3.1 Phase-matching manipulation for large temporal window

Temporal window refers to the achievable delay range between the PT and sampling pulses in an SSCC. In practical applications, a temporal window larger than 50 ps is usually required to match the response limits of a fast photodiode and an oscilloscope, and a temporal resolution of ${\sim}1~\text{ps}$ is needed to resolve fine-structured noise. Figure 2(a) shows a typical noncollinear SSCC based on sum-frequency generation (SFG) using a bulk nonlinear crystal. According to its geometrical relations, the temporal window $\unicode[STIX]{x0394}T$ of this SFG-SSCC equals the sum of time delay for the PT pulse through $\overline{BE}$ and that for the sampling pulse through $\overline{AD}$ , which can be calculated by

(1) $$\begin{eqnarray}\displaystyle \unicode[STIX]{x0394}T=W/c\cdot (n_{T}\cdot \sin \unicode[STIX]{x1D6FC}+n_{S}\cdot \sin \unicode[STIX]{x1D6FD}), & & \displaystyle\end{eqnarray}$$

where $W$ is the transverse width of beam intersection region, $c$ is the light speed in vacuum, $n_{T}\;(n_{S})$ is the refractive index of PT (sampling) pulse and $\unicode[STIX]{x1D6FC}\;(\unicode[STIX]{x1D6FD})$ is the inner cross-angle between the PT (sampling) and correlation beams. Clearly shown by Equation (1), the temporal window $\unicode[STIX]{x0394}T$ is determined by the beam aperture and noncollinear angle. As $W$ is ultimately limited by the available crystal aperture, further enhancement of temporal window depends on the increase of angles $\unicode[STIX]{x1D6FC}$ and $\unicode[STIX]{x1D6FD}$ . However, the angles $\unicode[STIX]{x1D6FC}$ and $\unicode[STIX]{x1D6FD}$ are connected to the phase-matching (PM) condition. An efficient SFG requires the phase mismatch, $\unicode[STIX]{x0394}\unicode[STIX]{x1D711}=\unicode[STIX]{x0394}\boldsymbol{k}\boldsymbol{\cdot }\boldsymbol{r}$ , to be minimized. The corresponding wave-vector mismatch is given by $\unicode[STIX]{x0394}\boldsymbol{k}=\boldsymbol{k}_{T}+\boldsymbol{k}_{S}-\boldsymbol{k}_{C}$ , where $\boldsymbol{k}_{T}$ , $\boldsymbol{k}_{S}$ and $\boldsymbol{k}_{C}$ are the wave vectors of the PT, sampling, and correlation pulses, respectively. $\unicode[STIX]{x0394}\boldsymbol{k}$ can be decomposed into parallel and perpendicular components relative to the direction of $\boldsymbol{k}_{C}$ : $\unicode[STIX]{x0394}k_{\Vert }=k_{T}\cos \unicode[STIX]{x1D6FC}+k_{S}\cos \unicode[STIX]{x1D6FD}-k_{C}$ , $\unicode[STIX]{x0394}k_{\bot }=k_{T}\sin \unicode[STIX]{x1D6FC}-k_{S}\sin \unicode[STIX]{x1D6FD}$ . Obviously, owing to the PM condition requirement ( $\unicode[STIX]{x0394}k_{\Vert }=0$ and $\unicode[STIX]{x0394}k_{\bot }=0$ ), $\unicode[STIX]{x1D6FC}$ and $\unicode[STIX]{x1D6FD}$ cannot be set arbitrarily.

Figure 2. PM manipulation and crystal design for noncollinear SSCC. (a) SFG cross-correlation with wide slanting interaction beams. $\unicode[STIX]{x1D6FC}\;(\unicode[STIX]{x1D6FD})$ , intersection angle between T (S) and C within NC; $W$ , transverse width of intersecting region between T and S; $L$ , longitudinal length of NC. (b) Plot for the analysis of temporal resolution. $\boldsymbol{k}_{T},\boldsymbol{k}_{S}$ and $\boldsymbol{k}_{C}$ are the wave vectors of T, S and C. (c) QPM design in a PPLN crystal with a poling period of $\unicode[STIX]{x1D6EC}$ . $\boldsymbol{k}_{\unicode[STIX]{x1D6EC}}$ , the grating $k$ -vectors provided by PPLN. (d) Lateral cross-correlation supported by high-order QPM. $\unicode[STIX]{x1D70E}$ , beam diameter of S. Its temporal window is limited by the width of PPLN crystal, while its temporal resolution is limited by the beam size $\unicode[STIX]{x1D70E}$ .

