A.

Section I: Usual parameters

The first part of the setup is dedicated to the measurement of standard parameters, such as threshold current, optical power versus current and temperature, laser polarization and beam geometry.

By means of a flip mirror placed immediately after the DUT collimation lens, the laser light is directed to various measurement instruments operating in free space. A power meter is used to measure the threshold current, the slope efficiency (optical power versus injection current) and the optical power versus temperature coefficient. The beam polarization and profile are measured with a polarimeter and a beamprofiler, respectively.

When the flip mirror is removed from the optical path, the laser beam is separated into two parts by a beamsplitter with a ratio of 80% in reflection (directed to section II) and 20% in transmission (directed to section III).

B.

Section II: Spectral parameters

The quality of the spectrum of a laser diode implemented in an atomic clock is of outmost importance for the performances of the clock. For that reason a complete part of the characterization bench is devoted to spectral measurements such as side-mode suppression ratio (SMSR), linewidth and laser noises. Two different types of laser noise are relevant for clock application. One is known as relative intensity noise (RIN, [9]) and corresponds to the optical power fluctuations with respect to the mean power level. The second is the frequency noise and relates to the frequency fluctuations of the laser.

The laser beam is directed to two sub-systems (named “freq. discr.” for frequency discriminator and “beat note” in Figure 1) for spectral and noise measurements. An optical isolator is implemented before the subsystems to avoid undesired perturbation of the laser spectrum by retro-reflection into the DUT. The half-wave plate in front of the optical isolator allows the alignment of the polarization axis of the laser beam to the input polarizer of the optical isolator and to the other downstream polarization sensitive components, so they do not need to be realigned for each DUT.

The frequency discriminator sub-system is composed of an evacuated Cs cell, a photo-detector, an attenuator and a retro-reflecting flip mirror and allows retrieving the Cs sub-Doppler absorption spectrum and the mode hop-free tuning range when the laser emission frequency is tuned to the atomic resonance. The frequency noise of the laser is measured by means of a Fast Fourier Transform (FFT) spectrum analyzer. The relative intensity noise (RIN) measurement is also performed at atomic resonance wavelength and with the same sub-system when the Cs cell is removed from the light path, using the same FFT spectrum analyzer.

In the beat-note sub-system, the beam of the DUT is coupled into a single-mode optical fiber. By picking up the light at the exit of this fiber, the laser linewidth can be evaluated using a fiber-coupled Fabry-Perot interferometer (FPI) or by beat-note measurement with a reference laser if the resolution of the FPI (5 MHz) is not sufficient. The beat note is detected by a fast photo-detector and measured with an electrical spectrum analyzer (ESA). A single-mode narrow linewidth laser (e.g., an external-cavity laser diode; ECDL) or a laser previously tested is used as reference laser.

The output of the single-mode can also be injected into fiber-coupled measurement instruments. The wavelength (or frequency) tuning coefficients are established from measurements with a fiber-coupled wavemeter, while the SMSR is evaluated with an optical spectrum analyzer (OSA). In these cases, obviously, no light from any other laser source than the DUT must be injected into the optical fiber.

C.

Section III: Optical feedback

The signal-to-noise limit of a high-performance laser-pumped atomic clock is often determined by the laser frequency and amplitude noises. Optical feedback onto the laser diode always occurs and, depending on its intensity, may degrade the laser’s spectral properties [10,11] and thus degrade the clock’s frequency stability [12,13]. The setup to appraise the optical feedback sensitivity of a laser diode is shown in Figure 2 and consists in a direct re-injection of attenuated laser light into the laser chip. It is composed of the assembly of neutral density (ND) filters for coarse attenuation, and of a linear polarizer and a quarter-wave plate for fine tuning of the feedback strength.

Figure 2.

Optical feedback calibration setup. PD: photo-detector; ND: neutral density filter; Pol: polarizer; λ/4 quarter-wave plate; P₀: laser output power; P: feedback optical power.

