CPT resonance generation method, CPT resonance detection method, CPT resonance generation apparatus, atomic oscillator and magnetic sensor

What is claimed is: 1. A (CPT) resonance generation method for generating a CPT resonance, comprising: applying an electric current to a laser light-emitting element, to emit laser light having at least two wavelengths, wherein a first value of a direct current component of the electric current applied to the laser light-emitting element in a first period is greater than an oscillation threshold for the laser light-emitting element, and a second value of the direct current component of the electric current applied to the laser light-emitting element in a second period, following the first period, is less than the first value of the direct current component of the electric current in the first period; and irradiating an alkali metal atom with the laser light, the laser light generated in the first period and the laser light generated by in the second period entering the alkali metal atom repeatedly a plurality of times to generate a Ramsey resonance, wherein the wavelength of the laser light in the first period increases from a value less than an absorption wavelength of the alkali metal atom to a value greater than the absorption wavelength, and decreases from the value greater than the absorption wavelength to the absorption wavelength. 2. The CPT resonance generation method according to claim 1 , wherein the second value of direct current component is less than the oscillation threshold for the laser light-emitting element. 3. The CPT resonance generation method according to claim 1 , wherein the second value of direct current component is zero. 4. A (CPT) resonance generation method for generating a CPT resonance, comprising: applying an electric current to a laser light-emitting element, to emit laser light having at least two wavelengths, wherein a first value of a direct current component of the electric current applied to the laser light-emitting element in a first period is greater than an oscillation threshold for the laser light-emitting element, and a second value of the direct current component of the electric current applied to the laser light-emitting element in a second period, following the first period, is less than the first value of the direct current component of the electric current in the first period; and irradiating an alkali metal atom with the laser light, the laser light generated in the first period and the laser light generated by in the second period entering the alkali metal atom repeatedly a plurality of times to generate a Ramsey resonance, wherein a value of the electric current applied to the laser light-emitting element in the first period includes a first value immediately after a start of the first period and a second value, which is less than the first value. 5. A method for detecting the CPT resonance generated by the CPT resonance generation method according to claim 1 , wherein light passing through the alkali metal atom is detected when the wavelength of the laser light coincides with the absorption wavelength during the wavelength increases in the first period. 6. The CPT resonance detection method according to claim 5 , wherein the laser light-emitting element is a surface emitting laser. 7. The CPT resonance detection method according to claim 5 , wherein the alkali metal atom is encapsulated in a cell. 8. The CPT resonance detection method according to claim 5 , wherein the alkali metal atom is rubidium (Rb), cesium (Cs), sodium (Na) or potassium (K). 9. A CPT resonance generation apparatus comprising: an alkali metal cell in which an alkali metal atom is encapsulated, and which laser light having at least two wavelengths enters; a laser light-emitting element configured to emit the laser light; and a power-supply unit configured to apply an electric current to the laser light-emitting element, wherein a first value of a direct current component of the applied electric current in a first period is greater than an oscillation threshold for the laser light-emitting element; a second value of the direct current component of the applied electric current in a second period, following the first period, is less than the first value of the direct current component; and the first period and the second period are repeated a plurality of times. 10. The CPT resonance generation apparatus according to claim 9 , wherein the laser light-emitting element is a surface emitting laser. 11. An atomic oscillator comprising: the CPT resonance generation apparatus according to claim 9 ; and a light reception unit configured to receive light passing through the alkali metal cell. 12. A magnetic sensor comprising: the CPT resonance generation apparatus according to claim 9 ; and a light reception unit configured to receive light passing through the alkali metal cell. 13. The CPT resonance generation method according to claim 4 , wherein the second value of direct current component is less than the oscillation threshold for the laser light-emitting element. 14. The CPT resonance generation method according to claim 4 , wherein the second value of direct current component is zero. 15. A method for detecting the CPT resonance generated by the CPT resonance generation method according to claim 4 , wherein light passing through the alkali metal atom is detected when the wavelength of the laser light coincides with an absorption wavelength, while the wavelength increases in the first period. 16. The CPT resonance detection method according to claim 15 , wherein the laser light-emitting element is a surface emitting laser. 17. The CPT resonance detection method according to claim 15 , wherein the alkali metal atom is encapsulated in a cell. 18. The CPT resonance detection method according to claim 15 , wherein the alkali metal atom is rubidium (Rb), cesium (Cs), sodium (Na) or potassium (K).