To mitigate the angle limitation in noncollinear PM, we introduce additional control degrees of freedom. First, the wavelength of sampling pulse can be chosen on demand. We have theoretically and experimentally verified that the increase of sampling wavelength can support larger noncollinear angle and hence larger temporal window^{[Reference Ma, Yuan, Wang, Zhang, Zhu and Qian26, Reference Qian, Ma, Yuan, Wang, Zhang and Zhu27]}, as shown in Figure 3(a). Either an optical parametric amplifier (OPA) or a supercontinuum generation (SCG) process, pumped by the replica of PT pulse, can be adopted to generate the required clean long-wavelength sampling pulse^{[Reference Ma, Yuan, Wang, Zhu and Qian38, Reference Filip, Tóth and Leemans39]}. Compared to the conventional short-wavelength SHG sampling, the long-wavelength sampling can increase the wavelength of correlation signal as well, which can better match the spectral range of the low loss and high sensitivity of the fiber-based detection system (see Section 3.2).

Figure 3. (a) Calculated maximum noncollinear angle of SFG (dashed curve) and temporal window (solid curve) with a dependence of sampling wavelength in bulk $\text{LiNbO}_{3}$ (black curves) and PPLN (red curves) crystals, respectively, for the SSCC configuration shown in Figure 2(a). (b) Calculated noncollinear angle (dashed curve) and temporal window (solid curve) on the poling period of PPLN for the SSCC configuration in Figure 2(d). Black (red) curves, the first (third)-order QPM. Cross-correlation trace when the width of the narrow sampling beam is set to be (c)  $150~\unicode[STIX]{x03BC}\text{m}$ and (d)  $70~\unicode[STIX]{x03BC}\text{m}$ . Inset is the corresponding CCD image of correlation signal. The PT pulse is the output of a 50-fs Ti:sapphire regenerative amplifier.

Besides, we may employ quasi-phase matching (QPM) instead of birefringent PM to further release the angle limitation [Figure 2(c)]. QPM, relying on a periodically poled crystal design, can introduce a grating $k$ -vector to the PM condition, $k_{\unicode[STIX]{x1D6EC}}=2\unicode[STIX]{x1D70B}m/\unicode[STIX]{x1D6EC}$ , where $\unicode[STIX]{x1D6EC}$ is the poling period and $m$ is the QPM order. In this case, the parallel component of wave-vector mismatch becomes $\unicode[STIX]{x0394}k_{\Vert }=k_{T}\cos \unicode[STIX]{x1D6FC}\,+\,k_{S}\cos \unicode[STIX]{x1D6FD}-k_{C}-2\unicode[STIX]{x1D70B}m/\unicode[STIX]{x1D6EC}$ . As a result, the PM condition can be manipulated by the two additional parameters of $m$ and $\unicode[STIX]{x1D6EC}$ . Generally, a shorter period $\unicode[STIX]{x1D6EC}$ and/or a larger order $m$ (only odd integer is valid) leads to a larger temporal window [see Figure 3(b)]. By using a periodically poled lithium niobate (PPLN) crystal with $\unicode[STIX]{x1D6EC}=6~\unicode[STIX]{x03BC}\text{m}$ and $m=1$ , for example, we achieved a temporal window per unit $W$ of ${\sim}45~\text{ps}/\text{cm}$ for the SSCC with a sampling wavelength of $3.3~\unicode[STIX]{x03BC}\text{m}$ ^{[Reference Ma, Yuan, Wang, Zhang, Zhu and Qian26]}. A larger temporal window of ${\sim}70~\text{ps}/\text{cm}$ was achieved by using a high-order QPM (e.g., $m=3,5$ )^{[Reference Ma, Wang, Yuan, Xie, Zhu and Qian28]}. A unique lateral cross-correlator with $\unicode[STIX]{x1D6FC}+\unicode[STIX]{x1D6FD}=\unicode[STIX]{x1D70B}/2$ can be realized by high-order QPM owing to its strong capability in compensating phase mismatch, as shown in Figure 2(d). In such a lateral cross-correlator, the sampling pulse is allowed to impinge the PPLN crystal from a lateral surface.

