1 Introduction

Halogen radicals (chlorine, bromine, iodine) have a broad range of implications for tropospheric oxidant chemistry. They originate from sea salt aerosol (SSA), emitted halogen gases, and transport from the stratosphere, and they cycle rapidly with inorganic non-radical reservoirs (Platt and Hönninger, 2003; Finlayson-Pitts, 2003; Saiz-Lopez and von Glasow, 2012; Simpson et al., 2015; Wang et al., 2019). Cl, Br, and I atoms provide sinks for volatile organic compounds (VOCs), dimethylsulfide (DMS), and mercury (Atkinson, 1997; Saiz-Lopez and von Glasow, 2012; Horowitz et al., 2017). Cycling between halogen radicals and their reservoirs converts ${\mathrm{NO}}_{\mathit{\text{x}}}$ to ${\mathrm{HNO}}_{\mathrm{3}}$ and causes catalytic loss of ozone (von Glasow et al., 2004; Yang et al., 2005; Sherwen et al., 2016b). Reaction of ${\mathrm{Cl}}^{-}$ with ${\mathrm{N}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{5}}$ in polluted environments at night produces ${\mathrm{ClNO}}_{\mathrm{2}}$ that photolyzes in the daytime to return Cl atoms and ${\mathrm{NO}}_{\mathrm{2}}$, stimulating ozone production (Osthoff et al., 2008; Roberts et al., 2008). Acid displacement of ${\mathrm{Cl}}^{-}$ by ${\mathrm{HNO}}_{\mathrm{3}}$ is a source of ${\mathrm{NO}}_{\mathrm{3}}^{-}$ aerosol. Reviews by Saiz-Lopez and von Glasow (2012) and Simpson et al. (2015) describe this fundamental knowledge of tropospheric halogen chemistry in more detail.

A number of global modeling studies have explored the importance of halogen chemistry in the troposphere (von Glasow et al., 2004; Saiz-Lopez et al., 2006; Ordóñez et al., 2012; Long et al., 2014), but there remain large uncertainties in sources and chemical mechanisms. Here we present a new mechanistic description of halogen tropospheric chemistry in the GEOS-Chem global model that synthesizes previous GEOS-Chem developments (Parrella et al., 2012; Eastham et al., 2014; Schmidt et al., 2016; Sherwen et al., 2016a, b, 2017; Chen et al., 2017; Wang et al., 2019; Zhu et al., 2019) and includes a number of updates. We use the updated model to interpret recent observations of tropospheric halogens, describe halogen radical cycling, and quantify the impacts on tropospheric oxidant chemistry. Shah et al. (2021) examine the impact of our simulated Br and Cl atom concentrations in a new redox mechanism for atmospheric mercury.

2 Tropospheric halogen chemistry in GEOS-Chem

We describe here our updated representation of tropospheric halogen chemistry in version 12.9 of GEOS-Chem (http://www.geos-chem.org), implemented as part of the general model mechanism for coupled ozone–${\mathrm{NO}}_{\mathit{\text{x}}}$–VOCs–aerosol–halogen tropospheric and stratospheric chemistry. Extensive referencing will be made to Sherwen et al. (2016b), who implemented the previous representation of tropospheric halogen chemistry in GEOS-Chem (version 11-02), and to Wang et al. (2019), who described an earlier version of the mechanism implemented here. GEOS-Chem stratospheric halogen chemistry is as described by Eastham et al. (2014), and we do not discuss it further here.

Table 1

Global sources and sinks of tropospheric gas-phase inorganic chlorine (${\mathrm{Cl}}_{\mathit{\text{y}}}$), bromine (${\mathrm{Br}}_{\mathit{\text{y}}}$), and iodine (${\mathrm{I}}_{\mathit{\text{y}}}$)${}^{\mathrm{a}}$.

${}^{\mathrm{a}}$ Annual totals for 2016 computed from GEOS-Chem. Dashes indicate negligibly small terms. Gas-phase inorganic chlorine is defined as ${\mathrm{Cl}}_{\mathit{\text{y}}}$ $\equiv$ $\mathrm{Cl}$ $+$ 2 $\times$ ${\mathrm{Cl}}_{\mathrm{2}}$ $+$ 2 $\times$ ${\mathrm{Cl}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{2}}$ $+$ ${\mathrm{ClNO}}_{\mathrm{2}}$ $+$ ${\mathrm{ClNO}}_{\mathrm{3}}$ $+$ $\mathrm{ClO}$ $+$ $\mathrm{ClOO}$ $+$ $\mathrm{OClO}$ $+$ $\mathrm{BrCl}$ $+$ $\mathrm{ICl}$ $+$ $\mathrm{HOCl}$ $+$ $\mathrm{HCl}$. Gas-phase inorganic bromine is defined as ${\mathrm{Br}}_{\mathit{\text{y}}}$ $\equiv$ $\mathrm{Br}$ $+$ 2 $\times$ ${\mathrm{Br}}_{\mathrm{2}}$ $+$ ${\mathrm{BrNO}}_{\mathrm{2}}$ $+$ ${\mathrm{BrNO}}_{\mathrm{3}}$ $+$ $\mathrm{BrO}$ $+$ $\mathrm{BrCl}$ $+$ $\mathrm{IBr}$ $+$ $\mathrm{HOBr}$ $+$ $\mathrm{HBr}$. Gas-phase inorganic iodine is defined as ${\mathrm{I}}_{\mathit{\text{y}}}$ $\equiv$ $\mathrm{I}$ $+$ 2 $\times$ ${\mathrm{I}}_{\mathrm{2}}$ $+$ 2 $\times$ ${\mathrm{I}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{2}}$ $+$ 2 $\times$ ${\mathrm{I}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{3}}$ $+$ 2 $\times$ ${\mathrm{I}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{4}}$ $+$ $\mathrm{OIO}$ $+$ $\mathrm{INO}$ $+$ ${\mathrm{INO}}_{\mathrm{2}}$ $+$ ${\mathrm{INO}}_{\mathrm{3}}$ $+$ $\mathrm{IO}$ $+$ $\mathrm{ICl}$ $+$ $\mathrm{IBr}$ $+$ $\mathrm{HOI}$ $+$ $\mathrm{HI}$. We use $X$ to denote any of Cl, Br, or I. ${}^{\mathrm{b}}$ Acid displacement, significant only for $\mathrm{HCl}$. The table gives the net production minus loss of $\mathrm{HCl}$ from acid aerosol displacement by ${\mathrm{HNO}}_{\mathrm{3}}$ and ${\mathrm{H}}_{\mathrm{2}}{\mathrm{SO}}_{\mathrm{4}}$ minus $\mathrm{HCl}$ uptake by sea salt alkalinity. ${}^{\mathrm{c}}$ ${\mathrm{CH}}_{\mathrm{2}}$$X_{\mathrm{2}}$ and $\mathrm{CH}$$X_{\mathrm{3}}$ denote unmixed halogens, such as ${\mathrm{CH}}_{\mathrm{2}}{\mathrm{Cl}}_{\mathrm{2}}$ or ${\mathrm{CHBr}}_{\mathrm{3}}$. ${\mathrm{CH}}_{\mathrm{2}}\mathrm{I}$$X$ denotes the mixed iodocarbons ${\mathrm{CH}}_{\mathrm{2}}\mathrm{ICl}$ and ${\mathrm{CH}}_{\mathrm{2}}\mathrm{IBr}$. ${}^{\mathrm{d}}$ Net stratospheric input to the troposphere. ${}^{\mathrm{e}}$ For ${\mathrm{Cl}}_{\mathit{\text{y}}}$ the uptake is included as an offsetting term in the acid displacement source (footnote ${}^{\mathrm{b}}$). NA: not available.

Table 1 lists the global sources and sinks of tropospheric gas-phase inorganic chlorine (${\mathrm{Cl}}_{\mathit{\text{y}}}$), bromine (${\mathrm{Br}}_{\mathit{\text{y}}}$), and iodine (${\mathrm{I}}_{\mathit{\text{y}}}$) in GEOS-Chem (see Table 1 for definitions of ${\mathrm{Cl}}_{\mathit{\text{y}}}$, ${\mathrm{Br}}_{\mathit{\text{y}}}$, and ${\mathrm{I}}_{\mathit{\text{y}}}$). SSA emissions are from Jaeglé et al. (2011). Open-fire emissions of $\mathrm{HCl}$ are obtained by applying the emission factors from Andreae (2019) for different vegetation types to the GFED4 (Global Fire Emissions Database version 4) biomass burned inventory (van der Werf et al., 2017). The resulting global source of 0.5 $\mathrm{Tg}\mathrm{Cl}{\mathrm{a}}^{-\mathrm{1}}$ is much smaller than in Wang et al. (2019), who used older emission factors from Lobert et al. (1999). Organohalogen gases can produce halogen radicals by oxidation and photolysis. Emissions of ${\mathrm{CH}}_{\mathrm{3}}\mathrm{Cl}$, ${\mathrm{CH}}_{\mathrm{2}}{\mathrm{Cl}}_{\mathrm{2}}$, ${\mathrm{CHCl}}_{\mathrm{3}}$, and ${\mathrm{CHBr}}_{\mathrm{3}}$ are implicitly treated in the model by specifying latitudinal and monthly surface air boundary conditions from CMIP6 (historical greenhouse gas concentrations for climate modeling) (Meinshausen et al., 2017). Emissions of other bromocarbons (${\mathrm{CH}}_{\mathrm{3}}\mathrm{Br}$, ${\mathrm{CH}}_{\mathrm{2}}{\mathrm{Br}}_{\mathrm{2}}$) and iodocarbons (${\mathrm{CH}}_{\mathrm{3}}\mathrm{I}$, ${\mathrm{CH}}_{\mathrm{2}}{\mathrm{I}}_{\mathrm{2}}$, ${\mathrm{CH}}_{\mathrm{2}}\mathrm{ICl}$, ${\mathrm{CH}}_{\mathrm{2}}\mathrm{IBr}$) are from Bell et al. (2002), Liang et al. (2010), and Ordóñez et al. (2012).

