Introduction

The growth of cloud droplets is dominated by two processes: condensation and collection. Condensation of water vapor on active cloud condensation nuclei is important in the size range from the activation size of aerosol particles to about a radius of $\mathrm{10}$ $\mathrm{\mu }$m . Since the rate of droplet growth by condensation is inversely proportional to the droplet radius, large droplets grow slower than smaller ones. This generates narrower size distributions . To form rain droplets in warm clouds, small droplets must grow to about $\mathrm{50}$ $\mathrm{\mu }$m in radius within 15–20 min . Therefore, collection, a widely accepted microscopical mechanism, has been proposed to explain the rapid formation of rain droplets . However, collection can only become active when the size distribution reaches a certain width.

observed a broadening of the droplet size distribution in Californian marine stratus, which was contrary to the classical theory of condensational growth . The increasing width of droplet size distributions was further observed by and . The contradiction between the observed broadening width and the theoretical narrowing width in the absence of turbulence has stimulated several studies. The classical treatment of diffusion-limited growth assumes that supersaturation depends only on average temperature and water mixing ratio. Since fluctuations of temperature and the water mixing ratio are affected by turbulence, the supersaturation fluctuations are inevitably subjected to turbulence. Naturally, condensational growth due to supersaturation fluctuations became the focus . The supersaturation fluctuations are particularly important for understanding the condensational growth of cloud droplets in stratiform clouds, where the updraft velocity of the parcel is almost zero . When the mean updraft velocity is not zero, there could be a competition between mean updraft velocity and supersaturation fluctuations. This may diminish the role of supersaturation fluctuations .

Condensational growth due to supersaturation fluctuations was first recognized by , who criticized the use of a volume-averaged supersaturation and proposed a randomly distributed supersaturation field. proposed that droplets moving in clouds are exposed to a varying supersaturation field. This results in a broadening of the droplet size distribution due to supersaturation fluctuations. called the mechanism of the eddy-hopping mechanism, which was then investigated by . Using direct numerical simulations (DNS), found that the mean energy dissipation rate of turbulence has a negligible effect on condensational growth and attributed this to the decorrelation between the supersaturation and the droplet size. considered three-dimensional (3-D) turbulence as well as stochastically forced temperature and vapor fields with a focus on statistical modeling for large-eddy simulations. They found that supersaturation fluctuations due to turbulence mixing are responsible for the broadening of the droplet size distribution. conducted 3-D DNS for condensational growth by only solving a passive scalar equation for the supersaturation and concluded that the width of the size distribution increases with increasing Reynolds number. extended the DNS of to a higher Reynolds number and found that the variance of the size distribution increases in time. In a similar manner as , modeled the supersaturation field as a passive scalar coupled to the Lagrangian particles and found that their results can be reconciled with those of earlier numerical studies by noting that the droplet size distribution broadens with increasing Reynolds number . Neither nor solved the thermodynamics that determine the supersaturation field. Both and solved the thermodynamics equations governing the supersaturation field. However, since collection was also included in their work, one cannot clearly identify the roles of turbulence on collection or condensational growth, nor can one compare their results with Lagrangian stochastic models related to condensational growth.

Recent laboratory experiments and observations about cloud microphysics also confirm the notion that supersaturation fluctuations may play an important role in broadening the size distribution of cloud droplets. The laboratory studies of and suggested that supersaturation fluctuations in the low aerosol number concentration limit are likely of leading importance for the onset of precipitation. The condensational growth due to supersaturation fluctuations seems to be more sensitive to the integral scale of turbulence . measured the variability of temperature, water vapor mixing ratio, and supersaturation in warm clouds and support the notion that both aerosol particle activation and droplet growth take place in the presence of a broad distribution of supersaturation . The challenge is now how to interpret the observed broadening of the droplet size distribution in warm clouds. How does turbulence drive fluctuations of the scalar fields (temperature and water vapor mixing ratio) and therefore affect the broadening of droplet size distributions ?

In an attempt to answer this question, we conduct 3-D DNS experiments of condensational growth of cloud droplets, where turbulence, thermodynamics, feedback from droplets to the fields via the condensation rate, and buoyancy force are all included. The main aim is to investigate how supersaturation fluctuations affect the droplet size distribution. We particularly focus on the time evolution of the size distribution $f(r,t)$ and its dependency on small and large scales of turbulence. We then compare our simulation results with Lagrangian stochastic models . For the first time, the stochastic model and simulation results from the complete set of equations governing the supersaturation field are compared.

Numerical model

We now discuss the basic equations where we combine the Eulerian description of the density ($\mathit{\rho }$), turbulent velocity ($\mathit{u}$), temperature ($T$), and water vapor mixing ratio ($q_{\mathrm{v}}$) with the Lagrangian description of the ensemble of cloud droplets. The water vapor mixing ratio $q_{\mathrm{v}}$ is defined as the ratio between the mass density of water vapor and dry air. Droplets are treated as superparticles. A superparticle represents an ensemble of droplets, whose mass, radius, and velocity are the same as those of each individual droplet within it . For condensational growth, the superparticle approach is the same as the Lagrangian point-particle approach since there is no interaction among droplets. Nevertheless, we still use the superparticle approach so that we can include more processes like collection in the future. Another reason to adopt the superparticle approach is that it can be easily adapted to conduct large-eddy simulations with appropriate sub-grid-scale models . To investigate the condensational growth of cloud droplets that experience fluctuating supersaturation, we track each individual superparticle in a Lagrangian manner. The motion of each superparticle is governed by the momentum equation for inertial particles. The supersaturation field in the simulation domain is determined by $T(\mathit{x},t)$ and $q_{\mathrm{v}}(\mathit{x},t)$ transported by turbulence. Lagrangian droplets are exposed in different supersaturation fields. Therefore, droplets either grow by condensation or shrink by evaporation depending on the local supersaturation field. This phase transition generates a buoyancy force, which in turn affects the turbulent kinetic energy, $T(\mathit{x},t)$, and $q_{\mathrm{v}}(\mathit{x},t)$. Pencil Code () is used to conduct all the simulations.