Ideal time-to-space encoding requires a one-to-one correspondence between the time delay $\unicode[STIX]{x1D70F}$ and the transverse location $x$ . This relation is strictly satisfied only on the input surface and then messes up inside the crystal. Such an effect of crystal length $L$ on the temporal resolution can be understood with the aid of Figure 2(b). Suppose that the PT beam slice $\text{T}_{1}$ and sampling beam slice $\text{S}_{1}$ arrive at the point $G$ at the same time (i.e., $\unicode[STIX]{x1D70F}=0$ ). They will produce the correlation signal at the main peak, which propagates perpendicularly to the crystal rear surface and emits away from the point $F$ . Ideally, the intensity of beam light $GF$ only corresponds to the correlation signal at $\unicode[STIX]{x1D70F}=0$ . Unfortunately, it also includes the contributions of correlation signals at $\unicode[STIX]{x1D70F}\neq 0$ . As shown in Figure 2(b), for example, the correlation signal between beam slices $\text{T}_{2}$ and $\text{S}_{2}$ also propagates along $GF$ . Thus, the maximum time delay difference is determined by the outmost pair of beam slices as

(2) $$\begin{eqnarray}\displaystyle \unicode[STIX]{x1D6FF}\unicode[STIX]{x1D70F}=L/c\cdot (n_{T}\cdot \cos \unicode[STIX]{x1D6FC}-n_{S}\cdot \cos \unicode[STIX]{x1D6FD}). & & \displaystyle\end{eqnarray}$$

$\unicode[STIX]{x1D6FF}\unicode[STIX]{x1D70F}$ reveals the time ambiguity in time-to-space encoding, and is defined as the temporal resolution of the correlation process. According to Equation (2), the temporal resolution also depends on the noncollinear angles $\unicode[STIX]{x1D6FC}$ and $\unicode[STIX]{x1D6FD}$ . Numerical calculations demonstrate that the increase of noncollinear angle (aiming for a larger temporal window) will degrade the temporal resolution. Equations (1) and (2) reveal an inherent trade-off between the temporal window and resolution. It should be noted that the unique lateral cross-correlation shown in Figure 2(d) may break this trade-off, as its temporal resolution is determined by the width $\unicode[STIX]{x1D70E}$ of sampling beam rather than the crystal length $L$ ^{[Reference Ma, Wang, Yuan, Xie, Zhu and Qian28]}, as shown in Figures 3(c) and 3(d). Due to the limited fiber channels $N$ in the fiber array (see Section 3.2), the sampling temporal resolution is ultimately limited to $\unicode[STIX]{x0394}T/N$ . So, the relation between $\unicode[STIX]{x0394}T$ and $\unicode[STIX]{x1D6FF}\unicode[STIX]{x1D70F}$ can be optimized by matching the correlation resolution $\unicode[STIX]{x1D6FF}\unicode[STIX]{x1D70F}$ with the sampling resolution, i.e., $\unicode[STIX]{x1D6FF}\unicode[STIX]{x1D70F}=\unicode[STIX]{x0394}T/N$ .

Figure 4. (a) Schematic diagram of high-sensitivity parallel detection system based on fiber array and PMT. Inset shows the widely used CCD-based parallel detection system. NF, neutral filter. (b) System photograph after packaging. (c) A measurement example of pulse contrast with a dynamic range of $10^{10}$ . Reference pulses I, II and III on the correlation trace are achieved by multiple Fresnel reflections of the sampling laser within a 1.1-mm-thick BK7 glass plate.

