1 Introduction

Marine boundary layer (MBL) clouds cover about one-fifth of Earth's surface and play an important role in the climate system (Wood, 2012). A faithful simulation of MBL clouds in the global climate model (GCM) is critical for the projection of future climate (Bony and Dufresne, 2005; Bony et al., 2015; Boucher et al., 2013) and understanding of aerosol–cloud interactions (Carslaw et al., 2013; Lohmann and Feichter, 2005). Unfortunately, this turns out to be an extremely challenging task. Among others, an important reason is that many physical processes in MBL clouds occur on spatial scales that are much smaller than the typical resolution of GCMs.

Of particular interest in this study is the warm-rain processes that play an important role in regulating the lifetime, water budget, and therefore integrated radiative effects of MBL clouds. In the bulk cloud microphysics schemes that are widely used in GCMs (Morrison and Gettelman, 2008), continuous cloud particle spectrum is often divided into two modes. Droplets smaller than the separation size $r^{\ast }$ are classified into the cloud mode, which is described by two moments of droplet size distribution (DSD), the droplet number concentration $N_{\mathrm{c}}$ (0th moment of DSD), and droplet liquid water content $q_{\mathrm{c}}$ (proportional to the third moment). Droplets larger than $r^{\ast }$ are classified into a precipitation mode (drizzle or rain), with properties denoted by drop concentration and water content ($N_{\mathrm{r}}$ and $q_{\mathrm{r}}$). In a bulk microphysics scheme, the transfer of mass from the cloud to rain modes as a result of the collision–coalescence process is separated into two terms, autoconversion and accretion:${\left(\frac{\partial q_{\mathrm{r}}}{\partial t}\right)}_{\mathrm{coal}}={\left(\frac{\partial q_{\mathrm{r}}}{\partial t}\right)}_{\mathrm{auto}}+{\left(\frac{\partial q_{\mathrm{r}}}{\partial t}\right)}_{\mathrm{acc}}$. Autoconversion is defined as the rate of mass transfer from the cloud to rain mode due to the coalescence of two cloud droplets with $r<r^{\ast }$. Accretion is defined as the rate of mass transfer due to the coalescence of a rain drop with $r>r^{\ast }$ with a cloud droplet. A number of autoconversion and accretion parameterizations have been developed, formulated either through numerical fitting of droplet spectra obtained from bin microphysics LES or parcel model (Khairoutdinov and Kogan, 2000), or through an analytical simplification of the collection kernel to arrive at expressions that link autoconversion and accretion with the bulk microphysical variables (Liu and Daum, 2004). For example, a widely used scheme developed by Khairoutdinov and Kogan (2000) (“KK scheme” hereafter) relates the autoconversion with $N_{\mathrm{c}}$ and $q_{\mathrm{c}}$ as follows:

1$${\left({\displaystyle \frac{\partial q_{\mathrm{r}}}{\partial t}}\right)}_{\mathrm{auto}}=f_{\mathrm{auto}}\left(q_{\mathrm{c}},N_{\mathrm{c}}\right)=C{q}_{\mathrm{c}}^{{\mathit{\beta }}_q}{N}_{\mathrm{c}}^{{\mathit{\beta }}_N},$$ where $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ have units of kg kg${}^{-\mathrm{1}}$ and cm${}^{-\mathrm{3}}$, respectively; the parameter $C=\mathrm{1350}$ and the two exponents ${\mathit{\beta }}_q=\mathrm{2.47}$ and ${\mathit{\beta }}_N=-\mathrm{1.79}$ are obtained through a nonlinear regression between the variables $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ and the autoconversion rate derived from large-eddy simulation (LES) with bin-microphysics spectra.

Having a highly accurate microphysical parameterization – specifically, highly accurate local microphysical process rates – is not sufficient for an accurate simulation of warm-rain processes in GCMs. Clouds can have significant structures and variations at the spatial scale much smaller than the typical grid size of GCMs (10–100 km) (Barker et al., 1996; e.g., Cahalan and Joseph, 1989; Lebsock et al., 2013; Wood and Hartmann, 2006; Zhang et al., 2019). Therefore, GCMs need to account for these subgrid-scale variations in order to correctly calculate grid-mean autoconversion and accretion rates. Pincus and Klein (2000) nicely illustrate this dilemma. Given subgrid-scale variability represented as a distribution $P\left(x\right)$ of some variable $x$, for example the $q_{\mathrm{c}}$ in Eq. (1), a grid-mean process rate is calculated as $⟨f\left(x\right)⟩=\int f\left(x\right)P\left(x\right)\mathrm{d}x$ , where $f\left(x\right)$ is the formula for the local process rate. For nonlinear process rates such as autoconversion and accretion, the grid-mean process rates calculated from the subgrid-scale variability do not equal the process rate calculated from the grid-mean value of $x$, i.e., $⟨f\left(x\right)⟩\ne f(⟨x⟩)$. Therefore, calculating autoconversion and accretion from grid-mean quantities introduces biases arising from subgrid-scale variability. To take this effect into account, a parameter $E$ is often introduced as part of the parameterization such that $⟨f\left(x\right)⟩=E\cdot f(⟨x⟩)$. Following the convention of previous studies, $E$ is referred to as the enhancement factor (EF) here. Given the autoconversion parameterization scheme, the magnitude of EF is primarily determined by cloud horizontal variability within a GCM grid. Unfortunately, because most GCMs do not resolve subgrid cloud variation, the value of EF is often simply assumed to be a constant for the lack of better options. In the previous generation of GCMs, the EF for the KK autoconversion scheme due to subgrid $q_{\mathrm{c}}$ variation is often simply assumed to be a constant. For example, in the widely used Community Atmosphere Model (CAM) version 5 (CAM5) the EF for autoconversion is assumed to be 3.2 (Morrison and Gettelman, 2008).

A number of studies have been carried out to better understand the horizontal variations of cloud microphysics in MBL cloud and the implications for warm-rain simulations in GCMs. Most of these studies have been focused on the subgrid variation of $q_{\mathrm{c}}$. Morrison and Gettelman (2008) and several later studies (Boutle et al., 2014; Hill et al., 2015; Lebsock et al., 2013; Zhang et al., 2019) showed that the subgrid variability $q_{\mathrm{c}}$ and thereby the EF are dependent on cloud regime and cloud fraction ($f_{\mathrm{c}}$). They are generally smaller over the closed-cell stratocumulus regime with higher $f_{\mathrm{c}}$ and larger over the open-cell cumulus regime that often has a relatively small $f_{\mathrm{c}}$. The subgrid variance of $q_{\mathrm{c}}$ is also dependent on the horizontal scale ($L$) of a GCM grid. Based on the combination of in situ and satellite observations, Boutle et al. (2014) found that the subgrid $q_{\mathrm{c}}$ variance first increases quickly with $L$ when $L$ is below about 20 km, then increases slowly and seems to approach to an asymptotic value for larger $L$. Similar spatial dependence is also reported in Huang et al. (2014), Huang and Liu (2014), Xie and Zhang (2015), and Wu et al. (2018), which are based on the ground radar retrievals from the Department of Energy (DOE) Atmospheric Radiation Measurement (ARM) sites. The cloud-regime and horizontal-scale dependences have inspired a few studies to parameterize the subgrid $q_{\mathrm{c}}$ variance as a function of either $f_{\mathrm{c}}$ or $L$ or a combination of the two (e.g., Ahlgrimm and Forbes, 2016; Boutle et al., 2014; Hill et al., 2015; Xie and Zhang, 2015; Zhang et al., 2019). Inspired by these studies, several latest-generation GCMs have adopted the cloud-regime-dependent and scale-aware parameterization schemes to account for the subgrid variability of $q_{\mathrm{c}}$ and thereby the EF (Walters et al., 2019).