Equations of motion for Eulerian fields

The background airflow is almost incompressible and thus obeys the Boussinesq approximation. Its density $\mathit{\rho }(\mathit{x},t)$ is governed by the continuity equation and velocity $\mathit{u}(\mathit{x},t)$ by the Navier–Stokes equation. The temperature $T(\mathit{x},t)$ of the background airflow is determined by the energy equation with a source term due to the latent heat release. The water vapor mixing ratio $q_{\mathrm{v}}(\mathit{x},t)$ is transported by the background airflow. The Eulerian equations are given by $$\begin{array}{}& {\displaystyle }& {\displaystyle \frac{\partial \mathit{\rho }}{\partial t}}+\mathbf{\nabla }\cdot \left(\mathit{\rho }\mathit{u}\right)=S_{\mathit{\rho }},& {\displaystyle }& {\displaystyle \frac{D\mathit{u}}{Dt}}=\mathit{f}-{\mathit{\rho }}^{-\mathrm{1}}\mathbf{\nabla }p+{\mathit{\rho }}^{-\mathrm{1}}\mathbf{\nabla }\cdot \left(\mathrm{2}\mathit{\nu }\mathit{\rho }\mathbf{S}\right)+B{\mathit{e}}_z+{\mathit{S}}_u,& {\displaystyle }& {\displaystyle \frac{DT}{Dt}}=\mathit{\kappa }{\mathrm{\nabla }}^{\mathrm{2}}T+{\displaystyle \frac{L}{c_p}}{C}_d,& {\displaystyle }& {\displaystyle \frac{D{q}_{\mathrm{v}}}{Dt}}=D{\mathrm{\nabla }}^{\mathrm{2}}{q}_{\mathrm{v}}-C_d,\end{array}$$ where $D/Dt=\partial /\partial t+\mathit{u}\cdot \mathbf{\nabla }$ is the material derivative, $\mathit{f}$ is a random forcing function , $\mathit{\nu }$ is the kinematic viscosity of air, ${\mathbf{S}}_{ij}=\mathrm{1}/\mathrm{2}({\partial }_j{u}_i+{\partial }_i{u}_j)-\mathrm{1}/\mathrm{3}{\mathit{\delta }}_{ij}\left({\partial }_k{u}_k\right)$ is the traceless rate-of-strain tensor, $p$ is the gas pressure, $\mathit{\rho }$ is the gas density, $c_{\mathrm{p}}$ is the specific heat at constant pressure, $L$ is the latent heat, $\mathit{\kappa }$ is the thermal diffusivity of air, $C_d$ is the condensation rate, $B$ is the buoyancy, $e_z$ is the unit vector in the $z$ direction (vertical direction), and $D$ is the diffusivity of water vapor. To avoid global transpose operations associated with calculating Fourier transforms for solving the nonlocal equation for the pressure in strictly incompressible calculations, we solve here instead the compressible Navier–Stokes equations using high-order finite differences. The sound speed $c_{\mathrm{s}}$ obeys $c_{\mathrm{s}}^{\mathrm{2}}=\mathit{\gamma }p/\mathit{\rho }$, where $\mathit{\gamma }=c_{\mathrm{p}}/c_{\mathrm{v}}=\mathrm{7}/\mathrm{5}$ is the ratio between specific heats, $c_{\mathrm{p}}$ and $c_{\mathrm{v}}$, at constant pressure and constant volume, respectively. We set the sound speed as 5 m s${}^{-\mathrm{1}}$ to simulate the nearly incompressible atmospheric airflow, resulting in a Mach number of $\mathrm{0.06}$ when $u_{\mathrm{rms}}=\mathrm{0.27}$ m s${}^{-\mathrm{1}}$, where $u_{\mathrm{rms}}$ is the rms velocity. Such a configuration, with such a small Mach number, is almost equivalent to an incompressible flow. It is worth noting that the temperature determining the compressibility of the flow is constant and independent of the temperature field of the gas flow governed by Eq. (). Also, since the gas flow is almost incompressible and its mass density is much smaller than the one of the droplet, there is no mass exchange between the gas flow and the droplet; i.e., the density of the gas flow $\mathit{\rho }(\mathit{x},t)$ is not affected by $T(\mathit{x},t)$. Thus, the source terms $S_{\mathit{\rho }}$ and ${\mathit{S}}_u$ in Eqs. () and () are neglected . The buoyancy $B(\mathit{x},t)$ depends on the temperature $T(\mathit{x},t)$, water vapor mixing ratio $q_{\mathrm{v}}(\mathit{x},t)$, and the liquid mixing ratio $q_{\mathrm{l}}$ , $$B(\mathit{x},t)=g(T^{\prime }/T+\mathit{\alpha }{q}_{\mathrm{v}}^{\prime }-q_{\mathrm{l}}),$$ where $\mathit{\alpha }=M_{\mathrm{a}}/M_{\mathrm{v}}-\mathrm{1}\approx \mathrm{0.608}$ when $M_{\mathrm{a}}$ and $M_{\mathrm{v}}$ are the molar masses of air and water vapor, respectively. The amplitude of the gravitational acceleration is given by $g$. The liquid water mixing ratio is the ratio between the mass density of liquid water and the dry air and is defined as $$q_{\mathrm{l}}\left(\mathit{x},t\right)={\displaystyle \frac{\mathrm{4}\mathit{\pi }{\mathit{\rho }}_{\mathrm{l}}}{\mathrm{3}{\mathit{\rho }}_{\mathrm{a}}(\mathrm{\Delta }x{)}^{\mathrm{3}}}}\sum _{j=\mathrm{1}}^{N_{\mathrm{△}}}r{\left(t\right)}^{\mathrm{3}}={\displaystyle \frac{\mathrm{4}\mathit{\pi }{\mathit{\rho }}_{\mathrm{l}}}{\mathrm{3}{\mathit{\rho }}_{\mathrm{a}}}}\sum _{j=\mathrm{1}}^{N_{\mathrm{△}}}f(r,t)r{\left(t\right)}^{\mathrm{3}}\mathit{\delta }r,$$ where ${\mathit{\rho }}_{\mathrm{l}}$ and ${\mathit{\rho }}_{\mathrm{a}}$ are the liquid water density and the reference mass density of dry air. $N_{\mathrm{△}}$ is the total number of droplets in a cubic grid cell with volume $(\mathrm{\Delta }x{)}^{\mathrm{3}}$, where $\mathrm{\Delta }x$ is the one-dimensional size of the grid box. The temperature fluctuations are given by $$T^{\prime }\left(\mathit{x},t\right)=T\left(\mathit{x},t\right)-T_{\mathrm{env}}$$ and the water vapor mixing ratio fluctuations by $$q_{\mathrm{v}}^{\prime }\left(\mathit{x},t\right)=q_{\mathrm{v}}\left(\mathit{x},t\right)-q_{v,\mathrm{env}}.$$ We adopt the same method as in , where the mean environmental temperature $T_{\mathrm{env}}$ and water vapor mixing ratio $q_{v,\mathrm{env}}$ do not change in time. This assumption is plausible in the circumstance that we do not consider the entrainment; i.e., there is only mass and energy transfer between liquid water and water vapor. The condensation rate $C_d$ is given by $$\begin{array}{cc}{\displaystyle }{C}_d\left(\mathit{x},t\right)& {\displaystyle }={\displaystyle \frac{\mathrm{4}\mathit{\pi }{\mathit{\rho }}_{\mathrm{l}}G}{{\mathit{\rho }}_{\mathrm{a}}(\mathrm{\Delta }x{)}^{\mathrm{3}}}}\sum _{j=\mathrm{1}}^{N_{\mathrm{△}}}s\left(\mathit{x},t\right)r\left(t\right)\\ & {\displaystyle }& {\displaystyle }={\displaystyle \frac{\mathrm{4}\mathit{\pi }{\mathit{\rho }}_{\mathrm{l}}G}{{\mathit{\rho }}_{\mathrm{a}}}}\sum _{j=\mathrm{1}}^{N_{\mathrm{△}}}s\left(\mathit{x},t\right)f(\mathit{x},t)r\left(t\right)\mathit{\delta }r,\end{array}$$ where $G$ is the condensation parameter (in units of ${\mathrm{m}}^{\mathrm{2}}{\mathrm{s}}^{-\mathrm{1}}$), which depends weakly on temperature and pressure and is here assumed to be constant . The supersaturation $s$ is defined as the ratio between the vapor pressure $e_{\mathrm{v}}$ and the saturation vapor pressure $e_{\mathrm{s}}$, $$s={\displaystyle \frac{e_{\mathrm{v}}}{e_{\mathrm{s}}}}-\mathrm{1}.$$ Using the ideal gas law, Eq. () can be expressed as $$s={\displaystyle \frac{{\mathit{\rho }}_{\mathrm{v}}{R}_{\mathrm{v}}T}{{\mathit{\rho }}_{\mathrm{vs}}{R}_{\mathrm{v}}T}}-\mathrm{1}={\displaystyle \frac{{\mathit{\rho }}_{\mathrm{v}}}{{\mathit{\rho }}_{\mathrm{vs}}}}-\mathrm{1}.$$ In terms of the water vapor mixing ratio $q_{\mathrm{v}}={\mathit{\rho }}_{\mathrm{v}}/{\mathit{\rho }}_{\mathrm{a}}$ and saturation water vapor mixing ratio $q_{\mathrm{vs}}={\mathit{\rho }}_{\mathrm{vs}}/{\mathit{\rho }}_{\mathrm{a}}$, Eq. () can be written as $$s\left(\mathit{x},t\right)={\displaystyle \frac{q_{\mathrm{v}}\left(\mathit{x},t\right)}{q_{\mathrm{vs}}\left(T\right)}}-\mathrm{1}.$$ Here ${\mathit{\rho }}_{\mathrm{v}}$ is the mass density of water vapor and ${\mathit{\rho }}_{\mathrm{vs}}$ the mass density of saturated water vapor, and $q_{\mathrm{vs}}\left(T\right)$ is the saturation water vapor mixing ratio at temperature $T$ and can be determined by the ideal gas law, $$q_{\mathrm{vs}}\left(T\right)={\displaystyle \frac{e_{\mathrm{s}}\left(T\right)}{R_{\mathrm{v}}{\mathit{\rho }}_{\mathrm{a}}T}}.$$ The saturation vapor pressure $e_{\mathrm{s}}$ over liquid water is the partial pressure due to the water vapor when an equilibrium state of evaporation and condensation is reached for a given temperature. It can be determined by the Clausius–Clapeyron equation, which determines the change in $e_{\mathrm{s}}$ with temperature $T$. Assuming constant latent heat $L$, $e_{\mathrm{s}}$ is approximated as $$e_{\mathrm{s}}\left(T\right)=c_{\mathrm{1}}\exp (-c_{\mathrm{2}}/T),$$ where $c_{\mathrm{1}}$ and $c_{\mathrm{2}}$ are constants adopted from page 14 of . We refer to Table  for all the thermodynamics constants. In the present study, the updraft cooling is omitted. Therefore, the assumption of constant latent heat $L$ is plausible.