3.2 High-sensitivity parallel detection for high dynamic range

The dynamic range of an SSCC is defined by the ratio between the maximum and minimum detectable intensities. As the upper limit is restricted by the laser damage of optical elements and thus is fixed to some extent, the dynamic range is mainly limited by the sensitivity of detector used in SSCC. The time-to-space encoding in SSCC precludes the use of single-element PMT detector and necessitates a multi-element detector. The CCD, as a commercial multi-element detector, is extensively used in the majority of SSCC investigations^{[Reference Collier, Hernandez-Gomez, Allott, Danson and Hall15–Reference He, Zhu, Wang, Cheng, Zou, Wu and Xie23]}. However, it has a much poorer sensitivity compared to the known most sensitive PMT detector. As a result, it limits the typical dynamic range of SSCC to about $10^{6}$ , much lower than the dynamic range of ${>}10^{10}$ obtainable by DSCC with a PMT detector.

In order to apply sensitive PMT into the SSCC, we proposed and demonstrated an ‘adapter’ that can convert the spatially parallel signal into temporally serial signal^{[Reference Zhang, Qian, Yuan, Zhu, Wen and Xu29, Reference Qian, Zhang, Yuan and Zhu30]}. The adapter to PMT is constituted by 100 fiber channels with different lengths, as shown in Figure 4(a). These fibers are integrated together into a one-dimensional (1D) fiber array by a high precision V-groove technique at one end, and bundled at the other end. The spatially parallel signal will be first sampled by the fiber array into 100 channels of sub-signals. Due to the length increment between adjacent fibers, each sub-signal will be delayed sequentially, thus delivered successively out of the fiber bundle. The time delay ( $\unicode[STIX]{x0394}t$ ) between adjacent sub-signals is determined by the increment of fiber length ( $\unicode[STIX]{x0394}l$ ) and the refractive index of fiber core ( $n$ ), $\unicode[STIX]{x0394}t=\unicode[STIX]{x0394}l\cdot n/c$ . $\unicode[STIX]{x0394}t$ should be larger than the response time of PMT to resolve all the 100 sub-signals. For the PMT with a typical response time of 1 ns, the optimal length increment of fiber channels $\unicode[STIX]{x0394}l$ should be approximately 1–1.5 m.

The invented detection system shown in Figure 4(a) combines a parallel-to-serial mapping of fiber adapter and a high sensitivity of PMT. To accommodate a high dynamic range and ensure a linear response of PMT, a series of variable attenuators may be used to reduce the signal intensities in different fiber channels. Therefore, the fiber-based adapter in practice is often composed of two parts as shown in Figure 4(b). The open ends of these fibers are covered with FC connectors. Normally, the two parts are connected correspondingly with 100 flanges with negligible loss. If needed, fiber attenuators instead of flanges can be used to connect with the corresponding fiber channels. The fiber-based structure used in the detection system facilitates the introduction of variable attenuations for parallel signals. As a comparison, it is more difficult to fabricate the required spatially varying neutral-density filters for CCDs as shown by the inset of Figure 4(a)^{[Reference Collier, Hernandez-Gomez, Allott, Danson and Hall15–Reference Dorrer, Bromage and Zuegel21]}. A band-pass filter at the correlation signal wavelength is added between the fiber bundle and PMT to block the PT and sampling components.

This high-sensitivity parallel detection system promotes the dynamic range of SSCC up to $3\times 10^{10}$ , comparable to that of a DSCC, as shown in Figure 4(c)^{[Reference Wang, Ma, Wang, Yuan, Xie, Ge, Liu, Yuan, Zhu and Qian33]}. By inserting a 1.1-mm-thick BK7 plate in the sampling arm, as a demonstration, we can create three equally spaced spikes via multiple Fresnel reflections in the trailing edge of sampling pulse, which will translate into three artificial spikes on the side of correlation trace that corresponds to the leading edge of PT pulse. The evidence for capturing the third replica with a relative intensity of ${\sim}10^{-9}$ clearly demonstrates the high dynamic range of the SSCC.

3.3 Disturbed noise reduction for high fidelity measurement

The high-sensitivity parallel detection system enhances the detectability for the noise background of PT pulse. On the other hand, it is also sensitive enough to resolve the disturbing or artificial noise produced during the SSCC measurement, such as scattering noise and artificial reflection spikes as illustrated in Figure 5 ^{[Reference Wang, Yuan, Ma and Qian24, Reference Qian, Wang, Yuan, Ma and Xie25]}. These disturbing noises may degrade measurement fidelity. It is difficult for a CCD-based SSCC to resolve such measurement noises due to its limited sensitivity. Furthermore, a high dynamic range cannot be practically achieved before the disturbing noise is eliminated or reduced substantially. Note, the disturbing noise such as scattering noise is inherently related to the time-to-space encoding in an SSCC, which does not exist in a conventional DSCC.