The calibration of the feedback optical power has been performed as follow: The optical power at the laser output is first measured using a power meter. The linear polarizer is then aligned with the main polarization axis of the laser. The reflected beam is slightly misaligned so that its power can be measured as a function of the coarse (ND filters) and fine (orientation of the quarter-wave plate) attenuation settings, without blocking, even partially, the laser output beam. Under the approximation that the reflected power doesn’t vary due to this small misalignment (∼2°), the complete attenuation setup is calibrated with respect to the coarse and fine attenuation settings. This calibration does not need to be repeated for each laser diode under test; a single calibration is sufficient – however, it shall be realized at each wavelength range.

The attenuation factor of the feedback control re-injection scheme is referred to as feedback power ratio (FPR) and is defined as the ratio between the optical power re-injected into the laser and the power emitted by the laser. Figure 3 displays the feedback optical power in µW, as a function of quarter-waveplate angle α. The cosine-wave behavior of the feedback optical power P in function of α (with respect to the linear polarizer axis), of the laser output power P₀ and of the feedback power ratio FPR₀ at angle α = 0, expressed as,

Figure 3.

Optical feedback power in function of the quarter-wave plate angle for different attenuation filter optical densities.

is respected within ± 1.5% for all angles α except for angles 45° and 135° where the feedback optical power is close to zero and its measurement limited by the power meter sensitivity. Accordingly, the feedback power ratio FPR, expressed in [dB], is

To measure the sensitivity to optical feedback for a given laser diode DUT, the return beam is aligned such as to obtain maximum coupling and feedback into the diode. This guarantees well-defined test conditions and good reproducibility of the measurement.

D.

Laser diode controller

A home-built digital controller for the laser diode is dedicated to the characterization bench. The free-running passive frequency stability of a laser diode mounted on a Peltier element in a TO3 package was measured as < 2 MHz. Considering a temperature tuning coefficient of 25 GHz/K, such value would correspond to a temperature stability as low as 100 µK. The noise of the laser current source is below 1 nA/√Hz.

A.

Power and Wavelength

The optical power, threshold current and slope efficiency are measured at different temperatures (e.g., from 20°C to 30°C) around the atomic (in the present case Cs) resonance wavelength. The laser injection current is varied while the optical power is measured at the same time with an optical power meter.

The frequency sensitivities to current and temperature are determined for different temperatures of the laser diode and at a wavelength around the atomic transition wavelength by means of a precise (10 MHz resolution) wavemeter.

B.

Side-mode suppression ratio

The side-mode suppression ratio is measured at different laser injection currents, using an optical spectrum analyzer (OSA). This measurement allows also verifying the single mode operation of the laser diode and can highlight potential modehops. An example of such measurements is shown in Figure 5.

Figure 5.

Example of SMSR measured for different injection currents in the case of an 894 nm DFB laser.

C.

Noises

The RIN is measured using a Fast Fourier Transform (FFT) spectrum analyzer, covering frequencies ranging from few mHz to 100 kHz. The FFT spectrum analyzer measures the power spectral density (PSD) in V/√Hz from the signal of the photo-detector once shone by the laser beam; the RIN is then calculated from the PSD and the DC voltage of the detector signal.

The frequency noise is also measured by means of a FFT spectrum analyzer. For this purpose, the laser frequency is set in the middle of one of the slopes of the atomic Doppler absorption signal. The slope of this signal is then used as a frequency discriminator (see inset in Figure 6, right) to convert the laser’s frequency fluctuations into amplitude fluctuations. The PSD of the frequency noise is measured using a photo-detector, provided the laser’s intensity noise is sufficiently low.

Figure 6.

Examples of noise measurement. Left: RIN of an 894 nm DFB laser; right: frequency noise of a 780 nm DFB laser.

D.

Linewidth

The laser linewidth is determined using two different techniques. In the first approach, the linewidth is obtained from heterodyning the DUT emission with a narrower reference laser (ECDL) of known linewidth (typically 150 kHz) and using a fast photo-detector and a RF spectrum analyzer. The beat-note width will then correspond to the sum of the two lasers’ individual linewidths (in the case of the convolution of two Lorentzian profiles). The other technique is based on the β-separation line method [14] that consists in extracting the linewidth (full width at half-maximum, FWHM) from the PSD frequency noise spectrum.

E.

Beam geometry and polarization

The beam geometry (divergence and diameter) is measured using a beam profiler after collimation of the laser beam with a lens of 2.75 mm focal length. The polarization is measured using a polarimeter.