List of constants for the thermodynamics: see text for explanations of symbols.

Lagrangian model for cloud droplets

In addition to the Eulerian fields described in Sect.  we treat cloud droplets as Lagrangian particles. In the Pencil Code, they are invoked as non-interacting superparticles.

Kinetics of cloud droplets

Each superparticle is treated as a Lagrangian point particle, where one solves for the particle position ${\mathit{x}}_i$, $${\displaystyle \frac{\mathrm{d}{\mathit{x}}_i}{\mathrm{d}t}}={\mathit{V}}_i,$$ and its velocity ${\mathit{V}}_i$ via $${\displaystyle \frac{\mathrm{d}{\mathit{V}}_i}{\mathrm{d}t}}={\displaystyle \frac{\mathrm{1}}{{\mathit{\tau }}_i}}(\mathit{u}-{\mathit{V}}_i)+g{\mathit{e}}_z$$ in the usual way; see for details. Here, $\mathit{u}$ is the fluid velocity at the position of the superparticle, and ${\mathit{\tau }}_i$ is the particle inertial response or stopping time of a droplet $i$ and is given by $${\mathit{\tau }}_i=\mathrm{2}{\mathit{\rho }}_{\mathrm{l}}{r}_i^{\mathrm{2}}/\left[\mathrm{9}\mathit{\rho }\mathit{\nu }D\right({\mathit{Re}}_i\left)\right].$$ The correction factor , $$D\left({\mathit{Re}}_i\right)=\mathrm{1}+\mathrm{0.15}{\mathit{Re}}_i^{\mathrm{2}/\mathrm{3}},$$ models the effect of the nonzero particle Reynolds number ${\mathit{Re}}_i=\mathrm{2}{r}_i|\mathit{u}-{\mathit{V}}_i|/\mathit{\nu }$. This is a widely used approximation, although it does not correctly reproduce the small-${\mathit{Re}}_i$ correction to the Stokes formula .

Condensational growth of cloud droplets

The condensational growth of the particle radius $r_i$ is governed by $${\displaystyle \frac{\mathrm{d}{r}_i}{\mathrm{d}t}}={\displaystyle \frac{\mathrm{Gs}\left({\mathit{x}}_i,t\right)}{r_i}}.$$

Experimental setup

Initial configurations

The initial values of the water vapor mixing ratio $q_{\mathrm{v}}(\mathit{x},t=\mathrm{0})=\mathrm{0.0157}$ kg kg${}^{-\mathrm{1}}$ and temperature $T(\mathit{x},t=\mathrm{0})=\mathrm{292}\mathrm{K}$ are matched to the ones obtained in the CARRIBA experiments , which are the same as those in . With this configuration, we obtain $s(\mathit{x},t=\mathrm{0})=\mathrm{2}$ %, which means that the water vapor is initially supersaturated. The time step of the simulations presented here is governed by the smallest timescale in the present configuration, which is the particle stopping time defined in Eq. (). The thermodynamic timescale is much larger than the turbulent one. Table  shows the list of thermodynamic parameters used in the present study.

Initially, 10 $\mathrm{\mu }$m sized droplets with zero velocity are randomly distributed in the simulation domain. The mean number density of droplets, which is constant in time since droplet collections are not considered, is $n_{\mathrm{0}}=\mathrm{2.5}\times {\mathrm{10}}^{\mathrm{8}}$ m${}^{-\mathrm{3}}$. This gives an initial liquid water content, ${\int }_{\mathrm{0}}^{\mathrm{\infty }}f(r,t=\mathrm{0})r^{\mathrm{3}}\mathrm{d}r$, which is $\mathrm{0.001}$ kg m${}^{-\mathrm{3}}$. The simulation domain is a cube of size $L_x=L_y=L_z$, the values of which are given in Table . The number of superparticles $N_{\mathrm{s}}$ satisfies $N_{\mathrm{s}}/N_{\mathrm{grid}}\approx \mathrm{0.1}$, where $N_{\mathrm{grid}}$ is the number of lattices depending on the spatial resolution of the simulations. Setting $N_{\mathrm{s}}/N_{\mathrm{grid}}\approx \mathrm{0.1}$, on the one hand, is still within the convergence range $N_{\mathrm{s}}/N_{\mathrm{grid}}\approx \mathrm{0.05}$ . On the other hand, it can mimic the diluteness of the atmospheric cloud system, where there are about 0.1 droplets per cubic Kolmogorov scale. This configuration results in $N_{\mathrm{s},\mathrm{128}}=\mathrm{244}\mathrm{140}$ when $N_{\mathrm{grid}}={\mathrm{128}}^{\mathrm{3}}$.