Figure 5. Schematic plots for the formation of the SSCC-related artifacts and the methods to remove them. (a) Artificial noise pedestal caused by air scattering of the correlation signal; (b) scattering noise suppression by using a stripe filter. FA, fiber array. SF, stripe filter. (c) The first kind of artificial spikes caused by stray reflection of sampling pulse. (d) A PPLN configuration capable of removing the first kind of artificial spikes. (e) The second kind of artificial spike caused by stray reflection of the correlation signal. (f) Scheme of removing the second kind of artificial spike by controlling the PM condition.

The disturbing noise can be revealed by comparing the correlation trace of SSCC with that of DSCC. Figure 6 summarizes the measurement results of a commercial femtosecond Ti:sapphire regenerative amplifier (details can refer to Ref. [Reference Wang, Yuan, Ma and Qian24]). Typically, an extra pedestal appears on the SSCC trace [black curve in Figure 6(a)], compared to the DSCC trace [red curve in Figure 6(a)]. This pedestal can be attributed to the Rayleigh scattering of the correlation signal by the air gap between the crystal and fiber array, especially by the signal peak [Figure 5(a)]. Owing to the time-to-space encoding, the spatially dispersed scattering background will lead to a pedestal on the correlation trace, even if the PT pulse itself is background-free. The scattering intensity is approximately $10^{-8}$ – $10^{-6}$ of the signal peak^{[Reference Wang, Ma, Yuan, Tang, Zhou, Xie and Qian40]}, higher than the system detection limit of $10^{-10}$ . The detection limit may be recovered if we attenuate the signal peak by a factor of at least $10^{4}$ . We fabricated a stripe filter that has a transmission of $10^{-4}$ within a 2-mm-wide coating area. Such a stripe filter was placed just behind the crystal with its center aligning to the peak of correlation signal, as shown in Figure 5(b). After dramatic depression of the scattering noise, the true noise pedestal of PT pulse can be well resolved [blue curve in Figure 6(a)].

Figure 6. Measured correlation traces. (a) Measured SSCC traces before (black curve) and after (blue curve) the elimination of the scattering noise using a stripe filter. Red curve shows the DSCC trace for the same PT pulse as a comparison. The two spikes around $+15~\text{ps}$ and $-15~\text{ps}$ are caused by Fresnel reflections of the PT and sampling pulses between the crystal surfaces. Their intensities are comparable because the crystal refractive indexes at the wavelengths of PT and sampling pulses are nearly the same. (b) SSCC traces measured with the designed PPLN crystal with $L_{1}=1~\text{mm},L_{2}=2~\text{mm}$ . The black and red curves correspond to the PM conditions of ( $\unicode[STIX]{x1D6FC}=20^{\circ }$ , $\unicode[STIX]{x1D6FD}=44^{\circ }$ ) and ( $\unicode[STIX]{x1D6FC}=4^{\circ }$ , $\unicode[STIX]{x1D6FD}=78^{\circ }$ ), respectively. The red trace has a higher fidelity by removing the two artificial spikes at $-2~\text{ps}$ and $-4~\text{ps}$ , caused by reflection of correlation signal, to the trailing edge of main pulse.