We do not include continental emissions of inorganic chlorine from anthropogenic sources (fuel combustion, waste incineration, etc.) and dust because they are highly uncertain and most likely negligible from a global perspective. The only available global emission inventory for anthropogenic $\mathrm{HCl}$ and ${\mathrm{Cl}}^{-}$ is that of McCulloch et al. (1999) at 6.7 $\mathrm{Tg}\mathrm{Cl}{\mathrm{a}}^{-\mathrm{1}}$ for 1990s, but we previously found this inventory to be too high by an order of magnitude in comparison to regional inventories and atmospheric observations (Wang et al., 2019). Analysis of deposition data by Haskins et al. (2020) finds that anthropogenic chlorine emissions have decreased by 95 % in the US since 1998, further indicating that the McCulloch et al. (1999) inventory is outdated. Our previous model comparisons to aerosol ${\mathrm{Cl}}^{-}$ observations indicate that anthropogenic chlorine sources are important in China (Wang et al., 2020) but not in the US, where the observed ${\mathrm{Cl}}^{-}$ concentrations can be attributed to long-range transport of SSA plus some dust influence in the southwest (Wang et al., 2019). Zhai et al. (2021), who include anthropogenic $\mathrm{HCl}$ emissions using the observed $\mathrm{HCl}:{\mathrm{SO}}_{\mathrm{2}}$ ratio (Lee et al., 2018), also find that anthropogenic sources of chlorine are very small over North America and western Europe. Because of this neglect of anthropogenic sources, our model results may underestimate chlorine concentrations in continental source regions.

The main global source of tropospheric ${\mathrm{Cl}}_{\mathit{\text{y}}}$ is mobilization of ${\mathrm{Cl}}^{-}$ from SSA. A total of 50 $\mathrm{Tg}{\mathrm{Cl}}^{-}{\mathrm{a}}^{-\mathrm{1}}$ (2.4 % of SSA emissions) is mobilized to ${\mathrm{Cl}}_{\mathit{\text{y}}}$ in the model by acid displacement and other heterogeneous reactions. This number is smaller than our previous estimate in Wang et al. (2019) (64 $\mathrm{Tg}{\mathrm{Cl}}^{-}{\mathrm{a}}^{-\mathrm{1}}$), mainly due to slower ${\mathrm{ClNO}}_{\mathrm{2}}$ generation from the ${\mathrm{N}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{5}}$ $+$ ${\mathrm{Cl}}^{-}$ reaction (Sect. 2.3). Organochlorines provide a tropospheric source of 3.3 $\mathrm{Tg}{\mathrm{Cl}}^{-}{\mathrm{a}}^{-\mathrm{1}}$ as Cl atoms from photolysis and oxidation. Transport from the stratosphere adds 0.14 $\mathrm{Tg}\mathrm{Cl}{\mathrm{a}}^{-\mathrm{1}}$ to tropospheric ${\mathrm{Cl}}_{\mathit{\text{y}}}$. The source of ${\mathrm{I}}_{\mathit{\text{y}}}$ is estimated to be 2.7 $\mathrm{Tg}\mathrm{I}{\mathrm{a}}^{-\mathrm{1}}$, mostly from the inorganic iodine (HOI, ${\mathrm{I}}_{\mathrm{2}}$) formed from the ocean surface reaction of ${\mathrm{O}}_{\mathrm{3}}$ with iodide (${\mathrm{I}}^{-}$), based on Carpenter et al. (2013) and MacDonald et al. (2014) and as described by Sherwen et al. (2016b).

In GEOS-Chem versions before 12.9, SSA debromination was not included despite being known to be an important source for ${\mathrm{Br}}_{\mathit{\text{y}}}$ (Sander et al., 2003). This is because SSA debromination generated excessive $\mathrm{BrO}$ concentrations in comparison to observations, which then drove excessive ozone depletion (Schmidt et al., 2016; Zhu et al., 2019). Revision of $\mathrm{HOBr}$ reactive uptake as a source of bromine radicals effectively corrects this problem (Sect. 2.2), allowing us to include mechanistically the SSA debromination source. This provides the main global source of tropospheric ${\mathrm{Br}}_{\mathit{\text{y}}}$ (20 $\mathrm{Tg}\mathrm{Br}{\mathrm{a}}^{-\mathrm{1}}$), mostly through the $\mathrm{HOBr}$, HOCl, and HOI $+$ ${\mathrm{Br}}^{-}$ heterogeneous reactions. Bromocarbon gases contribute only 0.54 $\mathrm{Gg}\mathrm{Br}{\mathrm{a}}^{-\mathrm{1}}$ to ${\mathrm{Br}}_{\mathit{\text{y}}}$ but still dominate the ${\mathrm{Br}}_{\mathit{\text{y}}}$ source in the free troposphere.

2.2 Chemical mechanism

Our tropospheric halogen chemistry mechanism synthesizes and updates previous GEOS-Chem mechanistic developments. Chlorine chemistry in GEOS-Chem was first built in Eastham et al. (2014) for the stratosphere and extended to the troposphere by Schmidt et al. (2016), with updates by Sherwen et al. (2016b, 2017) and Wang et al. (2019, 2020). Tropospheric bromine chemistry was first built by Parrella et al. (2012), with updates to heterogeneous reactions by Schmidt et al. (2016), Chen et al. (2017), Wang et al. (2019), and Zhu et al. (2019). Iodine chemistry was built by Sherwen et al. (2016a, b). Recent general model updates important for halogen chemistry include a new method of simulating cloud chemistry in partly cloudy grid cells that accounts for limitation by entrainment of air into the cloud (Holmes et al., 2019) and an improved cloud water pH calculation that considers carboxylic acids and dust alkalinity (Moch et al., 2020; Shah et al., 2020). Aqueous aerosol thermodynamics including calculation of aerosol pH and $\mathrm{HCl}$–${\mathrm{Cl}}^{-}$ partitioning are from ISORROPIA II (Fountoukis and Nenes, 2007).

Table 2

First-order reaction rate constants ($k^I$) for $\mathrm{HOBr}$ heterogeneous reactions in aerosol and liquid cloud water.

${}^{\mathrm{a}}$ This first-order rate constant describes the first-order $\mathrm{HOBr}$ loss rate $-\frac{\mathrm{d}\left[\mathrm{HOBr}\right]}{\mathrm{d}t}=k^I\left[\mathrm{HOBr}\right]$, which is used in Eqs. (1)–(4) to calculate the $\mathrm{HOBr}$ reactive uptake coefficient $\mathit{\gamma }$. ${}^{\mathrm{b}}$ References: (1) Liu and Abbatt (2020), (2) Troy and Margerum (1991), (3) Fickert et al. (1999), (4) Roberts et al. (2014), Beckwith et al. (1996; $k_{\text{ter}}$ value), (5) Roberts et al. (2014), Liu and Margerum (2001; $k_{\text{ter}}$ value).

We update here the reactive uptake of $\mathrm{HOBr}$ by aerosols and cloud droplets (Table 2). This uptake involves reactions with ${\mathrm{Br}}^{-}$, ${\mathrm{Cl}}^{-}$, and dissolved ${\mathrm{SO}}_{\mathrm{2}}$ ($\mathrm{S}\left(\mathrm{IV}\right)$ $\equiv$ ${\mathrm{HSO}}_{\mathrm{3}}^{-}$ $+$ ${\mathrm{SO}}_{\mathrm{3}}^{\mathrm{2}-}$): $$\begin{array}{}\text{R1}& {\displaystyle }\mathrm{HOBr}\left(\mathrm{aq}\right)+{\mathrm{Br}}^{-}+{\mathrm{H}}^{+}\to {\mathrm{Br}}_{\mathrm{2}}+{\mathrm{H}}_{\mathrm{2}}\mathrm{O}\text{R2}& {\displaystyle }\mathrm{HOBr}\left(\mathrm{aq}\right)+{\mathrm{Cl}}^{-}+{\mathrm{H}}^{+}\to \mathrm{BrCl}+{\mathrm{H}}_{\mathrm{2}}\mathrm{O}\text{R3}& {\displaystyle }\mathrm{HOBr}\left(\mathrm{aq}\right)+{\mathrm{HSO}}_{\mathrm{3}}^{-}\to \mathrm{HBr}+{\mathrm{HSO}}_{\mathrm{4}}^{-}\text{R4}& {\displaystyle }\mathrm{HOBr}\left(\mathrm{aq}\right)+{\mathrm{SO}}_{\mathrm{3}}^{\mathrm{2}-}\to \mathrm{HBr}+{\mathrm{SO}}_{\mathrm{4}}^{\mathrm{2}-}.\end{array}$$

Reactions (R1) and (R2) with subsequent fast photolysis of ${\mathrm{Br}}_{\mathrm{2}}$ and $\mathrm{BrCl}$ recycle bromine radicals from $\mathrm{HOBr}$ and further mobilize ${\mathrm{Br}}^{-}$ and ${\mathrm{Cl}}^{-}$ to produce new radicals. In GEOS-Chem, the rates are applied to the following stoichiometry: R5$$\begin{array}{rl}\mathrm{HOBr}\left(\mathrm{aq}\right)& +Y{\mathrm{Br}}^{-}+(\mathrm{1}-Y){\mathrm{Cl}}^{-}+{\mathrm{H}}^{+}\to \\ & Y{\mathrm{Br}}_{\mathrm{2}}+(\mathrm{1}-Y)\mathrm{BrCl}+{\mathrm{H}}_{\mathrm{2}}\mathrm{O},\end{array}$$ where $Y$ is the yield of ${\mathrm{Br}}_{\mathrm{2}}$, and $\mathrm{1}-Y$ is the yield of $\mathrm{BrCl}$, which are calculated based on the laboratory study of Fickert et al. (1999) and described in Table 2.