Summary of the simulations; see text for explanation of symbols.

DNS

We conduct high-resolution simulations () for the different Taylor micro-scale Reynolds number ${\mathit{Re}}_{\mathit{\lambda }}$ and mean energy dissipation rate $\stackrel{\mathrm{‾}}{\mathit{ϵ}}$ (see Table  for details of the simulations). The Taylor micro-scale Reynolds number is defined as ${\mathit{Re}}_{\mathit{\lambda }}\equiv u_{\mathrm{rms}}^{\mathrm{2}}\sqrt{\mathrm{5}/\left(\mathrm{3}\mathit{\nu }\stackrel{\mathrm{‾}}{\mathit{ϵ}}\right)}$. For simulations with different values of $\stackrel{\mathrm{‾}}{\mathit{ϵ}}$ at fixed ${\mathit{Re}}_{\mathit{\lambda }}$, we vary both the domain size $L_x$ ($L_y=L_z=L_x$) and the amplitude of the forcing $f_{\mathrm{0}}$. As for fixed $\stackrel{\mathrm{‾}}{\mathit{ϵ}}$, ${\mathit{Re}}_{\mathit{\lambda }}$ is varied by solely changing the domain size, which in turn changes $u_{\mathrm{rms}}$. In all simulations, we use for the Prandtl number $\mathit{Pr}=\mathit{\nu }/\mathit{\kappa }=\mathrm{1}$ and for the Schmidt number $\mathit{Sc}=\mathit{\nu }/D=\mathrm{0.6}$. For our simulations with $N_{\mathrm{grid}}={\mathrm{512}}^{\mathrm{3}}$ mesh points, the code computes 55 000 time steps in 24 h wall-clock time using 4096 cores. For $N_{\mathrm{grid}}={\mathrm{128}}^{\mathrm{3}}$ mesh points, the code computes 4.5 million time steps in 24 h wall-clock time using 512 cores.

Results

Figure a shows time-averaged turbulent kinetic-energy spectra for different values of $\stackrel{\mathrm{‾}}{\mathit{ϵ}}$ at fixed ${\mathit{Re}}_{\mathit{\lambda }}\approx \mathrm{130}$. Since the abscissa in the figures is normalized by $k_{\mathit{\eta }}=\mathrm{2}\mathit{\pi }/\mathit{\eta }$, the different spectra shown in Fig. a collapse onto a single curve. Here, $\mathit{\eta }$ is the Kolmogorov length scale. Fig. b shows the time-averaged turbulent kinetic-energy spectra for different values of ${\mathit{Re}}_{\mathit{\lambda }}$ at fixed $\stackrel{\mathrm{‾}}{\mathit{ϵ}}\approx \mathrm{0.039}{\mathrm{m}}^{\mathrm{2}}{\mathrm{s}}^{-\mathrm{3}}$. For larger Reynolds numbers the spectra extend to smaller wavenumbers. A flat profile corresponds to Kolmogorov scaling when the energy spectrum is compensated by ${\stackrel{\mathrm{‾}}{\mathit{ϵ}}}^{-\mathrm{2}/\mathrm{3}}{k}^{\mathrm{5}/\mathrm{3}}$. For the largest ${\mathit{Re}}_{\mathit{\lambda }}$ in our simulations (${\mathit{Re}}_{\mathit{\lambda }}=\mathrm{130}$), the inertial range extends for about a decade in $k$-space.

Time-averaged kinetic-energy spectra of the turbulence gas flow for (a) different $\stackrel{\mathrm{‾}}{\mathit{ϵ}}$ = $\mathrm{0.005}{\mathrm{m}}^{\mathrm{2}}{\mathrm{s}}^{-\mathrm{3}}$ (dash-dotted blue line), 0.019 (dash-dotted magenta line), and 0.039 (dashed cyan line) at fixed ${\mathit{Re}}_{\mathit{\lambda }}=\mathrm{130}$ (see runs C, D, and E in Table  for details) and for (b) different ${\mathit{Re}}_{\mathit{\lambda }}=\mathrm{45}$ (solid black line), 78 (dashed red line), and 130 (dashed cyan line) at fixed $\stackrel{\mathrm{‾}}{\mathit{ϵ}}=\mathrm{0.039}{\mathrm{m}}^{\mathrm{2}}{\mathrm{s}}^{-\mathrm{3}}$ (see runs A, B, and C in Table  for details).

[Figure omitted. See PDF]

Next we inspect the response of thermodynamics to turbulence. In Fig. , we show time series of fluctuations of temperature $T_{\mathrm{rms}}$, water vapor mixing ratio $q_{\mathrm{v},\mathrm{rms}}$, buoyancy force $B_{\mathrm{rms}}$, and the supersaturation $s_{\mathrm{rms}}$. All quantities reach a statistically steady state within a few seconds. The steady-state values of $T_{\mathrm{rms}}$, $q_{\mathrm{v},\mathrm{rms}}$, and $s_{\mathrm{rms}}$ increase with increasing ${\mathit{Re}}_{\mathit{\lambda }}$ approximately linearly and hardly vary at all with $\stackrel{\mathrm{‾}}{\mathit{ϵ}}$. On the other hand, $B_{\mathrm{rms}}$ changes only by a few percent as ${\mathit{Re}}_{\mathit{\lambda }}$ or $\stackrel{\mathrm{‾}}{\mathit{ϵ}}$ vary. Note, however, that the buoyancy force is only about 0.3 % of the fluid acceleration. This is because $T_{\mathrm{rms}}$ is small (about $\mathrm{0.1}\mathrm{K}$ in the present study). Therefore, the effect of the buoyancy force should indeed be small.