However, the aforementioned studies have an important limitation. They consider only the impacts of subgrid $q_{\mathrm{c}}$ variations on the EF but ignore the impacts of subgrid variation of $N_{\mathrm{c}}$ and its covariation with $q_{\mathrm{c}}$. Based on cloud fields from large-eddy simulation, Larson and Griffin (2013) and later Kogan and Mechem (2014, 2016) elucidated that it is important to consider the covariation of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ to derive a physically complete and accurate EF for the autoconversion parameterization. Lately, on the basis of MBL cloud observations from the Moderate Resolution Imaging Spectroradiometer (MODIS), Zhang et al. (2019) (hereafter referred to as Z19) have elucidated that the subgrid variation of $N_{\mathrm{c}}$ tends to further increase the EF for the autoconversion process in addition to the EF due to $q_{\mathrm{c}}$ variation. The effect of $q_{\mathrm{c}}$–$N_{\mathrm{c}}$ covariation on the other hand depends on the sign of the $q_{\mathrm{c}}$–$N_{\mathrm{c}}$ correlation. A positive $q_{\mathrm{c}}$–$N_{\mathrm{c}}$ correlation would lead to an EF $<$ 1 that partly offsets the effects of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ variations. Although Z19 shed important new light on the EF problem for the warm-rain process, their study also suffers from limitations due to the use of satellite remote sensing data. First, as a passive remote sensing technique, the MODIS cloud product can only retrieve the column-integrated cloud optical thickness and the cloud droplet effective radius at cloud top, from which the column-integrated cloud liquid water path (LWP) is estimated. As a result of using LWP, instead vertically resolved observations the vertical dependence of the $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ horizontal variabilities are ignored in Z19. Second, the $N_{\mathrm{c}}$ retrieval from MODIS is based on several important assumptions, which can lead to large uncertainties (see review by Grosvenor et al., 2018). Furthermore, the MODIS cloud retrieval product is known to suffer from several inherent uncertainties, such as the three-dimensional radiative effects(e.g., Zhang and Platnick, 2011; Zhang et al., 2012, 2016), which in turn can lead to large uncertainties in the estimated EF.

This study is a follow-up of Z19. To overcome the limitations of satellite observations, we use the in situ measurements of MBL cloud from a recent DOE field campaign, the Aerosol and Cloud Experiments in the Eastern North Atlantic (ACE-ENA), to investigate the subgrid variations of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$, as well as their covariation, and the implications for the simulation of autoconversion simulation in GCMs. A main focus of this investigation is to understand the vertical dependence of the $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ horizontal variations within the MBL clouds. This aspect has been neglected in Z19 as well as most previous studies (Boutle et al., 2014; Lebsock et al., 2013; Xie and Zhang, 2015). A variety of microphysical processes, such as adiabatic growth, collision–coalescence, and entrainment mixing, can influence the vertical structure of MBL clouds. At the same time, these processes also vary horizontally at the subgrid scale of GCMs. As a result, the horizontal variations of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$, as well as their covariation, and therefore the EFs may depend on the vertical location inside the MBL clouds. It is important to understand this dependence for several reasons. First, the warm-rain process is usually initialized at cloud top where the autoconversion process of the cloud droplets gives birth to embryo drizzle drops. The accretion process is, on the other hand, more important in the lower part of the cloud (Wood, 2005b). Thus, a better understanding of the vertical dependence of horizontal variations of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ inside MBL clouds could help us understand how the EF should be modeled in the GCMs for both autoconversion and accretion. Second, a good understanding of the vertical dependence of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ variation inside MBL clouds will also help us understand the limitations in the previous studies, such as Z19, that use the column-integrated products for the study of EF. Finally, this investigation may also be useful for modeling other processes, such as aerosol–cloud interactions, in the GCMs.

Therefore, our main objectives in this study are to (1) better understand the horizontal variations of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$, their covariation, and the dependence on vertical height in MBL clouds; and (2) elucidate the implications for the EF of the autoconversion parameterization in GCMs. The rest of the paper is organized as follows: we will describe the data and observations used in this study in Sect. 2 and explain how we select the cases from the ACE-ENA campaign for our study in Sect. 3. We will present case studies in Sects. 4 and 5. Finally, the results and findings from this study will be summarized and discussed in Sect. 6.

The data and observations used for this study are from two main sources: the in situ measurements from the ACE-ENA campaign and the ground-based observations from the ARM ENA site. The ENA region is characterized by persistent subtropical MBL clouds that are influenced by different seasonal meteorological conditions and a variety of aerosol sources (Wood et al., 2015). A modeling study by Carslaw et al. (2013) found the ENA to be one of the regions over the globe with the largest uncertainty of aerosol indirect effect. As such, the ENA region attracted substantial attention over the past few decades for aerosol–cloud interaction studies. From April 2009 to December 2010 the DOE ARM program deployed its ARM Mobile Facility (AMF) to Graciosa Island (39.09${}^{\circ }$ N, 28.03${}^{\circ }$ W) for a measurement field campaign targeting the properties of cloud, aerosol, and precipitation in the MBL (CAP-MBL) in the Azores region of ENA (Wood et al., 2015). The measurements from the CAP-MBL campaign have proved highly useful for a variety of purposes, from understanding the seasonal variability of clouds and aerosols in the MBL of the ENA region (Dong et al., 2014; Rémillard et al., 2012) to improving cloud parameterizations in the GCMs (Zheng et al., 2016) to validating the spaceborne remote sensing products of MBL clouds (Zhang et al., 2017). The success of the CAP-MBL revealed that the ENA has an ideal mix of conditions to study the interactions of aerosols and MBL clouds. In 2013 a permanent measurement site was established by the ARM program on Graciosa Island and is typically referred to as the ENA site (Voyles and Mather, 2013).

2.1 In situ measurements from the ACE-ENA campaign

The Aerosol and Cloud Experiments in ENA (ACE-ENA) project was “motivated by the need for comprehensive in situ characterizations of boundary-layer structure and associated vertical distributions and horizontal variabilities of low clouds and aerosol over the Azores” (Wang et al., 2016). The ARM Aerial Facility (AAF) Gulfstream-1 (G-1) aircraft was deployed during two intensive observation periods (IOPs), the summer 2017 IOP from 21 June to 20 July 2017 and the winter 2018 IOP from 15 January to 18 February 2018. Over 30 research flights (RFs) were carried out during the two IOPs around the ARM ENA site on Graciosa Island that sampled a large variety of cloud and aerosol properties along with the meteorological conditions.

Table 1 summarizes the in situ measurements from the ACE-ENA campaign used in this study. The location and velocity of G-1 aircraft and the environmental and meteorological conditions during the flight (temperature, humidity, and wind velocity) are taken from Aircraft-Integrated Meteorological Measurement System 20 Hz (AIMMS-20) dataset (Beswick et al., 2008). The size distribution of cloud droplets and the corresponding $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ are obtained from the fast cloud droplet probe (FCDP) measurement. The FCDP measures the concentration and size of cloud droplets in the diameter size range from 1.5 to 50 $\mathrm{\mu }$m in 20 size bins with an overall uncertainty of size around 3 $\mathrm{\mu }$m (Lance et al., 2010; SPEC, 2019). Following previous studies (Wood, 2005a), we adopt $r^{\ast }=\mathrm{20}$ $\mathrm{\mu }$m as the threshold to separate cloud droplets from drizzle drops; i.e., drops with $r<r^{\ast }$ are considered cloud droplets. After the separation, the $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ are derived from the FCDP droplet size distribution measurements. As an evaluation, we compared our FCDP-derived $q_{\mathrm{c}}$ results with the direct measurements of $q_{\mathrm{c}}$ from the multi-element water content system (WCM-2000; Matthews and Mei, 2017) also flown during the ACE-ENA and found a reasonable agreement (e.g., biases within 20 %). We also performed a few sensitivity tests in which we perturbed the value of $r^{\ast }$ from 15 up to 50 $\mathrm{\mu }$m. The perturbation shows little impact on the results shown in Sects. 4 and 5. The cloud droplet spectrum from the FCDP is available at a frequency of 10 Hz, which is used in this study. We have also done a sensitivity study, in which we averaged the FCDP data to 1 Hz and got almost identical results. Since the typical horizontal speed of the G-1 aircraft during the in-cloud leg is about 100 m s${}^{-\mathrm{1}}$, the spatial sampling rate these instruments is on the order of 10 m for the FCDP at 10 Hz.

