clocks, comprising a special-shaped cavity and a MOT cavity. A Zeeman slower is arranged between the special-shaped cavity and the MOT cavity, and the special-shaped cavity and the MOT cavity are provided with a plurality of interfaces that communicate with their interiors; an internal heating atomic oven is arranged in the special-shaped cavity, and an anti-Helmholtz coil and a remanence compensation coil are arranged on the outer wall of the MOT cavity; the two cavities are both connected with a vacuum device for forming a vacuum, and both the special-shaped cavity and the MOT cavity are provided with optomechanical components. The system integrates the internal heating atomic oven in the special-shaped cavity to reduce the space occupied by the heating atomic oven.

The invention discloses a physical system of strontium optical clock applied for space station, relating to the field of optical atomic clocks, comprising a special-shaped cavity and a MOT cavity. A Zeeman slower is arranged between the special-shaped cavity and the MOT cavity, and the special-shaped cavity and the MOT cavity are provided with a plurality of interfaces that communicate with their interiors; an internal heating atomic oven is arranged in the special-shaped cavity, and an anti-Helmholtz coil and a remanence compensation coil are arranged on the outer wall of the MOT cavity; the two cavities are both connected with a vacuum device for forming a vacuum, and both the special-shaped cavity and the MOT cavity are provided with optomechanical components. The system integrates the internal heating atomic oven in the special-shaped cavity to reduce the space occupied by the heating atomic oven.

The invention discloses a physical system of strontium optical clock applied for space station, relating to the field of optical atomic clocks, comprising a special-shaped cavity and a MOT cavity. A Zeeman slower is arranged between the special-shaped cavity and the MOT cavity, and the special-shaped cavity and the MOT cavity are provided with a plurality of interfaces that communicate with their interiors; an internal heating atomic oven is arranged in the special-shaped cavity, and an anti-Helmholtz coil and a remanence compensation coil are arranged on the outer wall of the MOT cavity; the two cavities are both connected with a vacuum device for forming a vacuum, and both the special-shaped cavity and the MOT cavity are provided with optomechanical components. The system integrates the internal heating atomic oven in the special-shaped cavity to reduce the space occupied by the heating atomic oven.

The invention discloses a physical system of strontium optical clock applied for space station, relating to the field of optical atomic clocks, comprising a special-shaped cavity and a MOT cavity. A Zeeman slower is arranged between the special-shaped cavity and the MOT cavity, and the special-shaped cavity and the MOT cavity are provided with a plurality of interfaces that communicate with their interiors; an internal heating atomic oven is arranged in the special-shaped cavity, and an anti-Helmholtz coil and a remanence compensation coil are arranged on the outer wall of the MOT cavity; the two cavities are both connected with a vacuum device for forming a vacuum, and both the special-shaped cavity and the MOT cavity are provided with optomechanical components. The system integrates the internal heating atomic oven in the special-shaped cavity to reduce the space occupied by the heating atomic oven.

A method of fabricating one or more glass cells includes drawing one or more glass capillaries from a source of glass material. The method includes performing a first conditioning of one or more inner surfaces of the one or more capillaries. The method includes sealing one or more first ends of the one or more capillaries using thermal energy. The method includes performing a second conditioning of the one or more inner surfaces after the sealing. The method includes purifying the one or more capillaries to increase a purity of a gas used to fill the one or more capillaries. The method includes filling the one or more capillaries using the gas after the purifying. The method includes pressurizing the one or more capillaries to a given pressure. The method includes sealing one or more second ends of the one or more capillaries using thermal energy.

A method of fabricating one or more glass cells includes drawing one or more glass capillaries from a source of glass material. The method includes performing a first conditioning of one or more inner surfaces of the one or more capillaries. The method includes sealing one or more first ends of the one or more capillaries using thermal energy. The method includes performing a second conditioning of the one or more inner surfaces after the sealing. The method includes purifying the one or more capillaries to increase a purity of a gas used to fill the one or more capillaries. The method includes filling the one or more capillaries using the gas after the purifying. The method includes pressurizing the one or more capillaries to a given pressure. The method includes sealing one or more second ends of the one or more capillaries using thermal energy.

A method of fabricating one or more glass cells includes drawing one or more glass capillaries from a source of glass material. The method includes performing a first conditioning of one or more inner surfaces of the one or more capillaries. The method includes sealing one or more first ends of the one or more capillaries using thermal energy. The method includes performing a second conditioning of the one or more inner surfaces after the sealing. The method includes purifying the one or more capillaries to increase a purity of a gas used to fill the one or more capillaries. The method includes filling the one or more capillaries using the gas after the purifying. The method includes pressurizing the one or more capillaries to a given pressure. The method includes sealing one or more second ends of the one or more capillaries using thermal energy.

A method of fabricating one or more glass cells includes drawing one or more glass capillaries from a source of glass material. The method includes performing a first conditioning of one or more inner surfaces of the one or more capillaries. The method includes sealing one or more first ends of the one or more capillaries using thermal energy. The method includes performing a second conditioning of the one or more inner surfaces after the sealing. The method includes purifying the one or more capillaries to increase a purity of a gas used to fill the one or more capillaries. The method includes filling the one or more capillaries using the gas after the purifying. The method includes pressurizing the one or more capillaries to a given pressure. The method includes sealing one or more second ends of the one or more capillaries using thermal energy.