Total reactive uptake of $\mathrm{HOBr}$ from Reactions (R3)–(R5) in aqueous aerosols and clouds is calculated with a standard first-order reactive uptake coefficient $\mathit{\gamma }$ (Jacob, 2000), calculated following Ammann et al. (2013): $$\begin{array}{}\text{1}& {\displaystyle }\mathit{\gamma }={\left({\displaystyle \frac{\mathrm{1}}{\mathrm{\Gamma }}}+{\displaystyle \frac{\mathrm{1}}{{\mathit{\alpha }}_b}}\right)}^{-\mathrm{1}}\text{2}& {\displaystyle }\mathrm{\Gamma }=\mathrm{4}{H}_{\mathrm{HOBr}}RT{I}_{\mathrm{r}}{k}^{I}f(r,I_{\mathrm{r}})/c\text{3}& {\displaystyle }{I}_{\mathrm{r}}=\sqrt{D_{\mathrm{l}}/k^I}\text{4}& {\displaystyle }{k}^I=k_{\mathrm{3}}^I+k_{\mathrm{4}}^I+k_{\mathrm{5}}^I,\end{array}$$ where $H_{\mathrm{HOBr}}$ is the Henry's law constant of $\mathrm{HOBr}$ (Sander, 2015); $T$ is temperature; $R$ is the universal gas constant (8.314 $\mathrm{J}{\mathrm{K}}^{-\mathrm{1}}{\mathrm{mol}}^{-\mathrm{1}}$); $D_{\mathrm{l}}$ is the liquid-phase diffusion coefficient for $\mathrm{HOBr}$ (1.4 $\times$ 10${}^{-\mathrm{5}}$ ${\mathrm{cm}}^{\mathrm{2}}{\mathrm{s}}^{-\mathrm{1}}$); $f(r,I_{\mathrm{r}}$) is the reacto-diffusive correction term; and $k^I$ is the first-order total reaction rate constant of $\mathrm{HOBr}$ from pathways (R3)–(R5), computed as a function of the concentrations of ${\mathrm{Br}}^{-}$, ${\mathrm{Cl}}^{-}$, ${\mathrm{H}}^{+}$, ${\mathrm{HSO}}_{\mathrm{3}}^{-}$, and ${\mathrm{SO}}_{\mathrm{3}}^{\mathrm{2}-}$. After computing the overall loss of $\mathrm{HOBr}$, we distribute the loss by pathways on the basis of the relative reaction rates $k_i^I$. Reactions (R3) and (R4) are important only in clouds where high liquid water content and relatively high pH enable dissolution of ${\mathrm{SO}}_{\mathrm{2}}$.

Wang et al. (2019) previously calculated $k_{\mathrm{5}}^I$ based on experimental results over limited and inconsistent pH ranges (pH $=$ 1.9–2.4 for $\mathrm{HOBr}$ $+$ ${\mathrm{Br}}^{-}$, pH $=$ 6.4 for $\mathrm{HOBr}$ $+$ ${\mathrm{Cl}}^{-}$; Beckwith et al., 1996; Liu and Margerum, 2001). This generated excessive $\mathrm{BrO}$ concentrations in comparison to observations. Here we revise the calculation of $k_{\mathrm{5}}^I$ to consider the entire range of aerosol and cloud pH, as recommended by Roberts et al. (2014), resulting in a much slower rate. We also adopt a new value for $k_{\mathrm{3}}^I$ from a recent laboratory study (Liu and Abbatt, 2020), updating the upper limit of 3.2 $\times$ 10${}^{\mathrm{9}}$ ${\mathrm{M}}^{-\mathrm{1}}{\mathrm{s}}^{-\mathrm{1}}$ previously reported by Liu (2000). Details of these updates are in Table 2. The overall result is to have less efficient heterogeneous recycling and mobilization of bromine radicals in both aerosols and clouds.

Wang et al. (2019) found the heterogeneous reaction of HOCl with ${\mathrm{Cl}}^{-}$ to be the dominant global tropospheric source of ${\mathrm{Cl}}_{\mathrm{2}}$ in GEOS-Chem: R6$$\mathrm{HOCl}\left(\mathrm{aq}\right)+{\mathrm{Cl}}^{-}+{\mathrm{H}}^{+}\to {\mathrm{Cl}}_{\mathrm{2}}+{\mathrm{H}}_{\mathrm{2}}\mathrm{O}.$$

Here we add competing reactions between $\mathrm{HOCl}$ and $\mathrm{S}\left(\mathrm{IV}\right)$: $$\begin{array}{}\text{R7}& {\displaystyle }\mathrm{HOCl}\left(\mathrm{aq}\right)+{\mathrm{HSO}}_{\mathrm{3}}^{-}\to \mathrm{HCl}+{\mathrm{HSO}}_{\mathrm{4}}^{-}\text{R8}& {\displaystyle }\mathrm{HOCl}\left(\mathrm{aq}\right)+{\mathrm{SO}}_{\mathrm{3}}^{\mathrm{2}-}\to \mathrm{HCl}+{\mathrm{SO}}_{\mathrm{4}}^{\mathrm{2}-},\end{array}$$ with reaction rate coefficients $k_{\mathrm{7}}$ $=$ 2.8 $\times$ 10${}^{\mathrm{5}}$ ${\mathrm{M}}^{-\mathrm{1}}{\mathrm{s}}^{-\mathrm{1}}$ and $k_{\mathrm{8}}$ $=$ 7.6 $\times$ 10${}^{\mathrm{8}}$ ${\mathrm{M}}^{-\mathrm{1}}{\mathrm{s}}^{-\mathrm{1}}$ from Liu and Abbatt (2020) and Fogelman et al. (1989), respectively. Reactions (R7) and (R8) are relatively slow and have minor overall impact on the ${\mathrm{Cl}}_{\mathit{\text{y}}}$ chemistry.

Aerosol aqueous-phase reaction of ${\mathrm{N}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{5}}$ with ${\mathrm{Cl}}^{-}$ produces ${\mathrm{ClNO}}_{\mathrm{2}}$ that photolyzes in the daytime to return Cl atoms and ${\mathrm{NO}}_{\mathrm{2}}$. The reaction competes with ${\mathrm{N}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{5}}$ hydrolysis, with the following first-order loss representation for ${\mathrm{N}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{5}}$: R9$${\mathrm{N}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{5}}\stackrel{\mathit{\phi }{\mathrm{Cl}}^{-}(\mathrm{1}-\mathit{\phi }){\mathrm{H}}_{\mathrm{2}}\mathrm{O}}{⟶}\mathit{\phi }{\mathrm{ClNO}}_{\mathrm{2}}+(\mathrm{2}-\mathit{\phi }){\mathrm{NO}}_{\mathrm{3}}^{-}+\mathrm{2}(\mathrm{1}-\mathit{\phi }){\mathrm{H}}^{+}.$$

McDuffie et al. (2018a, b) evaluated different model expressions for the reactive uptake coefficient ${\mathit{\gamma }}_{{\mathrm{N}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{5}}}$ and the ${\mathrm{ClNO}}_{\mathrm{2}}$ yield $\mathit{\phi }$ and recommended lower values than previously used in GEOS-Chem by Wang et al. (2019) to account for the effect of organic coating of particles. We previously implemented this update in Wang et al. (2020), and it is now part of GEOS-Chem version 12.9.

We update the previous GEOS-Chem representation of $\mathrm{IBr}$ and $\mathrm{ICl}$ formation from uptake of iodine species on sea salt aerosols (Sherwen et al., 2016a) to conserve mass and be consistent with analogous reactions for uptake of bromine and chlorine: $$\begin{array}{}\text{R10}& {\displaystyle }\begin{array}{rl}& {\mathrm{INO}}_{\mathrm{3}}+\mathrm{0.85}{\mathrm{Cl}}^{-}+\mathrm{0.15}{\mathrm{Br}}^{-}+{\mathrm{H}}^{+}\\ & \to \mathrm{0.85}\mathrm{ICl}+\mathrm{0.15}\mathrm{IBr}+{\mathrm{HNO}}_{\mathrm{3}}\end{array}\text{R11}& {\displaystyle }\begin{array}{rl}& {\mathrm{INO}}_{\mathrm{2}}+\mathrm{0.85}{\mathrm{Cl}}^{-}+\mathrm{0.15}{\mathrm{Br}}^{-}+{\mathrm{H}}^{+}\\ & \to \mathrm{0.85}\mathrm{ICl}+\mathrm{0.15}\mathrm{IBr}+{\mathrm{HNO}}_{\mathrm{2}}\end{array}\text{R12}& {\displaystyle }\begin{array}{rl}& \mathrm{HOI}+\mathrm{0.85}{\mathrm{Cl}}^{-}+\mathrm{0.15}{\mathrm{Br}}^{-}+{\mathrm{H}}^{+}\\ & \to \mathrm{0.85}\mathrm{ICl}+\mathrm{0.15}\mathrm{IBr}+{\mathrm{H}}_{\mathrm{2}}\mathrm{O}\end{array}\text{R13}& {\displaystyle }{\mathrm{INO}}_{\mathrm{3}}+{\mathrm{H}}_{\mathrm{2}}\mathrm{O}\to \mathrm{HOI}+{\mathrm{HNO}}_{\mathrm{3}}.\end{array}$$

Reaction rates are calculated using reactive uptake coefficients $\mathit{\gamma }$ for ${\mathrm{INO}}_{\mathrm{3}}$, ${\mathrm{INO}}_{\mathrm{2}}$, and $\mathrm{HOI}$ as given by Sherwen et al. (2016a), with Reactions (R10)–(R12) taking place in acidic aerosols and Reaction (R13) taking place in alkaline aerosols.

Heterogeneous halogen reactions on ice crystals${}^{\mathrm{a}}$.

${}^{\mathrm{a}}$ Formulations for the reactive uptake coefficient $\mathit{\gamma }$ are from IUPAC (Cowley et al., 2010). [ ]${}_{\mathrm{g}}$ denotes gas-phase concentration in units of $\mathrm{molecules}{\mathrm{cm}}^{-\mathrm{3}}$ of air; ${\mathit{\gamma }}_{\text{gs}}$ is the elementary reaction probability for a gas-phase molecule colliding with the ice surface; $\mathit{\theta }$ is the fractional coverage of a gas species on the ice surface. $K_{\text{LangC}}$ is a partition coefficient in units of cubic centimeters per molecule. $K_{\text{LinC}}$ is a partition coefficient in units of $\mathrm{molecules}{\mathrm{cm}}^{-\mathrm{2}}/\mathrm{molecules}{\mathrm{cm}}^{-\mathrm{3}}$. $T$ is air temperature in kelvin. $N_{max}$ denotes the maximum number of available surface sites for a gas species per cubic centimeter of ice surface; $c$ is the average gas-phase thermal velocity for the reactant; $\mathit{\theta }$, $K_{\text{LangC}}$, $K_{\text{LinC}}$, and $N_{max}$ for each species are calculated using the same method throughout the table. Reactions (R14) and (R15) compete with each other; Reactions R18, R19, and R20 compete with each other; these competitions use branching ratios determined by the relative rates.