As can be seen from Figure 6(a), there are two extra spikes around $\pm 15~\text{ps}$ on the SSCC traces compared to the DSCC trace, which can be regarded as measurement artifacts. The artificial spike at the trailing edge of the main pulse is obviously caused by the stray reflection of PT pulse between the crystal surfaces. However, it is hard, at the first sight, to understand the origin of the artificial spike at the leading edge of the main pulse. Actually, it is caused by the stray reflection of sampling pulse between the crystal surfaces [Figure 5(c)]. This type of artificial noise exists in various cross-correlators including DSCCs. Coating the crystal with anti-reflecting film may help reduce this type of artifacts, but can hardly remove them and will degrade the ultrahigh dynamic range. We propose a solution to eliminate this kind of artifacts. As shown in Figure 5(c), the time interval $\unicode[STIX]{x0394}t$ between the first-order artificial spike and the main peak is determined by the crystal length $L$ , $\unicode[STIX]{x0394}t=2n_{\text{S}}L/c$ . If $L$ is large enough to let $\unicode[STIX]{x0394}t$ be larger than the temporal window $\unicode[STIX]{x0394}T$ , the first-order artificial spike (and also the high-order ones) will move out of the temporal window. However, as implied by Equation (2), the increase of crystal length will degrade the temporal resolution as well. From this point of view, the measurement fidelity and temporal resolution is also a trade-off in SSCC with a bulk crystal. This trade-off can be readily released by the QPM design as shown in Figure 5(d). The crystal can be designed as a combination of a short poled portion ( $L_{1}$ ) and a long unpoled portion ( $L_{2}$ ). The temporal resolution $\unicode[STIX]{x1D6FF}\unicode[STIX]{x1D70F}$ is then determined only by the poled portion ( $L_{1}$ ), whereas the temporal location $\unicode[STIX]{x0394}t$ of pre-artifact is determined by the whole crystal length ( $L_{1}+L_{2}$ ). Therefore, the pre-artifacts can be tuned far away from the main pulse by increasing $L_{2}$ , whereas a high resolution can be ensured by maintaining a short $L_{1}$ [black curve in Figure 6(b)].

The increase of whole crystal length makes the SSCC more easily affected by the second kind of artificial spikes, which is caused by stray reflection of correlation signal between the crystal surfaces [see the two spikes just before the main pulse on the black trace shown in Figure 6(b)]. As shown in Figure 5(e), the generated SFG correlation signal is reflected for several times between the crystal surfaces, thus extra spikes will impose on the correlation trace if the SFG beam is not perpendicular to the crystal. The spike locations are determined by the propagation angle of the SFG beam and the length of the crystal. These artificial spikes may immerse in the main peak if the crystal is not long enough. However, in the crystal design shown in Figure 5(d), they can be easily removed owing to the longer crystal. Thanks to the QPM structure, we can shift and delay this kind of artifact far away after the main peak by appropriate parameters setting, as illustrated in Figures 5(f) and 6(b). Thus, proper QPM design may tune both kinds of artifacts out of the temporal window.

4.1 Integration of the key technologies

Here in above, we have introduced several key technologies fulfilling the major demands of a practical SSCC, i.e., high dynamic range, large temporal window, high resolution and high fidelity. A prototype of SSCC is schematically shown in Figure 7(a), which includes three units, i.e., sampling pulse generation, a cross-correlation process and a parallel detection system. The clean sampling pulse can be generated by various nonlinear processes. For example, SHG of the PT pulse can be adopted as a short-wavelength sampling pulse, whereas OPA or SCG process can generate a long-wavelength sampling pulse.

Figure 7. (a) Schematic diagram of noncollinear SSCC. BS, beam splitter; $\text{L}_{1}$ , imaging lens; $\text{L}_{2}$ , focusing lens. (b) SSCC measurement (red curve) versus Sequoia measurement (blue curve). Tiny spikes at $-27~\text{ps}$ and $-32~\text{ps}$ , appearing on the red trace were the artifacts caused by the two beam splitters used in SSCC.

The cross-correlation unit undertakes the time-to-space encoding, and determines the main performance of SSCC. Both the PT and sampling beams should be wide enough in the plane ( $x$ – $z$ ) of noncollinear PM to support a large temporal window. The beam widths in another transverse dimension ( $y$ ) can be designed for proper intensities. Both beams in the $y$ direction should be focused upon the crystal by cylindrical lenses or mirrors. QPM crystals as well as conventional bulk crystals are applicable for the cross-correlation. In a real single-shot environment, bulk crystals may work better than QPM crystals in the aspect of output stability, since QPM crystals typically have a small thickness (e.g., 0.5 mm), which may not overlap with the beams in the $y$ direction. Therefore, the SSCCs developed for PW laser applications adopt the cross-correlation configuration shown in Figure 2(a) with large aperture $\unicode[STIX]{x03B2}$ -BBO crystals. The spatial location of the signal pulse peak out of the crystal can be adjusted by the delay line built in the arm of the PT pulse. For revealing the prepulse features, the main peak is often tuned toward the rear edge of the temporal window.