Table 1

In situ cloud instruments from ACE-ENA campaign used in this study.

In addition to the in situ measurements, ground measurements from the ARM ENA site are also used to provide ancillary data for our studies. In particular, we will use the Active Remote Sensing of Cloud Layers product (ARSCL; Clothiaux et al., 2000; Kollias et al., 2005) which blends radar observations from the Ka-band ARM zenith cloud radar (KAZR), the micropulse lidar (MPL), and the ceilometer to provide information on cloud boundaries and the mesoscale structure of cloud and precipitation. The ARSCL product is used to specify the vertical location of the G-1 aircraft and thereby the in situ measurements with respect to the cloud boundaries, i.e., cloud base and top (see example in Fig. 1). In addition, the radar reflectivity observations from KAZR, alone with in situ measurements, are used to select the precipitating cases for our study. Note that the ARSCL product is from the vertically pointing instruments, which sometimes are not collocated with the in situ measurements from G-1 aircraft. As explained later in the next section, only those cases with a reasonable collocation are selected for our study.

Figure 1

(a) Horizontal flight track of the G-1 aircraft (red) during the 18 July 2017 RF around the DOE ENA site (yellow star) on Graciosa Island. (b) The vertical flight track of G-1 (thick black line) overlaid on the radar reflectivity contour by the ground-based KZAR. The dotted lines in the figure indicate the cloud base and top retrievals from ground-based radar and CEIL instruments. The yellow-shaded regions are the “hlegs” and green-shaded regions are the “vlegs”. See text for their definitions.

[Figure omitted. See PDF]

3.1 ACE-ENA flight pattern

The section provides a brief overview of the G-1 aircraft flight patterns during the ACE-ENA and explains the method for case selections for our study using the 18 July 2017 RF as an example. As shown in Table 2, a variety of MBL conditions were sampled during the two IOPs of the ACE-ENA campaign, from mostly clear sky to thin stratus and drizzling stratocumulus. The basic flight patterns of G-1 aircraft in the ACE-ENA included spirals to obtain vertical profiles of aerosol and clouds, as well as legs at multiple altitudes, including below cloud, inside cloud, at the cloud top, and in the free troposphere. As an example, Fig. 1a shows the horizontal location of the G-1 aircraft during the 18 July 2017 RF, which is the “golden case” for our study as explained in the next section. The corresponding vertical track of the aircraft is shown in Fig. 1b overlaid on the reflectivity curtain of the ground-based KAZR. In this RF, the G-1 aircraft repeated the horizontal level runs multiple times in a V shape at different vertical levels inside, above, and below the MBL (see Fig. 1b). The lower tip of the V shape is located at the ENA site on Graciosa Island. The average wind in the upper MBL (i.e., 900 mbar) is approximately Northwest. So, the west side of the V-shape horizontal level runs is along the wind and the east side across the wind. Note that the horizontal velocity of the G-1 aircraft is approximately 100 m s${}^{-\mathrm{1}}$. Since the duration of these selected V-shaped hlegs is between 580 and 700 s, their total horizontal length is roughly 60 km, with each side of the V shape $\sim$ 30 km. These V-shape horizontal level runs, with one side along and the other across the wind, are a common sampling strategy used in the ACE-ENA to observe the properties of aerosol and cloud at different vertical levels of the MBL. In our study we use the vertical location of the G-1 aircraft from the AIMMS to identify continuous horizontal flight tracks which are referred to as the “hlegs”. For the 18 July 2017 case, a total of 13 hlegs are identified as shown in Fig. 1b. Among them, hlegs 5, 6, 7, 8, 10, 11, and 12 are the seven V-shape horizontal level runs inside the MBL cloud. Together they provide an excellent set of samples of the MBL cloud properties at different vertical levels of a virtual GCM grid box of about 30 km. As previously mentioned, Boutle et al. (2014) found that the horizontal variance of $q_{\mathrm{c}}$ increases with the horizontal scale $L$ slowly when $L$ is larger than about 20 km. Therefore, although the horizontal sampling of the selected hlegs is only about 30 km, the lessons learned here could yield useful insights for larger GCM grid sizes. In addition to the hlegs, we also identified the vertical penetration legs in each flight, referred to as the “vlegs”, from which we will obtain the vertical structure of the MBL, along with the properties of cloud and aerosol.

Table 2

Conditions of MBL sampled during the two IOPs of the ACE-ENA campaign. Dates are given in month and day (m/dd) format.

As illustrated in Fig. 1a and b for the 18 July 2017 RF, the criteria we used to select the RF cases and the hlegs within the RF can be summarized as follows:

• The RF samples multiple continuous in-cloud hlegs at different vertical levels with the horizontal length of at least 10 km and cloud fraction larger than 10 % (i.e., the fraction of an hleg with $q_{\mathrm{c}}$ $>$ 0.01 g m${}^{-\mathrm{3}}$must exceed 10 % of the total length of that hleg). It is important to note here that, unless otherwise specified, all the analyses of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ are based on in-cloud observations (i.e., in the regions with $q_{\mathrm{c}}$ $>$ 0.01 g m${}^{-\mathrm{3}}$).

• Moreover, the selected hlegs must sample the same region (i.e., the same virtual GCM grid box) repeatedly in terms of horizontal track but different vertical levels in terms of vertical track. Take the 18 July 2017 case as an example. The hlegs 5, 6, 7, and 8 follow the same V-shaped horizontal track (see Fig. 1a) but sample different vertical levels of the MBL clouds (see Fig. 1b). Such hlegs provide us the horizontal sampling needed to study the subgrid horizontal variations of the cloud properties and, at the same time, the chance to study the vertical dependence of the horizontal cloud variations.

• Finally, the RF needs to have at least one vleg, and the cloud boundary derived from the vleg is largely consistent with that derived from the ground-based measurements. This requirement is to ensure that the vertical locations of the selected hlegs with respect to cloud boundaries can be specified. For example, as shown in Fig. 1b according to the ground-based observations, hlegs 5 and 10 of the 18 July 2017 case are close to cloud base, while hlegs 8 and 12 are close to cloud top (see also Fig. 4).

Table 3

A summary of selected RFs and the selected hlegs and vlegs within each RF.

4.1 Horizontal and vertical variations of cloud microphysics

On 18 July 2017, the North Atlantic is controlled by the Icelandic low to the north and the Azores high to the south (see Fig. 2b), which is a common pattern of large-scale circulation during the summer season in this region (Wood et al., 2015). The Azores is at the southern tip of the cold air sector of a frontal system where the fair-weather low-level stratocumulus clouds are dominant (see satellite image in Fig. 2a). The RF on this day started around 08:30 UTC and ended around 12:00 UTC. As explained in the previous section, we selected seven hlegs from this RF that horizontally sampled the same region repeatedly in a similar V-shaped track but vertically at different levels. The radar reflectivity observation from the ground-based KAZR during the same period peaks around 10 dBZ, indicating the presence of significant drizzle inside the MBL clouds.

Figure 2

(a) The real color satellite image of the ENA region on 18 July 2017 from MODIS. The small red star marks the location of the ARM ENA site on Graciosa Island. (b) The averaged sea level pressure (SLP) of the ENA region on 18 July 2017 from the MERRA-2 reanalysis.

[Figure omitted. See PDF]

Figure 3

The horizontal variations of $q_{\mathrm{c}}$ (red) and $N_{\mathrm{c}}$ (blue) for each selected hleg derived from the in situ FCDP instrument. The yellow-shaded time period in each plot corresponds to the cross-wind side of the V-shaped flight track, and the unshaded part corresponds to the along-wind part. Note that plots are ordered such that (a) hleg 8 and (e) hleg 12 are close to cloud top; (b) hleg 6, (c) hleg 7, and (f) hleg 11 are sampled in the middle of clouds; and (d) hleg 5 and (g) hleg 10 are close to cloud base.