Time series of the field quantities: (a) $T_{\mathrm{rms}}$, (b) $q_v,\mathrm{rms}$, (c) $B_{\mathrm{rms}}$, and (d) $s_{\mathrm{rms}}$. Same simulations as in Fig. .

[Figure omitted. See PDF]

When changing $\stackrel{\mathrm{‾}}{\mathit{ϵ}}$ while keeping ${\mathit{Re}}_{\mathit{\lambda }}$ fixed, the Kolmogorov scale of turbulence varies. Therefore, the various fluctuations quoted above are insensitive to the small scales of turbulence. However, when varying ${\mathit{Re}}_{\mathit{\lambda }}$ while keeping $\stackrel{\mathrm{‾}}{\mathit{ϵ}}$ fixed, their rms values change, which is due to large scales of turbulence. Indeed, temperature fluctuations are driven by the large scales of turbulence, which affects the supersaturated vapor pressure $q_{\mathrm{vs}}$ via the Clausius–Clapeyron equation; see Eq. (). Therefore, supersaturation fluctuations result from both temperature fluctuations and water vapor fluctuations via Eq. (). Both $q_{\mathrm{v},\mathrm{rms}}$ and $T_{\mathrm{rms}}$ increase with increasing ${\mathit{Re}}_{\mathit{\lambda }}$, resulting in larger fluctuations of $s$. Supersaturation fluctuations, in turn, affect $T$ and $q_{\mathrm{v}}$ via the condensation rate $C_d$.

Comparison of the time evolution of droplet size distributions for different (a) $\stackrel{\mathrm{‾}}{\mathit{ϵ}}$ at ${\mathit{Re}}_{\mathit{\lambda }}=\mathrm{130}$ (runs C, D, and E in Table ) and (b) ${\mathit{Re}}_{\mathit{\lambda }}$ at $\stackrel{\mathrm{‾}}{\mathit{ϵ}}=\mathrm{0.039}$ m${}^{\mathrm{2}}$ s${}^{-\mathrm{3}}$ (runs A, B, and C in Table ). Same simulations as in Fig. .

[Figure omitted. See PDF]

Our goal is to investigate the condensational growth of cloud droplets due to supersaturation fluctuations. Figure  shows the time evolution of droplet size distributions for different configurations. The conventional understanding is that condensational growth leads to a narrow size distribution . However, supersaturation fluctuations broaden the distribution. More importantly, the width of the size distribution increases with increasing ${\mathit{Re}}_{\mathit{\lambda }}$, but decreases slightly with increasing $\stackrel{\mathrm{‾}}{\mathit{ϵ}}$ over the range studied here. This is consistent with the results shown in Fig.  in that supersaturation fluctuations are sensitive to ${\mathit{Re}}_{\mathit{\lambda }}$ but are insensitive to $\stackrel{\mathrm{‾}}{\mathit{ϵ}}$. In atmospheric clouds, ${\mathit{Re}}_{\mathit{\lambda }}\approx {\mathrm{10}}^{\mathrm{4}}$, which may result in an even broader size distribution.

Time evolution of ${\mathit{\sigma }}_A$ for different (a) $\stackrel{\mathrm{‾}}{\mathit{ϵ}}$ at ${\mathit{Re}}_{\mathit{\lambda }}=\mathrm{130}$ and (b) ${\mathit{Re}}_{\mathit{\lambda }}$ at $\stackrel{\mathrm{‾}}{\mathit{ϵ}}=\mathrm{0.039}{\mathrm{m}}^{\mathrm{2}}{\mathrm{s}}^{-\mathrm{3}}$. Same simulations as in Fig. .

[Figure omitted. See PDF]