In principle, the noncollinear cross-correlation based on time-to-space encoding requires uniform PT and sampling beams to avoid overestimation of noise. However, the cross-correlation measurement of pulse contrast is very different from the well-known measurement of femtosecond pulse duration. The noise pedestal has fluctuations in the picosecond time scale and also varies orders of magnitude within a large temporal window ( ${\sim}70~\text{ps}$ in our device). Therefore, the requirement on uniform interacting beams is not so rigid. For instance, typical intensity modulations of diffraction ripples are ${\sim}36\%$ at maximum^{[Reference Siegman41]}, which may result in ${\sim}1.36{-}2.5$ times noise overestimation at a specific temporal position, but is still acceptable to the largely varied noise pedestal. It is generally regarded that there is little difference between the high-contrast levels of $1\times 10^{10}$ and $2.5\times 10^{10}$ , for instance. In addition, the noncollinear cross-correlation is implemented only in the $\mathit{x}$ -dimension, and the beam focusing in the $y$ -dimension can reduce the effect of near-field diffraction and thus the noise overestimation.

The generated spatially dispersed correlation signal is collected by the high-sensitivity parallel detection system. To suppress the effect of air scattering on the fidelity, a stripe filter is added just behind the crystal as described in Section 3.3. In the next step, an imaging lens and a focusing lens are used to couple the correlation signal into 100 fibers. A PMT successively converts the 100 optical signals into electrical pulses that can be displayed on a high speed oscilloscope. After data acquisition and calibration, one may retrieve the profile of the PT pulse.

As a demonstration, the SSCC was used to characterize the pulses cleaned by a cross-polarized wave generation (XPW) device. A dynamic range of $3\times 10^{10}$ was achieved [Figure 7(b)], which is appropriate for characterizing the pulse contrast of petawatt lasers. Furthermore, we have made a comparison between the measurement results of the SSCC and a commercial DSCC (i.e., Sequoia). The two results show an excellent agreement in terms of the noise background, temporal spikes and the main pulse, as shown in Figure 7(b). The SSCC also successfully measured the pulse contrast of a 200 TW femtosecond Ti:sapphire laser operating at 10 Hz^{[Reference Wang, Ma, Wang, Yuan, Xie, Ge, Liu, Yuan, Zhu and Qian33]}.

4.2 Installation and initialization

In this section, we simply introduce how to install the SSCC in single-shot laser situation, and emphasize on how to quickly set the proper attenuations for achieving high dynamic range. The SSCC employs two types of attenuation. The first type is the stripe filter behind the correlating crystal for suppressing the scattering noise. The second type is the attenuators in the fiber channels for tuning the output signal from fiber bundle within the dynamic range of PMT. In order to ensure linear response, we keep all the sub-signals within a relative range of ${\sim}10^{3}$ , although the typical dynamic range of PMT is about $10^{5}$ . Here, we illustrate the procedure for presetting the two types of attenuation by a virtual example of the PT pulse, as shown in Figure 8(a).

Figure 8. (a) An exemplary PT pulse profile with a strong prepulse and a noise pedestal around the main pulse. (b)–(d) Presetting procedure for the attenuations of SSCC aiming at measuring the PT pulse shown in (a).

As the PT pulse profile is unknown in advance, we first insert a piece of neutral-density filter before the fiber array, whose attenuation should be initially selected to be high enough and be reduced step by step in order to protect the PMT. Suppose such an external filter with a $10^{5}$ attenuation is properly set, then one can determine the spatial locations of the main pulse and one prepulse by using the first laser shot of test. As the generated correlation signals, at these two locations, are intense enough to produce scattering noise, both of them should be attenuated by additional stripe filters. Based on the first-shot test measurement, two stripe filters with attenuation of $10^{6}$ (i.e., over the dynamic range of PMT) and $10^{4}$ (i.e., over the relative sub-signal range of $10^{3}$ ) are inserted at the spatial locations of the main pulse and the prepulse, respectively. After setting the stripe filters, we lower the attenuation of neutral-density filter from $10^{5}$ to $10^{2}$ , a reduction factor same to the relative sub-signal range of $10^{3}$ . At this moment, we are ready for the second laser shot of test. For the PT pulse example shown in Figure 8(a), noise pedestal exists around the main pulse, and thus attenuators in the fiber channels are needed. As the external neutral-density filter will be removed away finally, attenuation of $10^{2}$ at least or higher for the fiber channels around the main pulse is required. We can remove the external neutral filter when the fiber attenuators are well set. Finally, we further check if the sub-signal amplitude in each fiber channel has been adjusted appropriately by a third laser shot of test.