Additional updates to the GEOS-Chem halogen mechanism in version 12.9 include a new scheme to calculate the reactive uptake coefficients $\mathit{\gamma }$ on ice crystals following recommendations by the International Union of Pure and Applied Chemistry (IUPAC) (Crowley et al., 2010) as listed in Table 3. We calculate the effective radius of ice crystals based on air temperature following Heymsfield et al. (2014) and Holmes et al. (2019) and increase the resulting surface area by a factor of 2.25 to account for irregular shape (Schmitt and Heymsfield, 2005). We also update ${\mathrm{BrNO}}_{\mathrm{3}}$ hydrolysis to include the temperature dependence of $\mathrm{\Gamma }$ (in Eq. 1) from Deiber et al. (2004): 5$$\mathrm{\Gamma }=\mathrm{0.0021}T-\mathrm{0.561},$$ where $T$ is air temperature in kelvin.

Figure 1

(a) Global budget and cycling of tropospheric inorganic chlorine (${\mathrm{Cl}}_{\mathit{\text{y}}}$) in GEOS-Chem. Read 1.0(4) as 1.0 $\times$ 10${}^{\mathrm{4}}$. Reactions producing Cl atoms are in red. Heterogeneous reactions are in green. The dotted box indicates the ${\mathrm{Cl}}_{\mathit{\text{y}}}$ family, and arrows into and out of that box represent general sources and sinks of ${\mathrm{Cl}}_{\mathit{\text{y}}}$. Reactions with a rate of $<$ 100 $\mathrm{Gg}\mathrm{Cl}{\mathrm{a}}^{-\mathrm{1}}$ are not shown. ${\mathrm{ClO}}^{\ast }$ stands for ClO $+$ OClO $+$ ${\mathrm{ClO}}_{\mathrm{2}}$ $+$ 2${\mathrm{Cl}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{2}}$; most ${\mathrm{ClO}}^{\ast }$ is present as ClO. The super-fast Cl–ClOO cycling is not included as it does not affect the Cl atom concentration. (b) Same as (a) but for tropospheric inorganic bromine (${\mathrm{Br}}_{\mathit{\text{y}}}$). (c) Same as (a) but for tropospheric inorganic iodine (${\mathrm{I}}_{\mathit{\text{y}}}$). ${\mathrm{IO}}^{\ast }$ stands for $\mathrm{IO}$ $+$ $\mathrm{OIO}$ $+$ 2${\mathrm{I}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{2}}$ $+$ 2${\mathrm{I}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{3}}$ $+$ 2${\mathrm{I}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{4}}$.

[Figure omitted. See PDF]

Figure 2

Global distribution of annual mean GEOS-Chem number densities of Cl atoms and mixing ratios of $\mathrm{BrO}$ and IO. Panels (a–c) show surface air values, and panels (d–f) show zonal means as a function of latitude and altitude. Dashed lines indicate the tropopause.

[Figure omitted. See PDF]

Figure 3

Global annual mean vertical speciation in GEOS-Chem of reactive chlorine (${\mathrm{Cl}}^{\ast }$ $\equiv$ ${\mathrm{Cl}}_{\mathit{\text{y}}}$ $-$ $\mathrm{HCl}$), gaseous inorganic bromine (${\mathrm{Br}}_{\mathit{\text{y}}}$), and gaseous inorganic iodine (${\mathrm{I}}_{\mathit{\text{y}}}$; right).

[Figure omitted. See PDF]

Figure 1 shows the global budgets and cycling of tropospheric inorganic chlorine (Fig. 1a), bromine (Fig. 1b), and iodine (Fig. 1c) in our model simulation. Figure 2 shows the annual mean global distributions of Cl atoms, $\mathrm{BrO}$, and IO. Figure 3 shows the global mean vertical distribution of the halogen speciation for reactive chlorine (${\mathrm{Cl}}^{\ast }$ $\equiv$ ${\mathrm{Cl}}_{\mathit{\text{y}}}$ $-$ $\mathrm{HCl}$), ${\mathrm{Br}}_{\mathit{\text{y}}}$, and ${\mathrm{I}}_{\mathit{\text{y}}}$. GEOS-Chem is driven here by 2016 GEOS-FP (forward processing) assimilated meteorological fields from the NASA Global Modeling and Assimilation Office (GMAO) with native horizontal resolution of 0.25${}^{\circ }$ $\times$ 0.3125${}^{\circ }$ and 72 vertical levels from the surface to the mesosphere. Our model simulation is conducted at 4${}^{\circ }$ $\times$ 5${}^{\circ }$ horizontal resolution, and meteorological fields are conservatively degraded to that resolution. The simulation is conducted for 2 years (2015–2016), with the first year as spin-up for initialization.

3.1 Chlorine

The dominant global source of ${\mathrm{Cl}}_{\mathit{\text{y}}}$ is acid displacement from SSA to $\mathrm{HCl}$. The global rate of $\mathrm{HCl}$ generation from acid displacement is 46 $\mathrm{Tg}\mathrm{Cl}{\mathrm{a}}^{-\mathrm{1}}$ and close to the observationally based estimate of 50 $\mathrm{Tg}\mathrm{Cl}{\mathrm{a}}^{-\mathrm{1}}$ by Graedel and Keene (1995). $\mathrm{HCl}$ is the largest reservoir of tropospheric ${\mathrm{Cl}}_{\mathit{\text{y}}}$, with a global mean tropospheric mixing ratio of 45 $\mathrm{ppt}$ (parts per trillion). Most $\mathrm{HCl}$ is removed by deposition, and only a small fraction (7.3 $\mathrm{Tg}\mathrm{Cl}{\mathrm{a}}^{-\mathrm{1}}$) reacts with OH and contributes to reactive chlorine ${\mathrm{Cl}}^{\ast }$. ${\mathrm{Cl}}^{\ast }$ can also be generated from ${\mathrm{Cl}}^{-}$ and dissolved $\mathrm{HCl}$ in clouds and aerosols by heterogeneous reactions with principal contributions from $\mathrm{HOBr}$ $+$ ${\mathrm{Cl}}^{-}$ (2.6 $\mathrm{Tg}\mathrm{Cl}{\mathrm{a}}^{-\mathrm{1}}$), HOCl $+$ ${\mathrm{Cl}}^{-}$ (1.5 $\mathrm{Tg}\mathrm{Cl}{\mathrm{a}}^{-\mathrm{1}}$), $\mathrm{HOI}$/I${\mathrm{NO}}_{\mathit{\text{x}}}$ $+$ ${\mathrm{Cl}}^{-}$ (0.8 $\mathrm{Tg}\mathrm{Cl}{\mathrm{a}}^{-\mathrm{1}}$), and ${\mathrm{N}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{5}}$ $+$ ${\mathrm{Cl}}^{-}$ (0.68 $\mathrm{Tg}\mathrm{Cl}{\mathrm{a}}^{-\mathrm{1}}$). This heterogeneous source of 6.3 $\mathrm{Tg}\mathrm{Cl}{\mathrm{a}}^{-\mathrm{1}}$ is lower than our previous estimate of 12 $\mathrm{Tg}\mathrm{Cl}{\mathrm{a}}^{-\mathrm{1}}$ in Wang et al. (2019) since the updated mechanisms for $\mathrm{HOBr}$ $+$ ${\mathrm{Cl}}^{-}$ (Sect. 2.3) and ${\mathrm{N}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{5}}$ $+$ ${\mathrm{Cl}}^{-}$ (Sect. 2.4 and Wang et al., 2020) reactions are slower. We calculate a tropospheric lifetime of 2.3 h for ${\mathrm{Cl}}^{\ast }$. Loss of ${\mathrm{Cl}}^{\ast }$ is mainly through the reaction of Cl with methane (44 %) and other organic compounds.

Distributions of ${\mathrm{Cl}}^{\ast }$ in the troposphere are generally similar to Wang et al. (2019). As shown in Fig. 2, tropospheric Cl atom concentrations are highest at the surface, reflecting the source from SSA (Fig. S1 in the Supplement), and in the upper troposphere due to transport from the stratosphere as well as cold temperature slowing down the Cl $+$ methane reaction. In surface air, simulated Cl atom concentrations are usually highest along polluted coastlines, where the large sources of ${\mathrm{HNO}}_{\mathrm{3}}$, ${\mathrm{H}}_{\mathrm{2}}{\mathrm{SO}}_{\mathrm{4}}$, and ${\mathrm{N}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{5}}$ from anthropogenic emissions drive acid displacement and ${\mathrm{ClNO}}_{\mathrm{2}}$ production. Figure 3 shows the global mean vertical distribution of ${\mathrm{Cl}}^{\ast }$ species. Boundary layer ${\mathrm{Cl}}^{\ast }$ is dominated on a zonal mean basis by ${\mathrm{ClNO}}_{\mathrm{2}}$ formed from ${\mathrm{N}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{5}}$ $+$ ${\mathrm{Cl}}^{-}$ in polluted air. High mixing ratios of Cl${\mathrm{NO}}_{\mathrm{3}}$ in the upper troposphere are related to transport from the stratosphere and its slow hydrolysis. The $\mathrm{BrCl}$ mixing ratio is much lower than in the previous GEOS-Chem studies of Sherwen et al. (2016b) and of Zhu et al. (2019) (who reported a tropospheric mean mixing ratio of 0.69 $\mathrm{ppt}$) because of slower update kinetics of $\mathrm{HOBr}$ in aerosol and cloud water.