[Figure omitted. See PDF]

Among the seven selected hlegs, hlegs 5, 6, 7, and 8 constitute one set of four consecutive V-shaped tracks, with hlegs 5 close to cloud base and hleg 8 close to cloud top. The hlegs 10, 11, and 12 are another set of consecutive V-shaped tracks with hlegs 10 and 12 close to cloud base and top, respectively (see Fig. 1). Using $q_{\mathrm{c}}>\mathrm{0.01}$ g m${}^{-\mathrm{3}}$ as a threshold for cloud, the cloud fraction ($f_{\mathrm{c}}$) of all these hlegs is close to unity (i.e., overcast), except for the two hlegs close to cloud base ($f_{\mathrm{c}}=$ 46 % for hleg 5 and $f_{\mathrm{c}}=$ 51 % for hleg 10). The $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ derived from the in situ FCDP measurements for these selected hlegs are plotted in Fig. 3 as a function of UTC time. It is evident from Fig. 3 that both $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ have significant horizontal variations. At cloud base (see Fig. 3d for hleg 5 and Fig. 3g for hleg 10) the $q_{\mathrm{c}}$ varies from 0.01 g m${}^{-\mathrm{3}}$ (i.e., the lower threshold) up to about 0.4 g m${}^{-\mathrm{3}}$ and the $N_{\mathrm{c}}$ from 25 up to 150 cm${}^{-\mathrm{3}}$, with the mean in-cloud values around 0.08 g m${}^{-\mathrm{3}}$ and 65 cm${}^{-\mathrm{3}}$, respectively. Such strong variations of cloud microphysics could be contributed by a number of factors. One can see from the ground radar and lidar observations in Fig. 1b that the height of cloud base varies significantly. As a result, the horizonal legs may not really sample the cloud base. In addition, the variability in updraft at cloud base could lead to the variability in the activation and growth of cloud condensation nuclei (CCN). In the middle of the MBL cloud, i.e., hleg 6 (Fig. 3c), 7 (Fig. 3b) and 11 (Fig. 3f), the mean value of $q_{\mathrm{c}}$ is significantly larger than that of cloud base hlegs while the variability is reduced. The mean value of $q_{\mathrm{c}}$ keeps increasing toward cloud top to $\sim$ 0.73 g m${}^{-\mathrm{3}}$ in hleg 8 (Fig. 3a) and to $\sim$ 0.53 g m${}^{-\mathrm{3}}$ in hleg 12 (Fig. 3e), respectively. In contrast, the horizontal variability of $q_{\mathrm{c}}$ seems to increase in comparison to those observed in mid-level hlegs.

Figure 4

(a) The vertical profiles of $q_{\mathrm{c}}$ derived from the vlegs (dotted lines) of the 18 July 2017 case. The overplotted red error bars indicate the mean values and standard deviations of the $q_{\mathrm{c}}$ derived from the selected hlegs at different vertical levels. (b) Same as panel (a) except for $N_{\mathrm{c}}$. (c) The vertical profile of the inverse relative variances (i.e., mean divided by standard deviation) of $N_{\mathrm{c}}$ (red circle) and $N_{\mathrm{c}}$ (blue triangle) derived from the hleg; (d) the vertical profile of the linear correlation coefficient between $\ln \left(q_{\mathrm{c}}\right)$ and $\ln \left(N_{\mathrm{c}}\right)$, i.e., ${\mathit{\rho }}_{\mathrm{L}}$ (square), and the linear correlation coefficient between $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$, i.e., $\mathit{\rho }$ (diamond).

[Figure omitted. See PDF]

To obtain a further understanding of the vertical variations of cloud microphysics, we analyzed the cloud microphysics observations from the two green-shaded vlegs 1 and 3 in Fig. 1b. The vertical profiles of the mean $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ from these two vlegs are shown in Fig. 4a and b, respectively, with the mean and standard deviation of the $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ derived from the seven selected hlegs overplotted. Overall, the vertical profiles of the $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ are qualitatively aligned with the classic adiabatic MBL cloud structure (Brenguier et al., 2000; Martin et al., 1994). That is, the $N_{\mathrm{c}}$ remains relatively constant (see Fig. 4b), while the $q_{\mathrm{c}}$ increases approximately linearly with height from cloud base upward as a result of condensation growth (see Fig. 4a,), except for the very top of the cloud, i.e., the entrainment zone where the dry air entrained from above mixes with the humid cloudy air in the MBL. In previous studies, a so-called inverse relative variance, $\mathit{\nu }$, is often used to quantify the subgrid variations of cloud microphysics. It is defined as follows: 2$${\mathit{\nu }}_X={\displaystyle \frac{⟨x{⟩}^{\mathrm{2}}}{{\mathit{\sigma }}_X^{\mathrm{2}}}},$$ where $X$ is either $q_{\mathrm{c}}$ (i.e., ${\mathit{\nu }}_X={\mathit{\nu }}_{q_{\mathrm{c}}}$) or $N_{\mathrm{c}}$ (i.e., ${\mathit{\nu }}_X={\mathit{\nu }}_{N_{\mathrm{c}}}$) (Barker et al., 1996; Lebsock et al., 2013; Zhang et al., 2019). $⟨x⟩$ and ${\mathit{\sigma }}_X$ are the mean value and standard deviation of $X$, respectively. As such, the smaller the $\mathit{\nu }$ value, the larger the horizontal variation of $X$ in comparison to the mean value. As shown in Fig. 4c, the ${\mathit{\nu }}_{q_{\mathrm{c}}}$ and ${\mathit{\nu }}_{N_{\mathrm{c}}}$ derived from the selected hlegs follow a similar vertical pattern: they both increase first from cloud base upward and then decrease in the entrainment zone, with the turning point somewhere around 1 km (i.e., around hleg 7 and 11). It indicates that both $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ have significant horizontal variabilities at cloud base which may be a combined result of horizontal fluctuations of dynamics (e.g., updraft) and thermodynamics (e.g., temperature and dynamics), as well as horizontal variations of aerosols. The horizontal variabilities of both $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ both decrease upward toward cloud top until the entrainment zone where both variabilities increase again.

Figure 5

The joint distributions of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$, along with the marginal histograms, for the seven selected hlegs from the 18 July 2017 RF. As in Fig. 3, the plots are ordered such that (a) hleg 8 and (e) hleg 12 are close to cloud top; (b) hleg 6, (c) hleg 7, and (f) hleg 11 are sampled in the middle of clouds; and (d) hleg 5 and (g) hleg 10 are close to cloud base.

[Figure omitted. See PDF]

So far, in all the analyses above, the variations of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ have been considered separately and independently. As pointed out in several previous studies, the covariation of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ could have an important impact on the EF for the autoconversion process in GCMs (Kogan and Mechem, 2016; Larson and Griffin, 2013; Zhang et al., 2019). This point will be further elucidated in detail in the next section. Figure 5 shows the joint distributions of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ for the seven selected hlegs, and the corresponding linear correlation coefficients as a function of height are shown in Fig. 4d. For the sake of reference, the linear correlation coefficient between $\ln \left(q_{\mathrm{c}}\right)$ and $\ln \left(N_{\mathrm{c}}\right)$ , i.e., the ${\mathit{\rho }}_{\mathrm{L}}$ that will be introduced later in Eq. (4), is also plotted in Fig. 4d. Looking first at hlegs 10, 11, and 12, i.e., the second group of consecutive V-shaped legs, there is a clear increasing trend of the correlation between $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ from cloud bottom ($\mathit{\rho }=\mathrm{0.75}$ for hleg 10) to cloud top ($\mathit{\rho }=\mathrm{0.95}$ for hleg 12). The picture based on hlegs 5, 6, 7, and 8 is more complex. As shown in Fig. 5, the joint distributions of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ of hleg 6 (Fig. 5b), hleg 7 (Fig. 5c), and, to a less extent, hleg 8 (Fig. 5d) all exhibit a clear bimodality. Further analysis reveals that each of the two modes in these bimodal distributions approximately corresponds to one side of the V-shaped track. To illustrate this, the east side (i.e., across wind) of the hleg is shaded in yellow in Fig. 3. It is intriguing to note that the $N_{\mathrm{c}}$ values from the east side of the hleg are systematically larger than those from the west side, while their $q_{\mathrm{c}}$ values are largely similar. It is unlikely that the bimodality is caused by the along-wind and across-wind difference between the two sides of the V-shaped track. It is most likely just a coincidence. On the other hand, the bimodal joint distribution between $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ is real, which could be a result of subgrid variations of updraft, precipitation, and/or aerosols.