We further quantify the variance of the size distribution by investigating the time evolution of the standard deviation of the droplet surface area ${\mathit{\sigma }}_A$ for different configurations. In terms of the droplet surface area $A_i$ ($A_i\propto r_i^{\mathrm{2}}$), Eq. () can be written as $${\displaystyle \frac{\mathrm{d}{A}_i}{\mathrm{d}t}}=\mathrm{2}\mathrm{Gs}.$$ It can be seen from Eq. () that the evolution of the surface area is analogous to Brownian motion, indicating that its standard deviation ${\mathit{\sigma }}_A\propto \sqrt{t}$. A more detailed stochastic model for ${\mathit{\sigma }}_A$ is developed by . Based on Eq. (), ${\mathit{\sigma }}_A$ is given by $${\displaystyle \frac{\mathrm{d}{\mathit{\sigma }}_A^{\mathrm{2}}}{\mathrm{d}t}}={\displaystyle \frac{\mathrm{d}}{\mathrm{d}t}}⟨{A^{\prime }}^{\mathrm{2}}⟩={\displaystyle \frac{\mathrm{d}}{\mathrm{d}t}}⟨A^{\mathrm{2}}-{⟨A⟩}^{\mathrm{2}}\mathrm{4}G⟨s^{\prime }{A}^{\prime }⟩$$ adopted a Langevin equation to model the supersaturation field and the vertical velocity of droplets, resulting in the scaling law: $${\mathit{\sigma }}_A\sim C({\mathit{\tau }}_L,{\mathit{\tau }}_{\mathrm{s}},{\mathit{Re}}_{\mathit{\lambda }})t^{\mathrm{1}/\mathrm{2}},$$ where $C({\mathit{\tau }}_L,{\mathit{\tau }}_{\mathrm{s},{\mathit{Re}}_{\mathit{\lambda }}})$ is a constant for given ${\mathit{\tau }}_L$, ${\mathit{\tau }}_{\mathrm{s}}$, and ${\mathit{Re}}_{\mathit{\lambda }}$. Under the assumptions that ${\mathit{\tau }}_{\mathrm{s}}\ll T_L$ and a negligible influence on the macroscopic observables from small-scale turbulent motions, obtained an analytical expression for ${\mathit{\sigma }}_A$ as $${\mathit{\sigma }}_A\sim {\mathit{\tau }}_{\mathrm{s}}{\mathit{Re}}_{\mathit{\lambda }}{t}^{\mathrm{1}/\mathrm{2}},$$ where ${\mathit{\tau }}_{\mathrm{s}}$ is the phase transition timescale given by $${\mathit{\tau }}_{\mathrm{s}}^{-\mathrm{1}}\left(t\right)=\mathrm{4}\mathit{\pi }G\underset{\mathrm{0}}{\overset{\mathrm{\infty }}{\int }}rf\mathrm{d}r,$$ and ${\mathit{\tau }}_L$ is the turbulence integral timescale. The model proposed that condensational growth of cloud droplets depends only on ${\mathit{Re}}_{\mathit{\lambda }}$ and is independent of $\stackrel{\mathrm{‾}}{\mathit{ϵ}}$. In terms of the size distribution $f(r,t)$, ${\mathit{\sigma }}_A$ can be given as $${\mathit{\sigma }}_A=\sqrt{a_{\mathrm{4}}-a_{\mathrm{2}}^{\mathrm{2}}},$$ where $a_{\mathit{\zeta }}$ is the moment of the size distribution, which is defined as $$a_{\mathit{\zeta }}=\underset{\mathrm{0}}{\overset{\mathrm{\infty }}{\int }}f{r}^{\mathit{\zeta }}\mathrm{d}r/\underset{\mathrm{0}}{\overset{\mathrm{\infty }}{\int }}f\mathrm{d}r.$$ Here, $\mathit{\zeta }$ is a positive integer. As shown in Fig. , the time evolution of ${\mathit{\sigma }}_A$ agrees with the prediction ${\mathit{\sigma }}_A\propto t^{\mathrm{1}/\mathrm{2}}$. and solved the passive scalar equation of $s$ without considering fluctuations of $T$ and $q_{\mathrm{v}}$. Feedbacks to flow fields from cloud droplets were also neglected. They found good agreement between the DNS and the stochastic model. Comparing with and , our study solves the complete sets of the thermodynamics of supersaturation. It is remarkable that a good agreement between the stochastic model and our DNS is observed. This indicates that the stochastic model is robust. On the other hand, modeling supersaturation fluctuations using the passive scalar equation seems to be sufficient for the Reynolds numbers considered in this study. We recall that ${\mathit{\tau }}_{\mathrm{s}}$ in Eq. () is constant. In the present study, ${\mathit{\tau }}_{\mathrm{s}}$ is determined by Eq. (). Therefore, ${\mathit{\tau }}_{\mathrm{s}}$ varies with time as shown in the inset of Fig. a. Nevertheless, since the variation of ${\mathit{\tau }}_{\mathrm{s}}$ is small, we still observe ${\mathit{\sigma }}_A\sim t^{\mathrm{1}/\mathrm{2}}$ except for the initial phase of the evolution, where $s(t=\mathrm{0})=\mathrm{2}\mathit{\%}$.

Comparing panels a and b of Fig. , it is clear that changing ${\mathit{Re}}_{\mathit{\lambda }}$ has a much larger effect on ${\mathit{\sigma }}_A$ than changing $\stackrel{\mathrm{‾}}{\mathit{ϵ}}$. In fact, as $\stackrel{\mathrm{‾}}{\mathit{ϵ}}$ is increased by a factor of about 8, ${\mathit{\sigma }}_A$ decreases only by a factor of about 1.6, so the ratio of their logarithms is about $\mathrm{1}/\mathrm{5}$, i.e., ${\mathit{\sigma }}_A\propto {\stackrel{\mathrm{‾}}{\mathit{ϵ}}}^{-\mathrm{1}/\mathrm{5}}$. By contrast, ${\mathit{\sigma }}_A$ changes by a factor of about 5 as ${\mathit{Re}}_{\mathit{\lambda }}$ is increased by a factor of nearly 3, so ${\mathit{\sigma }}_A\propto {\mathit{Re}}_{\mathit{\lambda }}^{\mathrm{3}/\mathrm{2}}$. This quantifies the high sensitivity of ${\mathit{\sigma }}_A$ to changes in ${\mathit{Re}}_{\mathit{\lambda }}$ compared to $\stackrel{\mathrm{‾}}{\mathit{ϵ}}$.