3.2 Bromine

The largest source of ${\mathrm{Br}}_{\mathit{\text{y}}}$ is from SSA debromination in the marine boundary layer (MBL), mainly contributed by $\mathrm{HOBr}$ $+$ ${\mathrm{Br}}^{-}$ and ${\mathrm{O}}_{\mathrm{3}}$ $+$ ${\mathrm{Br}}^{-}$ producing ${\mathrm{Br}}_{\mathrm{2}}$ and $\mathrm{HOBr}$, respectively. Bromocarbon photochemistry dominates the source of ${\mathrm{Br}}_{\mathit{\text{y}}}$ in the free troposphere. Uptake of $\mathrm{HBr}$ by SSA is the major sink of ${\mathrm{Br}}_{\mathit{\text{y}}}$. The global tropospheric loading of $\mathrm{BrO}$ in the model is 2.1 $\mathrm{Gg}\mathrm{Br}$, corresponding to a mean tropospheric mixing ratio of 0.19 $\mathrm{ppt}$ (0.38 $\mathrm{ppt}$ in daytime). This value is much lower than the most recent GEOS-Chem estimate of 8.0 $\mathrm{Gg}$ by Zhu et al. (2019) because of the updated $\mathrm{HOBr}$ heterogeneous chemistry described in Sect. 2.3. The newly added pH dependences in Table 2 decrease the rate of Reaction (R5), resulting in much slower recycling of $\mathrm{HOBr}$ in cloud and aerosol water. $\mathrm{HOBr}$ is now more likely to react with $\mathrm{S}\left(\mathrm{IV}\right)$ via Reactions (R3) and (R4) than previously, forming $\mathrm{HBr}$, which then gets taken up by SSA. In Zhu et al. (2019), 82 % of $\mathrm{HOBr}$ heterogeneous reactions were with ${\mathrm{Br}}^{-}$ and ${\mathrm{Cl}}^{-}$, and only 18 % were with $\mathrm{S}\left(\mathrm{IV}\right)$. Due to the update in Sect. 2.3, 59 % of $\mathrm{HOBr}$ heterogeneous reactions are with ${\mathrm{Br}}^{-}$ and ${\mathrm{Cl}}^{-}$, and 41 % are with $\mathrm{S}\left(\mathrm{IV}\right)$. The higher fraction of ${\mathrm{Br}}_{\mathit{\text{y}}}$ in the form of $\mathrm{HBr}$ decreases the tropospheric lifetime of ${\mathrm{Br}}_{\mathit{\text{y}}}$ because $\mathrm{HBr}$ is more water-soluble than other ${\mathrm{Br}}_{\mathit{\text{y}}}$ species. We calculate tropospheric lifetimes of 7.9 h for ${\mathrm{Br}}_{\mathit{\text{y}}}$ and 6.8 min for $\mathrm{BrO}$${}_x$ ($\equiv$ Br $+$ $\mathrm{BrO}$).

Distributions of $\mathrm{BrO}$ in Fig. 2 are similar to Zhu et al. (2019) except for lower mixing ratios. High surface $\mathrm{BrO}$ mixing ratios are usually associated with high SSA (Fig. S1). $\mathrm{BrO}$ mixing ratios are low over the Southern Ocean despite high SSA emission because SSA alkalinity is not completely depleted, and hence reaction (R5) is ineffective. $\mathrm{BrO}$ decreases from the surface to the middle troposphere, reflecting the SSA source, and then increases in the upper troposphere because of efficient heterogeneous recycling of $\mathrm{HBr}$ in ice clouds (Table 3). Figure 3 shows the global mean vertical distribution of ${\mathrm{Br}}_{\mathit{\text{y}}}$ species, which is very different from Sherwen et al. (2016b), where the ${\mathrm{Br}}_{\mathit{\text{y}}}$ concentration increased with altitude. This is due to the inclusion of SSA debromination in our simulation. Our ${\mathrm{Br}}_{\mathit{\text{y}}}$ mixing ratio in the MBL is still only slightly higher than that in Sherwen et al. (2016b) because of the much lower ${\mathrm{Br}}_{\mathit{\text{y}}}$ lifetime, resulting from the slower $\mathrm{HOBr}$ heterogeneous reactions, as mentioned above.

Figure 4

Annual mean bromine enrichment factor (EF) of sea salt aerosol (SSA) in surface air. GEOS-Chem model results for total SSA (contours) are compared to observations (circles). We sum [${\mathrm{Br}}^{-}$] and [SSA] from both fine and coarse SSA and use Eq. (6) to calculate the EF.

[Figure omitted. See PDF]

The ${\mathrm{I}}_{\mathit{\text{y}}}$ source totals 2.7 $\mathrm{Tg}\mathrm{I}{\mathrm{a}}^{-\mathrm{1}}$, with most (2.1 $\mathrm{Tg}\mathrm{I}{\mathrm{a}}^{-\mathrm{1}}$) originating from ocean volatilization of $\mathrm{HOI}$ and ${\mathrm{I}}_{\mathrm{2}}$ (Carpenter et al., 2013; MacDonald et al., 2014). The sink of ${\mathrm{I}}_{\mathit{\text{y}}}$ is from deposition (1.8 $\mathrm{Tg}\mathrm{I}{\mathrm{a}}^{-\mathrm{1}}$) and uptake by aerosols (0.91 $\mathrm{Tg}\mathrm{I}{\mathrm{a}}^{-\mathrm{1}}$). The global tropospheric loading of IO in the model is 1.4 $\mathrm{Gg}\mathrm{I}$, corresponding to a mean tropospheric mixing ratio of 0.08 $\mathrm{ppt}$. As shown in Figs. 2 and 3, concentrations of all ${\mathrm{I}}_{\mathit{\text{y}}}$ species are highest in the MBL, consistent with the dominant emission from the ocean. Surface IO mixing ratios are highest over tropical oceans, where both organic and inorganic iodine emissions are high due to the high temperature. Concentrations of IO and most ${\mathrm{I}}_{\mathit{\text{y}}}$ species are the lowest in the middle troposphere, where ${\mathrm{I}}_{\mathit{\text{y}}}$ speciation is mostly as $\mathrm{HOI}$, which can be removed via wet deposition efficiently. We calculate tropospheric lifetimes of 1.6 $\mathrm{d}$ for ${\mathrm{I}}_{\mathit{\text{y}}}$ and 1.7 min for I $+$ IO* ($\equiv$ IO $+$ OIO $+$ 2${\mathrm{I}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{2}}$ $+$ 2${\mathrm{I}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{3}}$ $+$ 2${\mathrm{I}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{4}}$). Our results are consistent with Sherwen et al. (2016b) since the iodine chemistry is largely unchanged. Our only significant update has been to conserve mass in iodine heterogeneous reactions (Text S2 in the Supplement), but this has little impact.

4 Comparison to observations

Here we compare the model simulation for 2016 to observations for gas-phase halogen species collected from surface and aircraft campaigns. The observations are in different years, but we assume that interannual variability is small compared to other sources of error. More extensive evaluations of previous model versions with observations for organohalogens, $\mathrm{HCl}$–${\mathrm{Cl}}^{-}$ acid displacement, and iodine species can be found in Sherwen et al. (2016b), Wang et al. (2019), and Sherwen et al. (2016a), respectively, and our model results are not significantly different for purpose of these comparisons.

4.1 Bromine enrichment factors (EFs)

The bromine enrichment factor (EF) is a measure of SSA debromination, which can be calculated in the model as

5$$\text{EF}={\displaystyle \frac{\left(\right[{\mathrm{Br}}^{-}]/[\mathrm{SSA}]{)}_{\text{atmosphere}}}{\left(\right[{\mathrm{Br}}^{-}]/[\mathrm{SSA}]{)}_{\text{emission}}}}.$$

Figure 5

Daytime surface air mixing ratios of $\mathrm{BrO}$ from island sites and ocean cruises, arranged from left to right in order of decreasing latitude. Observed values (black) are means for the reporting period in different years. Open bars show the measurement detection limit and indicate that the observation is below detection limit. Model values (red) are monthly mean values in 2016 taken for the same month and location as the observations. References: (1) Saiz-Lopez et al. (2004, 2006), (2) Keene et al. (2007), (3, 5, 6) Sander et al. (2003), (4, 11) Leser et al. (2003), Martin et al. (2009), (7) Read et al. (2008), Mahajan et al. (2010), (8, 9) Volkamer et al. (2010), (10) Volkamer et al. (2015).

[Figure omitted. See PDF]

Figure 4 shows the annual mean EFs in surface air in GEOS-Chem. The high values (EF $>$ 1) indicate a more important role of $\mathrm{HBr}$ uptake than SSA debromination. EF is especially high over continental regions because ${\mathrm{Br}}_{\mathit{\text{y}}}$ volatilized from SSA is then transported inland and taken up by continental aerosols. Measured annual mean observations at 10 surface sites from Sander et al. (2003) and from Newberg et al. (2005) are also shown in Fig. 4. The mean GEOS-Chem EF averaged over these sites is 0.88, higher than in Zhu et al. (2019) (0.75). This is due to the updated reactive uptake of $\mathrm{HOBr}$ in Sect. 2.2, which results in less efficient mobilization of bromine radicals from SSA. The mean observed EF is 0.57. The model bias is mainly due to the underestimates over the Southern Ocean. Zhu et al. (2019) suggested that this may be due to excessive model uptake of $\mathrm{HBr}$ by SSA in summer. Free-tropospheric transport of bromine released from SSA (Wang et al., 2015) is estimated conservatively in GEOS-Chem as the updated $\mathrm{HOBr}$ reactive uptake may potentially lead to overestimation of bromine washout during deep convection.

Figure 6

Median vertical profiles of $\mathrm{BrO}$ mixing ratios from the CONTRAST (January–February 2014 over the western tropical Pacific), CAST (January–February 2014 over the western tropical Pacific), TORERO (January–February 2012 over the eastern tropical Pacific), ATom-3 (September–October 2017 over the Pacific and Atlantic), and ATom-4 (April–May 2018 over the Pacific and Atlantic) campaigns. Observations are shown as medians in 1 km vertical bins. Model values are shown as medians sampled along the flight tracks. There are two independent CONTRAST $\mathrm{BrO}$ data sets. The solid black line shows the chemical ionization mass spectrometer (CIMS) data from Chen et al. (2016). The dashed black line shows the differential optical absorption spectroscopy (DOAS) data from Koenig et al. (2017). The solid and dashed red lines show model values sampled along the flight tracks at the time of the available CIMS and DOAS observations, respectively.