The step-by-step method introduced in Figure 8 allows the complete presetting of attenuations associated in the SSCC only by three laser shots of test, although 100 fiber channels are involved. After this initialization, the SSCC can start working online as a real-time monitor for pulse contrast. At current stage, it needs about twenty minutes to read out and process the 100 sub-signals artificially for each measurement. In next step, we plan to develop a real-time data processor for our SSCC.

Figure 9. Two application examples of the SSCC prototypes. (a) Picture of the 1053-nm version and (b) contrast measurement result for the SG-II Nd:glass petawatt laser. (c) Picture of the 800-nm version and (d) contrast measurement result for the SULF-5 PW Ti:sapphire laser.

4.3 In situ applications on petawatt laser facilities

Until now, we have developed five SSCC prototypes for the petawatt facilities in China with two typical examples shown in Figure 9. These SSCCs include two wavelength versions, the 1053-nm version [Figure 9(a)] and the 800-nm version [Figure 9(c)]. Since the year of 2014, the 1053-nm version has been operating on the SG-II Nd:glass petawatt laser at Shanghai Institute of Optics and Fine Mechanics (SIOM), Chinese Academy of Sciences (CAS)^{[Reference Ouyang, Cui, Zhu, Zhu and Zhu35]}. Four other sets of the 800-nm version have been applied successively on the 1-PW Ti:sapphire laser at SIOM of CAS, the 1-PW Ti:sapphire laser at Institute of Physics (IOP) of CAS, the 5-PW OPCPA laser at Laser Fusion Research Center (LFRC) of China Academy of Engineering Physics (CAEP)^{[Reference Zeng, Zhou, Zuo, Zhu, Su, Wang, Wang, Huang, Jiang, Jiang, Guo, Xie, Zhou, Wu, Mu, Peng and Jing36]} and the 5-PW Ti:sapphire laser at Shanghai Superintense Ultrafast Laser Facility (SULF) of CAS^{[Reference Yu, Xu, Liu, Li, Li, Liu, Li, Wu, Yang, Yang, Wang, Leng, Li and Xu37]}. All these laser facilities operate in a single-shot mode, which are appropriate sources for testing the performance of the SSCCs. All the SSCCs have succeeded in measuring the pulse contrast with a dynamic range of $10^{10}$ , with one example shown in Figure 9(d). Besides, the SSCCs can also be used as real-time monitors for the optimization of laser operation. With the aid of the SSCC, pulse contrast of the SG-II PW laser facility has been improved from $10^{4}$ initially to $10^{8}$ actually [Figure 9(b)], which is the reported highest pulse contrast among the Nd:glass petawatt lasers worldwide^{[Reference Ouyang, Cui, Zhu, Zhu and Zhu35]}.

In these SSCCs, the large-size $\unicode[STIX]{x03B2}$ -BBO crystals are adopted, which may support a temporal window of 50 ps for the 800-nm version and 70 ps for the 1053-nm version, respectively. Extension of temporal window can be realized via splicing several single-shot measurement results, with successive increment of the relative delay by adjusting the delay line built in the arm of PT pulse. The delay increment should be less than the single-shot temporal window, such that the data in the overlapped part of adjacent measurements can be used as calibration base, assuming shot-to-shot fluctuation is negligible. Such a multi-shot measurement scheme can extend the measurement temporal range to ${>}100~\text{ps}$ , which is limited by the range of the delay line. The results shown in Figures 9(b) and 9(d) are obtained both by using two shots. The successful applications verify the feasibility and practicability of the SSCCs. Besides, it can be easily extended to other laser wavelengths. Actually, the SSCC will show better measurement performance in mid-IR spectral region since the longer wavelength of correlation signal matches the detection system better in this case.