As a result of the bimodality of $N_{\mathrm{c}}$, the correlation coefficients between $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ is significantly smaller for hlegs 6 ($\mathit{\rho }=\mathrm{0.22}$) and 7 ($\mathit{\rho }=\mathrm{0.31}$) in comparison to other hlegs. However, if the two sides of the V-shaped tracks are considered separately, then $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ become more correlated, except for the east side of hleg 6, which still exhibits to some degree a bimodal joint distribution of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$. In spite of the bimodality, there is evidently a general increasing trend of the correlation between $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ from cloud base toward cloud top. At the cloud top, the $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ correlation coefficient can be as high as $\mathit{\rho }=\mathrm{0.95}$ for hleg 12 (see Fig. 5e). As explained in the next section, this close correlation between $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ has important implications for the simulation of the autoconversion enhancement factor.

As a summary, the above phenomenological analysis of the 18 July 2017 RF reveals the following features of the horizontal and vertical variations of cloud microphysics. Vertically, the mean values of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ qualitatively follow the adiabatic structure of MBL cloud; i.e., $q_{\mathrm{c}}$ increases linearly with height and $N_{\mathrm{c}}$ remains largely invariant above cloud base. Even though the joint distribution of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ exhibits a bimodality in several hlegs, their correlation generally increases with height and can be as high as $\mathit{\rho }=\mathrm{0.95}$ at cloud top. Horizontally, both $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ have a significant variability at cloud base, which tends to first decrease upward and then increase in the uppermost part of cloud close to the entrainment zone. Finally, we have to point out a couple of important caveats in the above analysis. First, as seen from Fig. 1 the selected hlegs are sampled at different vertical locations and also at different times. For example, hleg 5 at cloud base is more than 1 h apart from hleg 8 at cloud top (Fig. 1a). As a result, the temporal evolution of clouds is a confounding factor and might be misinterpreted as vertical variations of clouds. On the other hand, as shown below, we also observed similar vertical structure of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ in other cases. It seems highly unlikely that the temporal evaluations of the clouds in all selected cases conspire to confound our results in the same way. Based on this consideration, we assume that the temporal evolution of clouds is an uncertainty that could lead to random errors but does not impact the overall vertical trend. The second caveat is that due to the very limited vertical sampling rate of hlegs (i.e., only 3–4 samples), we cannot possibly resolve the detailed vertical variation of ${\mathit{\nu }}_q$, ${\mathit{\nu }}_N$, and $\mathit{\rho }$. Although we have used the word “trend” in the above analysis, it should be noted that the vertical profile of these parameters may, but more likely may not, be linear. So, the word “trend” here indicates only the large pattern that can be resolved by the hlegs. Obviously these two caveats also apply to the analysis below the EF, which is also derived from the hlegs.

As explained in the introduction, in GCMs the autoconversion process is usually parameterized as a highly nonlinear function of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$, e.g., the KK scheme in Eq. (1). In such a parameterization, an EF is needed to account for the bias caused by the nonlinearity effect. A variety of methods have been proposed and used in the previous studies to estimate the EF (Larson and Griffin, 2013; Lebsock et al., 2013; Pincus and Klein, 2000; Zhang et al., 2019). The methods used in this study are based on Z19. Only the most relevant aspects are recapped here. Readers are referred to Z19 for detail.

If the subgrid variations of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$, as well as their covariation, are known, then the EF can be estimated based on its definition as follows:

3$$E={\displaystyle \frac{{\int }_{N_{\mathrm{c},\min }}^{\mathrm{\infty }}{\int }_{q_{\mathrm{c},\min }}^{\mathrm{\infty }}{q}_{\mathrm{c}}^{{\mathit{\beta }}_q}{N}_{\mathrm{c}}^{{\mathit{\beta }}_N}P\left(q_{\mathrm{c}},N_{\mathrm{c}}\right)\mathrm{d}{q}_{\mathrm{c}}\mathrm{d}{N}_{\mathrm{c}}}{⟨q_{\mathrm{c}}{⟩}^{{\mathit{\beta }}_q}⟨N_{\mathrm{c}}{⟩}^{{\mathit{\beta }}_N}}},$$ where $⟨q_{\mathrm{c}}⟩$ and $⟨N_{\mathrm{c}}⟩$ are the grid-mean value, $P(q_{\mathrm{c}},N_{\mathrm{c}})$ is the joint probability density function (PDF) of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$. $q_{\mathrm{c},\min }$ and $N_{\mathrm{c},\min }$ are the lower limits of the in-cloud value (e.g., $q_{\mathrm{c},\min }=\mathrm{0.01}$ g m${}^{-\mathrm{3}}$). Some previous studies approximate the $P(q_{\mathrm{c}},N_{\mathrm{c}})$ as a bivariate lognormal distribution as follows: 4$$\begin{array}{rl}& P\left(q_{\mathrm{c}},N_{\mathrm{c}}\right)={\displaystyle \frac{\mathrm{1}}{\mathrm{2}\mathit{\pi }{q}_{\mathrm{c}}{N}_{\mathrm{c}}{\mathit{\sigma }}_{q_{\mathrm{c}}}{\mathit{\sigma }}_{N_{\mathrm{c}}}\sqrt{\mathrm{1}-{\mathit{\rho }}_{\mathrm{L}}^{\mathrm{2}}}}}\exp \left(-{\displaystyle \frac{\mathit{\zeta }}{\mathrm{2}}}\right)\\ & \mathit{\zeta }={\displaystyle \frac{\mathrm{1}}{\mathrm{1}-{\mathit{\rho }}_{\mathrm{L}}^{\mathrm{2}}}}\left[{\left({\displaystyle \frac{\ln q_{\mathrm{c}}-{\mathit{\mu }}_{q_{\mathrm{c}}}}{{\mathit{\sigma }}_{q_{\mathrm{c}}}}}\right)}^{\mathrm{2}}\right.\\ & -\mathrm{2}\mathit{\rho }\left({\displaystyle \frac{\ln q_{\mathrm{c}}-{\mathit{\mu }}_{q_{\mathrm{c}}}}{{\mathit{\sigma }}_{q_{\mathrm{c}}}}}\right)\left({\displaystyle \frac{\ln N_{\mathrm{c}}-{\mathit{\mu }}_{N_{\mathrm{c}}}}{{\mathit{\sigma }}_{N_{\mathrm{c}}}}}\right)\\ & \left.+{\left({\displaystyle \frac{\ln N_{\mathrm{c}}-{\mathit{\mu }}_{N_{\mathrm{c}}}}{{\mathit{\sigma }}_{N_{\mathrm{c}}}}}\right)}^{\mathrm{2}}\right],\end{array}$$ where ${\mathit{\mu }}_X$ and ${\mathit{\sigma }}_X$ are, respectively, the mean and standard deviation of $\ln \left(X\right)$, where $X$ is either $q_{\mathrm{c}}$ or $N_{\mathrm{c}}$. ${\mathit{\rho }}_{\mathrm{L}}$ is the linear correlation coefficient between $\ln \left(q_{\mathrm{c}}\right)$ and $\ln \left(N_{\mathrm{c}}\right)$ (Larson and Griffin, 2013; Lebsock et al., 2013; Zhang et al., 2019). It should be noted here that ${\mathit{\rho }}_{\mathrm{L}}$ is fundamentally different from $\mathit{\rho }$ (i.e., the linear correlation coefficient between $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$). On the other hand, we found that for all the selected hlegs, $\mathit{\rho }$ and ${\mathit{\rho }}_{\mathrm{L}}$ are in an excellent agreement (see Fig. 4d). In fact, $\mathit{\rho }$ and ${\mathit{\rho }}_{\mathrm{L}}$ can be used interchangeably in the context of this study without any impact on the conclusions. Nevertheless, interested readers may find more detailed discussion of the relationship between $\mathit{\rho }$ and ${\mathit{\rho }}_{\mathrm{L}}$ in Larson and Griffin (2013).