[Figure omitted. See PDF]

Summary of aircraft measurements.

${}^{\mathrm{a}}$ CIMS: chemical ionization mass spectrometer; ${}^{\mathrm{b}}$ DOAS: differential optical absorption spectroscopy; ${}^{\mathrm{c}}$ for 60 s data; ${}^{\mathrm{d}}$ for 30 s data; ${}^{\mathrm{e}}$ for 1 s data. ${}^{\mathrm{f}}$ References: (1) Chen et al. (2016), (2) Koenig et al. (2017), (3) Le Breton et al. (2017), (4) Dix et al. (2016), (5) Veres et al. (2019), (6) Lee et al. (2018).

Bromine monoxide ($\mathrm{BrO}$)

Figure 5 compares surface measurements of $\mathrm{BrO}$ concentrations in marine air during daytime with corresponding model values. The model is generally consistent with these observations in showing surface air $\mathrm{BrO}$ mixing ratios in the range of 0–3 $\mathrm{ppt}$. $\mathrm{BrO}$ over the tropical North Atlantic is higher (1–3 $\mathrm{ppt}$) than other oceans ($<$ 1 $\mathrm{ppt}$ and below measurement detection limits) in both the model and observations. In the model this is due to high SSA emissions and efficient acidification of SSA from continental outflow of ${\mathrm{HNO}}_{\mathrm{3}}$ and ${\mathrm{SO}}_{\mathrm{2}}$, resulting in rapid debromination. Figure 6 compares modeled vertical profiles with aircraft $\mathrm{BrO}$ observations over the tropics from the CONTRAST (Chen et al., 2016; Koenig et al., 2017), CAST (Le Breton et al., 2017), TORERO (Volkamer et al., 2015), and ATom (Wofsy and ATom Science Team, 2018; Veres et al., 2019) aircraft campaigns. Details of the instruments and uncertainty in these observations are listed in Table 4. The median profiles of $\mathrm{BrO}$ measured by CIMS during CONTRAST, CAST, and ATom are all around or below their detection limits. In contrast, observations during CONTRAST and TORERO measured by DOAS show higher $\mathrm{BrO}$ mixing ratios ($>$ 1 $\mathrm{ppt}$). There are two independent $\mathrm{BrO}$ measurements during CONTRAST. The DOAS measurement by Koenig et al. (2017) consists of portions of five flights during CONTRAST and shows higher values than the CIMS measurement by Chen et al. (2016). The model provides a reasonable fit to CONTRAST CIMS $\mathrm{BrO}$, with a mean bias of 0.03 $\mathrm{ppt}$, but is low compared to the DOAS observations. Observed $\mathrm{BrO}$ mixing ratios are low almost everywhere during the ATom campaign and show no obvious vertical variation from MBL to the free troposphere. Modeled $\mathrm{BrO}$ is generally consistent with ATom observations in the lower troposphere but is much higher in the upper troposphere, where transport from the stratosphere becomes important in the model. On the other hand, the model is lower than the TORERO observations in the upper troposphere. The higher $\mathrm{BrO}$ mixing ratios in the lowermost stratosphere in the model during ATom and in both model and observations during TORERO are consistent with balloon-borne measurements at 45${}^{\circ }$ N by Stachnik et al. (2013), showing 5 $\mathrm{ppt}$ $\mathrm{BrO}$ at 15 $\mathrm{km}$ altitude, but the lower $\mathrm{BrO}$ mixing ratios in the observations during ATom and in both model and observations during CONTRAST CIMS are consistent with aircraft measurements over the eastern Pacific by Werner et al. (2017), showing $<$ 1 $\mathrm{ppt}$ at 12–15 $\mathrm{km}$ altitudes.

To summarize, there is much ambiguity in the comparisons of model results to observed $\mathrm{BrO}$ concentrations, as might be expected since most observations are near their detection limits and with large uncertainties (Table 4). There is no evidence of systematic model bias, but more sensitive observations would be needed to be conclusive.

Figure 7

Surface air mixing ratios of $\mathrm{HCl}$ at coastal and island sites and from ocean cruises, arranged from left to right in order of decreasing latitude. Observations (black) are means or medians depending on availability from the publications. Model values (red) are monthly mean values in 2016 taken for the same month and location as the observations. References: (1, 5, 8, 9) Keene et al. (2009), (2) Keene et al. (2007), (3) Crisp et al. (2014), (4) Dasgupta et al. (2007), (6) Sander et al. (2013), (7) Sanhueza and Garaboto (2002).

[Figure omitted. See PDF]

Figure 8

Surface air mixing ratios of ${\mathrm{ClNO}}_{\mathrm{2}}$ at coastal and island sites, arranged from left to right in order of decreasing latitude. Observed (black) and modeled (red) values are maxima for the reporting period. Model maxima are based on hourly values sampled at the same location and time period as the observations. References: (1) Priestley et al. (2018), (2, 4, 6) Sommariva et al. (2018), (3, 5) Bannan et al. (2017), (7) Phillips et al. (2012), (8) Kercher et al. (2009), (9, 10) Jeong et al. (2018), (11) Mielke et al. (2013), (12) Riedel et al. (2013), (13) Kim et al. (2014), (14) Osthoff et al. (2008), (15) Faxon et al. (2015).

[Figure omitted. See PDF]

Inorganic chlorine gases (${\mathrm{Cl}}_{\mathit{\text{y}}}$)

Our model does not include anthropogenic inorganic chlorine sources, which could however be important in polluted continental boundary layer regions as seen in atmospheric observations (Wang et al., 2016; Tham et al., 2016; Lee et al., 2018; Zhou et al.,2018; Yun et al., 2018; Peng et al., 2020; Thornton et al., 2010; Wang et al., 2020; Gunthe et al., 2021). Here we focus on a more global perspective. Figure 7 compares modeled surface $\mathrm{HCl}$ mixing ratios to observations at coastal sites and over oceans. The model captures the spatial variability in the $\mathrm{HCl}$ mixing ratios across locations, which largely reflects the strong acid displacement at northern midlatitudes. As previously shown by Wang et al. (2019), acid displacement is key to reproducing the observations. Figure 8 compares surface modeled maximum ${\mathrm{ClNO}}_{\mathrm{2}}$ to observations in island and coastal environments. Observations of ${\mathrm{ClNO}}_{\mathrm{2}}$ are usually reported as maxima instead of means and are made in nighttime urban environments, which are difficult to compare to our global model because of the coarse grid resolution and nighttime stratification of the surface layer. Despite these drawbacks, the model still offers a credible simulation of the 24 h maximum ${\mathrm{ClNO}}_{\mathrm{2}}$.

Figure 9

Vertical profiles of $\mathrm{HCl}$, HOCl, ${\mathrm{Cl}}_{\mathrm{2}}$ and nighttime ${\mathrm{ClNO}}_{\mathrm{2}}$ mixing ratios during the WINTER campaign over the eastern US and offshore in February–March 2015. Observations are shown as individual 1 $\min$ data points, with medians and 25th–75th percentiles in 500 $\mathrm{m}$ vertical bins. ${\mathrm{ClNO}}_{\mathrm{2}}$ data exclude during the daytime (10:00–16:00 LT), when mixing ratios are near zero in both the observations and the model. Model values are shown as medians sampled along the flight tracks.

[Figure omitted. See PDF]

The WINTER aircraft campaign provided data for multiple ${\mathrm{Cl}}_{\mathit{\text{y}}}$ gases including $\mathrm{HCl}$, ${\mathrm{ClNO}}_{\mathrm{2}}$, HOCl, and ${\mathrm{Cl}}_{\mathrm{2}}$. The measurements were made over the eastern US and offshore during February–March 2015 by CIMS (Lee et al., 2018), as summarized in Table 4. Figure 9 compares the observed median vertical profiles of $\mathrm{HCl}$, ${\mathrm{ClNO}}_{\mathrm{2}}$, HOCl, and ${\mathrm{Cl}}_{\mathrm{2}}$ during WINTER to the model sampled along the flight tracks for the corresponding period. Modeled $\mathrm{HCl}$ is lower than the observations but mostly within the calibration uncertainty ($\pm$ 30 %). Modeled HOCl largely underestimates WINTER observations. Wang et al. (2019) found that such underestimation is over both land and ocean and mainly in daytime, when HOCl has a very short lifetime against photolysis (a few minutes). This may suggest a large photochemical source needed to decrease the model bias. Recent work also identified the potential of ${\mathrm{IO}}_{\mathit{\text{x}}}$ ion chemistry to lead to measurement interferences (Dörich et al., 2021) and of the detection of acid gases, which could impact the measured $\mathrm{HOCl}:\mathrm{HCl}$ ratio. Furthermore, rapid interconversion of halogen species on inlet walls has been reported that could also impact the measured $\mathrm{HOCl}:\mathrm{HCl}$ ratio (Neuman et al., 2010).

Figure 10

(a) Vertical profiles of $\mathrm{BrCl}$, ${\mathrm{Cl}}_{\mathrm{2}}$, and ${\mathrm{ClNO}}_{\mathrm{2}}$ mixing ratios from the ATom-3 campaign over the Pacific and Atlantic in September–October 2017. Observations are medians and 25th–75th percentiles in 1 $\mathrm{km}$ vertical bins. Model values are medians sampled along the flight tracks. (b) Same as Fig. 10a but for the Atom-4 campaign in April–May 2018.

[Figure omitted. See PDF]

Figure 10 compares modeled vertical $\mathrm{BrCl}$, ${\mathrm{Cl}}_{\mathrm{2}}$, and ${\mathrm{ClNO}}_{\mathrm{2}}$ mixing ratios to observations during the ATom aircraft campaigns. Both modeled and observed chlorine gases are low in most regions ($<$ 1 $\mathrm{ppt}$). Most ATom measurements were made in daytime, when modeled $\mathrm{BrCl}$, ${\mathrm{Cl}}_{\mathrm{2}}$, and ${\mathrm{ClNO}}_{\mathrm{2}}$ are close to zero due to their very short lifetimes against photolysis. Modeled $\mathrm{BrCl}$ and ${\mathrm{Cl}}_{\mathrm{2}}$ underestimate observed values, especially in the lower troposphere. The observed median mixing ratios of all these species at all altitudes are either below or around the measurement detection limits (Table 4). The underestimates of HOCl during WINTER and of $\mathrm{BrCl}$ and ${\mathrm{Cl}}_{\mathrm{2}}$ during ATom during the daytime may suggest a large photochemical source that can produce chlorine radicals from ${\mathrm{Cl}}^{-}$.