Two comments are here in order. First, we emphasize that we observe here ${\mathit{\sigma }}_A\propto {\mathit{Re}}_{\mathit{\lambda }}^{\mathrm{3}/\mathrm{2}}$ instead of ${\mathit{\sigma }}_A\propto {\mathit{Re}}_{\mathit{\lambda }}$. Therefore, there could be a critical ${\mathit{Re}}_{\mathit{\lambda }}$, beyond which ${\mathit{\sigma }}_A\propto {\mathit{Re}}_{\mathit{\lambda }}$ and below which ${\mathit{\sigma }}_A\propto {\mathit{Re}}_{\mathit{\lambda }}^{\mathrm{3}/\mathrm{2}}$. However, the highest ${\mathit{Re}}_{\mathit{\lambda }}$ in our DNS is 130. To verify this proposal, a large parameter range of ${\mathit{Re}}_{\mathit{\lambda }}$ is required. Second, we note that ${\mathit{\sigma }}_A\propto {\stackrel{\mathrm{‾}}{\mathit{ϵ}}}^{-\mathrm{1}/\mathrm{5}}$. This is because the Damköhler number increases with decreasing $\stackrel{\mathrm{‾}}{\mathit{ϵ}}$ (see Table ), which is defined as the ratio of the fluid timescale to the characteristic thermodynamic timescale associated with the evaporation process $\mathrm{Da}={\mathit{\tau }}_{\mathrm{L}}/{\mathit{\tau }}_{\mathrm{s}}$. also found that ${\mathit{\sigma }}_A$ decreases with $\stackrel{\mathrm{‾}}{\mathit{ϵ}}$, even though the mean updraft cooling is included in their study.

Discussion and conclusion

Condensational growth of cloud droplets due to supersaturation fluctuations is investigated using DNS. Cloud droplets are tracked in a Lagrangian framework, where the momentum equation for inertial particles are solved. The thermodynamic equations governing the supersaturation field are solved simultaneously. Feedback from cloud droplets onto $\mathit{u}$, $T$, and $q_{\mathrm{v}}$ is included through the condensation rate and buoyancy force. We resolve the smallest scale of turbulence in all simulations. Contrary to the classical condensation theory, which leads to a narrow distribution when supersaturation fluctuations are ignored, we find that droplet size distributions broaden due to supersaturation fluctuations. For the first time, we explicitly demonstrate that the size distribution becomes wider with increasing ${\mathit{Re}}_{\mathit{\lambda }}$, which is, however, insensitive to $\stackrel{\mathrm{‾}}{\mathit{ϵ}}$. Supersaturation fluctuations are subjected to both temperature fluctuations and water vapor mixing ratio fluctuations.

We observe that ${\mathit{\sigma }}_A\propto \sqrt{t}$ when the complete sets of the thermodynamics equations governing the supersaturation are solved, which are consistent with the findings by and even though fluctuations of temperature and water vapor mixing ratio, buoyancy force, and droplets feedbacks to the field quantities are neglected in their studies. This indicates that the stochastic model of condensational growth developed by is robust. For the first time, to our knowledge, the stochastic model and simulation results from the complete set of thermodynamics equations governing the supersaturation field are compared. The broadening size distribution with increasing ${\mathit{Re}}_{\mathit{\lambda }}$ demonstrates that condensational growth due to supersaturation fluctuations is an important mechanism for droplet growth. The maximum ${\mathit{Re}}_{\mathit{\lambda }}$ in the present study is 130, which is about 2 orders of magnitude smaller than the one in atmospheric clouds (${\mathit{Re}}_{\mathit{\lambda }}={\mathrm{10}}^{\mathrm{4}}$). Since the width of the size distribution increases dramatically with increasing ${\mathit{Re}}_{\mathit{\lambda }}$, the supersaturation-fluctuation-facilitated condensation may easily overcome the bottleneck barrier .

The stochastic model developed by assumes that the width of droplet size distributions is independent of $\stackrel{\mathrm{‾}}{\mathit{ϵ}}$. Our result shows that the width decreases slightly with increasing $\stackrel{\mathrm{‾}}{\mathit{ϵ}}$. However, the largest $\stackrel{\mathrm{‾}}{\mathit{ϵ}}$ in warm clouds is about ${\mathrm{10}}^{-\mathrm{3}}{\mathrm{m}}^{\mathrm{2}}{\mathrm{s}}^{-\mathrm{3}}$ . Therefore, neglecting the smallest scales in the stochastic model is indeed acceptable. also found that the width of the droplet size distribution decreases with increasing $\stackrel{\mathrm{‾}}{\mathit{ϵ}}$ and attributed this to the decorrelation between supersaturation fluctuations and surface area of droplets. , however, found stronger correlation between supersaturation fluctuations and surface area of droplets with increasing ${\mathit{Re}}_{\mathit{\lambda }}$. The present study is consistent with both the works of and . Therefore, we emphasize that there is no contradiction between both papers.

In the present study, the simulation box is stationary, which means that the volume is not exposed to cooling, as no mean updraft is considered. Therefore, the condensational growth is solely driven by supersaturation fluctuations. This is similar to the condensational growth of cloud droplets in stratiform clouds, where the updraft velocity of the parcel is close to zero . The observational data show that the width of the size distribution is wider than the one expected from condensational growth with a mean supersaturation . Qualitatively consistent with observations, we show that the width of droplet size distributions broadens due to supersaturation fluctuations.

Entrainment of dry air is not considered here. It may lead to rapid changes in the supersaturation fluctuations and result in an even faster broadening of the size distribution . Activation of aerosols in a turbulent environment is omitted. This may provide a more physical and realistic initial distribution of cloud droplets. Incorporating all the cloud microphysical processes is computationally demanding and will have be explored in future studies.