Substituting $P\left(q_{\mathrm{c}},N_{\mathrm{c}}\right)$ in Eq. (4) into Eq. (3) yields a formula for EF that consists of the following three terms: 5$$\begin{array}{rl}E& =E_q\left({\mathit{\nu }}_{q_{\mathrm{c}}},{\mathit{\beta }}_q\right)\cdot E_N\left({\mathit{\nu }}_{N_{\mathrm{c}}},{\mathit{\beta }}_N\right)\\ & \cdot E_{\mathrm{COV}}\left({\mathit{\rho }}_{\mathrm{L}},{\mathit{\beta }}_q,{\mathit{\beta }}_N{\mathit{\nu }}_{q_{\mathrm{c}}},{\mathit{\nu }}_{N_{\mathrm{c}}}\right),\end{array}$$ where $E_q\left({\mathit{\nu }}_{q_{\mathrm{c}}},{\mathit{\beta }}_q\right)$ corresponds to the enhancing effect of the subgrid variation of $q_{\mathrm{c}}$, if $q_{\mathrm{c}}$ follows a marginal lognormal distribution, i.e., $P\left(x\right)=\frac{\mathrm{1}}{\sqrt{\mathrm{2}\mathit{\pi }}x\mathit{\sigma }}\exp \left(-\frac{{\left(\ln x-\mathit{\mu }\right)}^{\mathrm{2}}}{\mathrm{2}{\mathit{\sigma }}^{\mathrm{2}}}\right)$. It is a function of the inverse relative variance ${\mathit{\nu }}_q$ in Eq. (2) as follows: 6$$E_q\left({\mathit{\nu }}_{q_{\mathrm{c}}},{\mathit{\beta }}_q\right)={\left(\mathrm{1}+{\displaystyle \frac{\mathrm{1}}{{\mathit{\nu }}_{q_{\mathrm{c}}}}}\right)}^{\frac{{\mathit{\beta }}_q^{\mathrm{2}}-{\mathit{\beta }}_q}{\mathrm{2}}}.$$ Similarly, the $E_N\left({\mathit{\nu }}_{N_{\mathrm{c}}},{\mathit{\beta }}_N\right)$ below corresponds to the enhancing effect of the subgrid variation of $N_{\mathrm{c}}$, if $N_{\mathrm{c}}$ follows a marginal lognormal distribution: 7$$E_N\left(v_{N_{\mathrm{c}}},{\mathit{\beta }}_N\right)={\left(\mathrm{1}+{\displaystyle \frac{\mathrm{1}}{{\mathit{\nu }}_{N_{\mathrm{c}}}}}\right)}^{\frac{{\mathit{\beta }}_N^{\mathrm{2}}-{\mathit{\beta }}_N}{\mathrm{2}}}.$$ The third term $E_{\mathrm{COV}}\left({\mathit{\rho }}_{\mathrm{L}},{\mathit{\beta }}_q,{\mathit{\beta }}_N{\mathit{\nu }}_{q_{\mathrm{c}}},{\mathit{\nu }}_{N_{\mathrm{c}}}\right)$ in Eq. (5), 8$$E_{\mathrm{COV}}\left({\mathit{\rho }}_{\mathrm{L}},{\mathit{\beta }}_q,{\mathit{\beta }}_N,v_{q_{\mathrm{c}}},v_{N_{\mathrm{c}}}\right)=\exp \left({\mathit{\rho }}_{\mathrm{L}}{\mathit{\beta }}_q{\mathit{\beta }}_N{\mathit{\sigma }}_{q_{\mathrm{c}}}{\mathit{\sigma }}_{N_{\mathrm{c}}}\right),$$ corresponds to the impact of the covariation of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ on the EF. Because ${\mathit{\beta }}_q>\mathrm{0}$ and ${\mathit{\beta }}_N<\mathrm{0}$, if $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ are negatively correlated (i.e., ${\mathit{\rho }}_{\mathrm{L}}<\mathrm{0}$), then the $E_{\mathrm{COV}}>\mathrm{1}$ and acts as an enhancing effect on the autoconversion rate computation. In contrast, if $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ are positively correlated (i.e., ${\mathit{\rho }}_{\mathrm{L}}>\mathrm{0}$), then the $E_{\mathrm{COV}}<\mathrm{1}$, which becomes a suppressing effect on the autoconversion rate computation.

As previously mentioned, most previous studies of the EF consider only the impact of subgrid $q_{\mathrm{c}}$ variation (i.e., only the $E_q$ term). The impacts of subgrid $N_{\mathrm{c}}$ variation as well as its covariation with $q_{\mathrm{c}}$ have been largely overlooked in observational studies, in which the $E_q$ is often derived from the observed subgrid variation of $q_{\mathrm{c}}$ based on the definition of EF, i.e., 9$$E_q={\displaystyle \frac{{\int }_{q_{\mathrm{c},\min }}^{\mathrm{\infty }}{q}_{\mathrm{c}}^{{\mathit{\beta }}_q}P\left(q_{\mathrm{c}}\right)\mathrm{d}{q}_{\mathrm{c}}}{⟨q_{\mathrm{c}}{⟩}^{{\mathit{\beta }}_q}}},$$ where $P\left(q_{\mathrm{c}}\right)$ is the observed subgrid PDF of $q_{\mathrm{c}}$. Alternatively, $E_q$ has also been estimated from the inverse relative variance ${\mathit{\nu }}_q$ by assuming the subgrid variation of $q_{\mathrm{c}}$ follows the lognormal distribution, in which case $E_q$ is given in Eq. (6).

Similar to $E_N$, if only the effect of subgrid $N_{\mathrm{c}}$ is considered, the corresponding $E_N$ can be derived from the following two ways: one from the observed subgrid PDF $P\left(N_{\mathrm{c}}\right)$ based on the definition of EF, i.e., 10$$E_N={\displaystyle \frac{{\int }_{N_{\mathrm{c},\min }}^{\mathrm{\infty }}{N}_{\mathrm{c}}^{{\mathit{\beta }}_N}P\left(N_{\mathrm{c}}\right)\mathrm{d}{N}_{\mathrm{c}}}{⟨N_{\mathrm{c}}{⟩}^{{\mathit{\beta }}_N}}},$$ and the other based on Eq. (7) from the relative variance ${\mathit{\nu }}_{N_{\mathrm{c}}}$ by assuming the subgrid $N_{\mathrm{c}}$ variation follows the lognormal distribution.

Now, we put the in situ $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ observations from the selected hlegs in the theoretical framework of EF described above and investigate the following questions:

• What is the (observation-based) EF derived based on Eq. (3) from the observed joint PDF $P(q_{\mathrm{c}},N_{\mathrm{c}})$?

• How well does the (bi-logarithmic) EF derived based on Eq. (5) by assuming that the covariation of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ follows a bivariate lognormal agree with the observation-based EF?

• What is the relative importance of the $E_q$, $E_N$, and $E_{\mathrm{COV}}$ terms in Eq. (5) in determining the value of EF?

• What is the error of considering only $E_q$ and omitting the $E_N$ and $E_{\mathrm{COV}}$ terms?

• How do the observation-based EFs from Eq. (3) and the $E_q$, $E_N$, and $E_{\mathrm{COV}}$ terms vary with vertical height in cloud?

These questions are addressed in the rest of this section. Focusing first on the $E_q$ in Fig. 6a, the $E_q$ derived from observation based on Eq. (9) (solid circle) shows a clear decreasing trend with height between cloud base at around 700 m to about 1 km, with a value reduced from about 3 to about 1.2. Then, the value of $E_q$ increases slightly in the cloud top hlegs 8 and 12. The $E_q$ derived based on Eq. (6) by assuming lognormal distribution (open circle) has a very similar vertical pattern, although the value is slightly overestimated on average by 0.07 in comparison to the observation-based result. The vertical pattern of $E_q$ can be readily explained by the subgrid variation of $q_{\mathrm{c}}$ in Fig. 4c. The $E_N$ derived from observation (solid triangle) in Fig. 6b shows a similar vertical pattern as $E_q$, i.e., first decreasing with height from cloud base to about 1.2 km and then increasing with height in the uppermost part of cloud. The $E_N$ derived based on Eq. (7) by assuming a lognormal distribution (open triangle) significantly underestimates the observation-based values (mean bias of $-$4.3), especially at cloud base (i.e., hleg 5 and 10) and cloud top (i.e., hleg 8 and 12).