Figure 11

Daytime surface air mixing ratios of IO from island sites and ocean cruises, arranged from left to right in order of decreasing latitude. Observed values (black) are means for the reporting period in different years. Model values (red) are monthly mean values in 2016 taken for the same month and location as the observations. References: (1, 4, 9, 12) Mahajan et al. (2012), (2, 7, 10) Großmann et al. (2013), (3) Mahajan et al. (2010), (5) Volkamer et al. (2015), (6) Prados-Roman et al. (2015), (8) Gómez Martín et al. (2013).

[Figure omitted. See PDF]

Figure 12

Median vertical profile of IO mixing ratios from the TORERO (January–February 2012 over the eastern tropical Pacific) campaign. Observations are shown as individual 1 $\min$ data points, with medians and 25th–75th percentiles in 1 $\mathrm{km}$ vertical bins. Model values are shown as medians sampled along the flight tracks.

[Figure omitted. See PDF]

Figure 11 compares surface measurements of IO over islands and oceans during daytime with corresponding model values. The model is generally consistent with these measurements, with an overall bias of $-$10 %. Both modeled and observed IO mixing ratios are highest over tropical oceans and lowest at high latitudes, reflecting the distribution of both organic and inorganic iodine emissions. Figure 12 compares modeled vertical profiles with aircraft IO observations over the eastern Pacific from TORERO (Volkamer et al., 2015). The model is in general agreement with the observations and able to reproduce the observed vertical variation with a mean bias of $-$0.09 $\mathrm{ppt}$. Both observed and modeled IO mixing ratios are high in the MBL, reflecting the marine sources of iodine, and vary little in the free troposphere. Recently, Koenig et al. (2020) reported IO and ${\mathrm{I}}_{\mathit{\text{y}}}$ mixing ratios of 0.08 and 0.53 $\mathrm{ppt}$ at 12 $\mathrm{km}$ during the CONTRAST campaign over the western tropical Pacific. Our modeled values are 0.07 and 0.43 $\mathrm{ppt}$ for IO and ${\mathrm{I}}_{\mathit{\text{y}}}$, respectively, at that location.

5 Global implications for tropospheric oxidant chemistry

We now examine the implications of tropospheric halogen chemistry as described by our mechanism for the concentrations of tropospheric VOCs, ozone, ${\mathrm{NO}}_{\mathit{\text{x}}}$, and OH. Shah et al. (2021) examined the implications for mercury chemistry.

5.1 Volatile organic compounds (VOCs)

Cl atoms are strong VOC oxidants, but their importance is limited by their small supply. The global mean tropospheric Cl atom concentration in our model is 630 ${\mathrm{cm}}^{-\mathrm{3}}$, consistent with the upper limit of 1000 ${\mathrm{cm}}^{-\mathrm{3}}$ inferred by Singh et al. (1996) from global modeling of ${\mathrm{C}}_{\mathrm{2}}{\mathrm{Cl}}_{\mathrm{4}}$ observations. Within the MBL, the global mean concentration is 840 ${\mathrm{cm}}^{-\mathrm{3}}$, similar to a recent estimate using isotopic observations of methane and CO by Gromov et al. (2018) (900 ${\mathrm{cm}}^{-\mathrm{3}}$). Oxidation by Cl atoms in the troposphere drives a loss rate of 3.6 $\mathrm{Tg}{\mathrm{a}}^{-\mathrm{1}}$ for methane in our model, contributing 0.8 % of the total methane chemical loss. It additionally contributes 14 % of the global chemical loss for ethane, 8 % for propane, and 7 % for higher alkanes. These impacts could be higher if anthropogenic chlorine sources were considered. Oxidation of VOCs by Br atoms in GEOS-Chem is significant only for acetaldehyde, where it accounts for 2.0 % of the global loss and up to 18 % of the loss in the MBL of high-SSA regions (tropical oceans, North Atlantic). Badia et al. (2019) previously estimated a 9 % contribution of Br atoms to acetaldehyde oxidation in the tropospheric column over the eastern tropical Pacific.

Figure 13

Effects of halogen chemistry on tropospheric OH, ${\mathrm{NO}}_{\mathit{\text{x}}}$, and ozone concentrations. The figure shows differences in annual mean concentrations between the standard simulation and a sensitivity simulation removing all tropospheric halogen reactions. The panels (a–c) are for surface air, and the panels (d–f) are for zonal means as a function of latitude and latitude. Only tropospheric grid boxes are shown.

[Figure omitted. See PDF]

Ozone, ${\mathrm{NO}}_{\mathit{\text{x}}}$, and OH

Figure 13 shows the effects of halogen chemistry on tropospheric OH, ${\mathrm{NO}}_{\mathit{\text{x}}}$, and ozone concentrations, as obtained by difference with a sensitivity simulation excluding all halogen reactions in the troposphere (“no halogen”). Halogen chemistry decreases the global tropospheric ozone burden by 11 % in our model, which is smaller than the 18.6 % in Sherwen et al. (2016b). Global ozone chemical production decreases by 2 %, while ozone lifetime decreases by 10 %. The decrease in ozone production is due to a 5.6 % global decrease in ${\mathrm{NO}}_{\mathit{\text{x}}}$ as a result of formation and hydrolysis of halogen nitrates $X$${\mathrm{NO}}_{\mathrm{3}}$ ($X$ $\equiv$ Cl, Br, I): $$\begin{array}{}\text{R21}& {\displaystyle }X\mathrm{O}+{\mathrm{NO}}_{\mathrm{2}}+M\to X{\mathrm{NO}}_{\mathrm{3}}+M\text{R22}& {\displaystyle }X{\mathrm{NO}}_{\mathrm{3}}+{\mathrm{H}}_{\mathrm{2}}\mathrm{O}\to \mathrm{HO}X+{\mathrm{HNO}}_{\mathrm{3}}.\end{array}$$

Globally, such ${\mathrm{NO}}_{\mathit{\text{x}}}$ loss is mostly through Cl${\mathrm{NO}}_{\mathrm{3}}$ and ${\mathrm{BrNO}}_{\mathrm{3}}$ hydrolysis, with a negligible contribution from ${\mathrm{INO}}_{\mathrm{3}}$. As shown in Fig. 13, surface ${\mathrm{NO}}_{\mathit{\text{x}}}$ increases over the continents, and this is due to ${\mathrm{ClNO}}_{\mathrm{2}}$ chemistry. We previously showed in Wang et al. (2019) that ${\mathrm{Cl}}^{-}$ originating from SSA can be transported far inland by acid displacement of $\mathrm{HCl}$ and subsequent $\mathrm{HCl}$ uptake by sulfate–nitrate–ammonium (SNA) aerosols. ${\mathrm{Cl}}^{-}$ will then react with ${\mathrm{N}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{5}}$ over the continents via Reaction (R9) and form ${\mathrm{ClNO}}_{\mathrm{2}}$, resulting in longer ${\mathrm{NO}}_{\mathit{\text{x}}}$ lifetime. This increase in continental boundary layer ${\mathrm{NO}}_{\mathit{\text{x}}}$ would be further amplified by anthropogenic sources of ${\mathrm{Cl}}^{-}$. Halogen chemistry in our model lowers global tropospheric concentrations of OH and ${\mathrm{HO}}_{\mathrm{2}}$ by 4.1 % and 3.4 %, respectively. The decrease in OH is mainly due to the decrease in ozone, which reduces primary OH production from ozone by 9.8 %. The increase in OH over continental regions (Fig. 13) is due to ${\mathrm{ClNO}}_{\mathrm{2}}$ chemistry.

Global tropospheric ozone budget in GEOS-Chem${}^{\mathrm{a}}$.

${}^{\mathrm{a}}$ Annual mean budget for the odd oxygen family (${\mathrm{O}}_{\mathit{\text{x}}}$) and for the reservoirs (${\mathrm{O}}_{\mathit{\text{z}}}$) of the expanded odd oxygen family (${\mathrm{O}}_{\mathit{\text{y}}}$ $\equiv$ ${\mathrm{O}}_{\mathit{\text{x}}}$ $+$ ${\mathrm{O}}_{\mathit{\text{z}}}$). Here, ${\mathrm{O}}_{\mathit{\text{z}}}$ $\approx$ 0.5${\mathrm{HO}}_{\mathit{\text{y}}}$ accounts for the hydrogen oxide (${\mathrm{HO}}_{\mathit{\text{y}}}$ $\equiv$ $\mathrm{OH}$ $+$ peroxy radicals) and their reservoirs cycling with ozone. See the text in Sect. 5.2 and Bates and Jacob (2020) for details. All values are given in ozone equivalent mass. For the halogen crossover reactions where two different halogens are included (e.g.,  $\mathrm{ClO}$ $+$ $\mathrm{BrO}$), we split the ozone loss equally between the two halogens. ${}^{\mathrm{b}}$ As implemented in this work. ${}^{\mathrm{c}}$ Version 12.9 with no tropospheric halogen reactions. ${}^{\mathrm{d}}$ ${\mathrm{O}}_{\mathit{\text{x}}}$ production efficiency per unit ${\mathrm{O}}_{\mathit{\text{z}}}$; see Eq. (6) in the text for definition. ${}^{\mathrm{e}}$ See Eq. (7) in the text for definition.