Figure 6

(a) $E_q$ as a function of height derived from observation based on Eq. (9) (solid circle) and from the inverse relative variance ${\mathit{\nu }}_q$ assuming lognormal distribution based on Eq. (6) (open circle). (b) $E_N$ as a function of height derived from observation based on Eq. (10) (solid triangle) and from the inverse relative variance ${\mathit{\nu }}_N$ assuming lognormal distribution based on Eq. (7) (open triangle). (c) $E_{\mathrm{COV}}$ derived based on Eq. (8) as a function of height. (d) $E$ as a function of height derived from observation based on Eq. (3) (solid star) and based on Eq. (5) assuming a bi-lognormal distribution (open star). The numbers beside the symbols in the figure correspond to the numbers of the seven selected hlegs.

[Figure omitted. See PDF]

Figure 7

(a) Histogram of $\ln \left(q_{\mathrm{c}}\right)$ based on observations from hleg 10 (bars) and the lognormal PDF (dashed line) based on the ${\mathit{\mu }}_{q_{\mathrm{c}}}$ and ${\mathit{\sigma }}_{q_{\mathrm{c}}}$ of hleg 10. (b) The histogram of $\ln \left(E_q\right)$ diagnosed from the observed $q_{\mathrm{c}}$ based on Eq. (9). The two vertical lines correspond to the leg-averaged $\ln \left(E_q\right)$ derived based on the observed $q_{\mathrm{c}}$ (solid) and the lognormal PDF (dashed line), respectively. (c) Histogram of $\ln \left(N_{\mathrm{c}}\right)$ based on observations from hleg 10 (bars) and the lognormal PDF (dashed line) based on the ${\mathit{\mu }}_{N_{\mathrm{c}}}$ and ${\mathit{\sigma }}_{N_{\mathrm{c}}}$ of hleg 10. (d) The histogram of $\ln \left(E_N\right)$ diagnosed from the observed $q_{\mathrm{c}}$ based on Eq. (10). The two vertical lines correspond to the leg-averaged $\ln \left(E_N\right)$ derived based on the observed $N_{\mathrm{c}}$ (solid) and the lognormal PDF (dashed line), respectively.

[Figure omitted. See PDF]

Using hleg 10 as an example, we further investigated the cause for the error in lognormal-based EFs in comparison to those diagnosed from the observation. As shown in Fig. 7a the observed $q_{\mathrm{c}}$ is slightly negatively skewed in logarithmic space by the small values. Because the autoconversion rate is proportional to $q_{\mathrm{c}}^{\mathrm{2.47}}$, the negatively skewed $q_{\mathrm{c}}$ also leads to a negatively skewed $E_q$ in Fig. 7b. As a result, the leg-averaged $E_q$ diagnosed from the observation is slightly smaller than that derived based on Eq. (6) by assuming a lognormal distribution. The negative skewness also explains the large error in $E_N$ for hleg 10 seen on Fig. 6b. As shown in Fig. 7c the observed $N_{\mathrm{c}}$ is also negatively skewed to a much larger extent in comparison to $q_{\mathrm{c}}$. Because the autoconversion rate is proportional to $N_{\mathrm{c}}^{-\mathrm{1.79}}$, the highly negatively skewed $N_{\mathrm{c}}$ results in a highly positively skewed $E_N$ in Fig. 7d. As a result, the $E_N$ diagnosed from the observation is much larger than that derived based on Eq. (7) by assuming a lognormal distribution.

The $E_q$ and $E_N$ reflect only the individual contributions of subgrid $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ variations to the EF. The effect of the covariation of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$, i.e., the $E_{\mathrm{COV}}$, is shown in Fig. 6c. Interestingly, the value of $E_{\mathrm{COV}}$ is smaller than unity for all the selected hlegs. As explained in Eq. (8), $E_{\mathrm{COV}}<\mathrm{1}$ is a result of a positive correlation between $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$, as seen in Fig. 4d. Therefore, in these hlegs the covariation of the $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ has a suppressing effect on the EF, in contrast to the enhancing effect of $E_q$ and $E_N$. This result is qualitatively consistent with Z19, who found that the vertically integrated liquid water path (LWP) of MBL clouds is in general positively correlated with the $N_{\mathrm{c}}$ estimated from the MODIS cloud retrieval product and, as a result, $E_{\mathrm{COV}}<\mathrm{1}$ over most of the tropical oceans. Because of the relationship in Eq. (8), the value $E_{\mathrm{COV}}$ is evidently negatively proportional to the correlation coefficient ${\mathit{\rho }}_{\mathrm{L}}$ in Fig. 4d. The largest value is seen in hleg 6 and 7, in which the bimodal joint distribution of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ results in a small ${\mathit{\rho }}_{\mathrm{L}}$. A rather small value of $E_{\mathrm{COV}}\sim \mathrm{0.45}$ is seen for cloud top hleg 8 and 12, as result of a strong correlation between $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ (${\mathit{\rho }}_{\mathrm{L}}>\mathrm{0.9}$) and moderate ${\mathit{\sigma }}_q$ and ${\mathit{\sigma }}_N$.

Finally, the EF that accounts for all factors, including the individual variations of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$, as well as their covariation, is shown in Fig. 6d. Focusing first on the observation-based results (solid star), i.e., $E$ in Eq. (3), evidently there is a decreasing trend from cloud base (e.g., $E=\mathrm{2.2}$ for hleg 5 and $E=\mathrm{1.59}$ for hleg 10) to cloud top (e.g., $E=\mathrm{1.20}$ for hleg 8 and $E=\mathrm{1.02}$ for hleg 12). The $E$ values derived based on Eq. (5) by assuming the bivariate lognormal distribution between $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ (i.e., open star in Fig. 6d) are in reasonable agreement with the observation-based results, with a mean bias of $-$0.09. It is intriguing to note that the value of $E=E_q\cdot E_N\cdot E_{\mathrm{COV}}$ in Fig. 6d is comparable to $E_q$ in Fig. 6a, which indicates that the enhancing effect of $E_N>\mathrm{1}$ in Fig. 6b is partially canceled by the suppressing effect of $E_{\mathrm{COV}}<\mathrm{1}$ in Fig. 6c. As previously mentioned, many previous studies of the EF consider only the effect of $E_q$ but overlook the effect of $E_N$ and $E_{\mathrm{COV}}$. The error in the studies would be quite large if it were not for a fortunate error cancellation.

In addition to the 18 July 2017 RF, we also found another six RFs that meet our criteria as described in Sect. 3 for case selection, from non-precipitating (e.g., 13 July 2017 case in Fig. S1) to weakly (e.g., 26 January 2018 case in Fig. S4) and heavily precipitating cloud (11 February 2018 case in Fig. S6). Due to limited space, we cannot present the detailed case studies of these RFs. Instead, we view them collectively and investigate whether the lessons learned from the 18 July 2017 RF, especially those about the EF in Sect. 4.2, also apply to the other cases.

In order to compare the hlegs from different RFs, we first normalize the altitude of each hleg with respect to the minimum and maximum values of all selected hlegs in each RF as follows:

11$$z_{\mathrm{hleg}}^{\ast }={\displaystyle \frac{z_{\mathrm{hleg}}-z_{min}}{z_{max}-z_{min}}},$$ where $z_{\mathrm{hleg}}^{\ast }$ is the normalized altitude for each hleg in a RF, and $z_{min}$ and $z_{max}$ are the altitude of the lowest and highest hleg in the corresponding RF. Defined this way, $z_{\mathrm{hleg}}^{\ast }$ is bounded between 0 and 1. Alternatively, $z_{\mathrm{hleg}}^{\ast }$ could also be defined with respect to the averaged cloud top ($z_{\mathrm{top}}$) and base ($z_{\mathrm{base}}$) as inferred from the KAZR or vlegs. However, because of the variation of cloud top and cloud base heights, as well as the collocation error, the $z_{\mathrm{hleg}}^{\ast }$ would often become significantly larger than 1 or smaller than 0, if $z_{\mathrm{hleg}}^{\ast }$ were defined with respect to $z_{\mathrm{top}}$ and $z_{\mathrm{base}}$, making results confusing and difficult to interpret.

Figure 8

(a) The observation-based $E$ derived from Eq. (3) that accounts for the covariation of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$. (b) The observation-based $E_q$ derived from Eq. (9) that accounts for only the subgrid variation of $q_{\mathrm{c}}$. (c) The observation-based $E_N$ derived from Eq. (10) that accounts for only the subgrid variation of $N_{\mathrm{c}}$. (d) The correlation coefficient between $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$. All quantities are plotted as a function of the normalized height $z_{\mathrm{hleg}}^{\ast }$ in Eq. (11). The dashed lines correspond to a linear fit of the data when the fitting is statistically significant (i.e., $P$ value $<$ 0.05).

[Figure omitted. See PDF]

Figure 8 shows the observation-based EFs for all the selected hlegs from the seven selected RFs as a function of the $z_{\mathrm{hleg}}^{\ast }$. As shown in Fig. 8a, the $E$ derived based on Eq. (3) that accounts for the covariation of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ has a decreasing trend from cloud base to cloud top. This is consistent with the result from the 18 July 2017 case in Fig. 6d. However, neither the $E_q$ in Fig. 8b nor the $E_N$ in Fig. 8c shows a clear dependence on $z_{\mathrm{hleg}}^{\ast }$ in comparison to the results of the 18 July 2017 case in Fig. 6a and b. Note that the $E_q$ and $E_N$ are influenced by a number of factors, such as horizontal distance and cloud fraction, in addition to vertical height. It is possible that the differences in other factors outweigh the vertical dependence here. Interestingly, the linear correlation coefficient $\mathit{\rho }$ between $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ in Fig. 8d shows an increasing trend with $z_{\mathrm{hleg}}^{\ast }$ that is statistically significant ($R$ value $=\mathrm{0.50}$ and $P$ value $=$ 0.02), despite a few outliers. This is consistent with what we found in the 18 July 2017 case (see Fig. 4d). As evident from Eq. (8), an increase in ${\mathit{\rho }}_{\mathrm{L}}$ would lead to a decrease in $E_{\mathrm{COV}}$. Since neither $E_q$ nor $E_N$ shows a clear dependence on $z_{\mathrm{hleg}}^{\ast }$, the decrease in $E_{\mathrm{COV}}$ with $z_{\mathrm{hleg}}^{\ast }$ seems to play an important role in the determining the value of $E$. Another line of evidence supporting this role is the fact that both $E_q$ and $E_N$ are quite large for the cloud top hlegs, while in contrast the values of the corresponding $E$ that accounts for the covariation of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ are much smaller. For example, the $E_q$ for two hlegs from the 11 February 2018 RF exceeds 8, but the corresponding $E$ values are smaller than 1.2, which is evidently a result of large ${\mathit{\rho }}_{\mathrm{L}}$ and thereby small $E_{\mathrm{COV}}$.

As previously mentioned, many previous studies of the EF for the autoconversion rate parameterization consider only the effect of subgrid $q_{\mathrm{c}}$ variation but ignore the effects of subgrid $N_{\mathrm{c}}$ variation and its covariation with $q_{\mathrm{c}}$. To understand the potential error, we compared the $E_q$ and $E$ both derived based on observations in Fig. 9. Apparently, $E_q$ is significantly larger than $E$ for most of the selected hlegs, which implies that considering only subgrid $q_{\mathrm{c}}$ variation would likely lead to an overestimation of EF. This is an interesting result. Note that $E_N\ge \mathrm{1}$ by definition and therefore $E_q>E$ is possible only when the covariation of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ has a suppressing effect, instead of enhancing. Once again, this result demonstrates the importance of understanding the covariation of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ for understanding the EF for autoconversion rate parameterization.

Figure 9

A comparison of observation-based $E$ and observation-based $E_q$ for all the selected hlegs from all four selected RFs.

[Figure omitted. See PDF]

Figure 10

(a) A comparison of observation-based $E_q$ derived based on Eq. (9) and $E_q$ derived based on Eq. (6) assuming lognormal distribution for subgrid $q_{\mathrm{c}}$ observations for all the selected hlegs. (b) A comparison of observation-based $E_N$ derived based on Eq. (10) and $E_N$ derived based on Eq. (7) assuming lognormal distribution or all the selected hlegs. (c) A comparison of observation-based $E$ derived based on Eq. (3) and $E$ derived based on Eq. (5) assuming bivariate lognormal distribution for the subgrid joint distribution of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$.

[Figure omitted. See PDF]

Having looked at the observation-based EFs, we now check if the EFs derived based on assumed PDFs (e.g., lognormal or bivariate lognormal distributions) agree with the observation-based results. As shown in Fig. 10a, the $E_q$ based on Eq. (6) that assumes a lognormal distribution for the subgrid variation of $q_{\mathrm{c}}$ is in an excellent agreement with the observation-based results. In contrast, the comparison is much worse for the $E_N$ in Fig. 10b, which is not surprising given the results from the 18 July 2017 case in Fig. 6b. As one can see from Fig. 5, the marginal PDF of $N_{\mathrm{c}}$ is often broad and sometimes even bimodal. The deviation of the observed $N_{\mathrm{c}}$ PDF from the lognormal distribution is probably the reason for the large difference of $E_N$ in Fig. 10b. As shown in Fig. 10c, the $E$ values derived based on Eq. (5) by assuming a bivariate lognormal function for the joint distribution of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ are in good agreement with observation-based values, which is consistent with the results from the 18 July 2017 case in Fig. 6.

In this study we derived the horizontal variations of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$, as well as their covariations in MBL clouds based on the in situ measurements from the recent ACE-ENA campaign, and investigated the implications of subgrid variability as it relates to the enhancement of autoconversion rates. The main findings can be summarized as follows:

• In the 18 July 2017 case, the vertical variation of the mean values of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ roughly follows the adiabatic structure. The horizontal variances of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ first decrease from cloud base upward toward the middle of the cloud and then increase near cloud top. The correlation between of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ generally increases from cloud base to cloud top.

• In other selected cases, the horizontal variances of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ show no statistically significant dependence on the vertical height in cloud. However, the increasing trend of the correlation between $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ from cloud base to cloud top remains robust.

• In a few selected V-shaped hlegs, the $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ follow a bimodal joint distribution which leads to a weak linear correlation between them.

• The observation-based physically complete $E$ that accounts for the covariation of $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ has a robust decreasing trend from cloud base to cloud top, which can be explained by the increasing trend of the $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ correlation from cloud base to cloud top.

• The $E$ estimated by assuming a monomodal bivariate lognormal joint distribution between $q_{\mathrm{c}}$ and $N_{\mathrm{c}}$ agrees well with the observation-based results.

Our study has a few important limitations. First of all, our results are based on a handful cases from a single field campaign. The lessons learned here need to be further examined based on more data or tested in modeling studies. Second, as pointed out in Sect. 4.1, due to the inherent sampling limitation of airborne measurements, the temporal evolution of clouds is an important uncertainty and a confounding factor in this study, which needs to be quantified in future studies. Third, our study provides only a phenomenological analysis of the horizontal variations of cloud microphysics in the MBL clouds and the implications for the EF. Ongoing modeling research based on a comprehensive LES model is being conducted to identify and elucidate the process-level physical mechanisms behind our observational results. Finally, this study is focused on the KK parameterization in estimating the enhancement factors resulting from subgrid variability of $q_{\mathrm{c}}$, $N_{\mathrm{c}}$, and $q_{\mathrm{c}}$–$N_{\mathrm{c}}$ covariance. The specific values are expected to differ when applied to other autoconversion parameterizations with different power-law exponents.