Table 5 summarizes the global annual budget of tropospheric ozone in the standard model and in the no-halogen simulation. The budget of ozone is shown as that of odd oxygen (${\mathrm{O}}_{\mathit{\text{x}}}$ $\equiv$ ${\mathrm{O}}_{\mathrm{3}}$ $+$ $\mathrm{O}$ $+$ $\mathrm{O}{(}^{\mathrm{1}}\mathrm{D})$ $+$ ${\mathrm{NO}}_{\mathrm{2}}$ $+$ 2${\mathrm{NO}}_{\mathrm{3}}$ $+$ peroxyacyl nitrates $+$ ${\mathrm{HNO}}_{\mathrm{3}}$ $+$ ${\mathrm{HNO}}_{\mathrm{4}}$ $+$ 3${\mathrm{N}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{5}}$ $+$ organic nitrates $+$ Criegee intermediates $+$ $X$$\mathrm{O}$ $+$ $\mathrm{HO}$$X$ $+$ $X$${\mathrm{NO}}_{\mathrm{2}}$ $+$ 2$X$${\mathrm{NO}}_{\mathrm{3}}$ $+$ 2$\mathrm{OIO}$ $+$ 2${\mathrm{I}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{2}}$ $+$ 3${\mathrm{I}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{3}}$ $+$ 4${\mathrm{I}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{4}}$ $+$ 2${\mathrm{Cl}}_{\mathrm{2}}$O${}_{\mathrm{2}}$ $+$ 2$\mathrm{OClO}$, where $X$ $\equiv$ Cl, Br, I) to account for the rapid cycling between ${\mathrm{O}}_{\mathit{\text{x}}}$ species. The 10 % shorter ozone lifetime as a result of halogen chemistry is due to catalytic ozone loss cycles driven by iodine (7.6 %), bromine (2.6 %), and chlorine (0.3 %). Figure 14 shows the relative contributions of different reaction routes to ozone chemical loss in the troposphere. Halogens contribute about 19 % of ozone loss in the MBL, decreasing to 8 % at 2–4 $\mathrm{km}$ altitude and then increasing to 24 % in the upper troposphere. Halogen-catalyzed ozone loss is mainly driven by the sequence ($X$ $\equiv$ I, Br, Cl): $$\begin{array}{}\text{R23}& {\displaystyle }X+{\mathrm{O}}_{\mathrm{3}}\to X\mathrm{O}+{\mathrm{O}}_{\mathrm{2}}\text{R24}& {\displaystyle }X\mathrm{O}+{\mathrm{HO}}_{\mathrm{2}}\to \mathrm{HO}X+{\mathrm{O}}_{\mathrm{2}}\text{R25}& {\displaystyle }\mathrm{HO}X+hv\to X+\mathrm{OH}.\end{array}$$

Bates and Jacob (2020) introduced an expanded odd oxygen family, ${\mathrm{O}}_{\mathit{\text{y}}}$ $\equiv$ ${\mathrm{O}}_{\mathit{\text{x}}}$ $+$ ${\mathrm{O}}_{\mathit{\text{z}}}$, to include both ${\mathrm{O}}_{\mathit{\text{x}}}$ and an additional subfamily, ${\mathrm{O}}_{\mathit{\text{z}}}$, consisting of ${\mathrm{HO}}_{\mathit{\text{x}}}$ and its reservoirs (${\mathrm{O}}_{\mathit{\text{z}}}$ $\equiv$ 0.5 $\times$ ($\mathrm{H}$ $+$ $\mathrm{OH}$ $+$ organic peroxy radicals $+$ ${\mathrm{HNO}}_{\mathrm{2}}$ $+$ ${\mathrm{HNO}}_{\mathrm{3}}$ $+$ ${\mathrm{HNO}}_{\mathrm{4}}$ $+$ peroxyacyl nitrates $+$ organic nitrates $+$ $X$ $+$ $X$$\mathrm{O}$ $+$ $X$${\mathrm{NO}}_{\mathrm{2}}$ $+$ $X$${\mathrm{NO}}_{\mathrm{3}}$ $+$ $\mathrm{OIO}$ $+$ $\mathrm{OClO}$ $+$ $\mathrm{ClOO}$) $+$ ${\mathrm{H}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{2}}$ $+$ organic peroxides $+$ $X_{\mathrm{2}}$ $+$ $\mathrm{HO}$$X$ $+$ ${\mathrm{I}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{2}}$ $+$ ${\mathrm{I}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{3}}$ $+$ ${\mathrm{I}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{4}}$ $+$ ${\mathrm{Cl}}_{\mathrm{2}}$O${}_{\mathrm{2}}$, where $X$ $\equiv$ Cl, Br, I). Table 4 also summarizes the budget of ${\mathrm{O}}_{\mathit{\text{z}}}$. The global tropospheric ${\mathrm{O}}_{\mathit{\text{z}}}$ burden decreases by 4 % due to the halogen chemistry, which is mainly because of the lower production from ${\mathrm{O}}_{\mathit{\text{x}}}$. Following Bates and Jacob (2020), we define the chain length $N$, or ${\mathrm{O}}_{\mathit{\text{x}}}$ production efficiency per unit ${\mathrm{O}}_{\mathit{\text{z}}}$, as the number of times a unit of ${\mathrm{O}}_{\mathit{\text{z}}}$ is converted to ${\mathrm{O}}_{\mathit{\text{x}}}$ before it is removed to terminal sinks: 5$$N={\displaystyle \frac{\text{Rate of conversion from }{\mathrm{O}}_{\mathit{\text{z}}}\text{ to }{\mathrm{O}}_{\mathit{\text{x}}}}{\left(\text{Rate of }{\mathrm{O}}_{\mathit{\text{z}}}\text{ loss to }{\mathrm{H}}_{\mathrm{2}}\mathrm{O}\right)+\left(\text{Rate of }{\mathrm{O}}_{\mathit{\text{z}}}\text{ deposition}\right)}}.$$

In the conventional ${\mathrm{O}}_{\mathit{\text{x}}}$ budget analysis, conversion from ${\mathrm{O}}_{\mathit{\text{x}}}$ to ${\mathrm{O}}_{\mathit{\text{z}}}$ through $\mathrm{O}{(}^{\mathrm{1}}\mathrm{D})$ $+$ ${\mathrm{H}}_{\mathrm{2}}\mathrm{O}$ is viewed as a sink for ${\mathrm{O}}_{\mathit{\text{x}}}$, but if $N$ $>$ 1 it is actually a net source. By considering this, Bates and Jacob (2020) introduced an effective ozone lifetime as 6$$\mathit{\tau }={\displaystyle \frac{\mathrm{1}}{k_{{\mathrm{O}}_{\mathit{\text{x}}}\text{ loss to }{\mathrm{O}}_{\mathrm{2}}}+k_{{\mathrm{O}}_{\mathit{\text{x}}}\text{ deposition}}+(\mathrm{1}-N)k_{{\mathrm{O}}_{\mathit{\text{x}}}\text{ conversion to }{\mathrm{O}}_{\mathit{\text{x}}}}}},$$ where $k_i$ is the pseudo-first-order loss rate constant for process $i$. As shown in Table 4, $N$ increases from 1.40 to 1.47 by including halogen chemistry, thus amplifying ozone production efficiency from $\mathrm{O}{(}^{\mathrm{1}}\mathrm{D})$ $+$ ${\mathrm{H}}_{\mathrm{2}}\mathrm{O}$. This is because of the decrease in ${\mathrm{HO}}_{\mathrm{2}}$, which slows down the loss rate of H${\mathrm{O}}_{\mathit{\text{x}}}$. The effective ozone lifetime decreases by 15 %, from 71 to 60 $\mathrm{d}$, because the halogen-driven catalytic pathways represent true ozone sinks by converting ${\mathrm{O}}_{\mathrm{3}}$ to ${\mathrm{O}}_{\mathrm{2}}$.

Figure 14

Contributions of different pathways to the global annual loss of tropospheric ozone as a function of altitude. The “other” pathway includes sinks from reactions with alkenes and ${\mathrm{HNO}}_{\mathrm{3}}$ deposition.

[Figure omitted. See PDF]

Figure 15

Annual average vertical profile of ozone mixing ratios from ozonesonde observations and the model for six zonal bands.

[Figure omitted. See PDF]

Figure 16

Seasonal variation in surface ozone at a range of Global Atmospheric Watch (GAW) sites. Observational data are from the World Data Centre for Reactive Gases (WDCRG) and are 3-year monthly averages (2015–2017). Modeled values are monthly averages for 2016.

[Figure omitted. See PDF]

Figure 15 compares modeled ozone concentrations with and without halogen chemistry to ozonesonde observations from the World Ozone and Ultraviolet Data Center (WOUDC; http://www.woudc.org, last access: 1 April 2021). We only use data from the electrochemical concentration cell (ECC) and do not apply WOUDC-suggested correction factors, following Hu et al. (2017). There are a total of 47 stations in 2016 (Table S1 in the Supplement), and we average the data into six latitudinal bands. Halogen chemistry does not degrade the simulation in the Southern Hemisphere, where the model bias is small, but worsens the underestimate in the Northern Hemisphere. Similar results are found in Fig. 16, which compares modeled surface ozone mixing ratios to observations at surface sites. There is no significant seasonal variation for the impacts of halogen chemistry on surface ozone at these sites. The last extensive evaluation of the global tropospheric ozone simulation in GEOS-Chem was done by Hu et al. (2017) and found no significant bias, but it used version 10.1 of the model, and there have been many changes to the model since then. In particular, the introduction of ${\mathrm{NO}}_{\mathit{\text{y}}}$ reactive uptake by clouds in version 12.6 (Holmes et al., 2019) drove a 7 % decrease in global tropospheric ozone. Correcting this underestimate should be a topic of further research.

We presented a new comprehensive representation of tropospheric halogen chemistry in the GEOS-Chem model that synthesizes and updates previous model developments. We used it to analyze the sources and cycling of halogen radicals, evaluate against observations of halogen radicals and their reservoirs, and examine the implications for tropospheric oxidant chemistry.

The model includes an improved representation of heterogeneous chemistry in aerosols and clouds, including in particular the reactions of $\mathrm{HOBr}$, leading to less effective recycling and mobilization of bromine radicals. This allows us to include in the model the known source of bromine radicals from debromination of sea salt aerosol (SSA) without generating excessive $\mathrm{BrO}$ concentrations. Simulation of cloud processing is improved to include a more accurate computation of cloud water pH (Shah et al., 2020) and cloud entrainment (Holmes et al., 2019). ${\mathrm{ClNO}}_{\mathrm{2}}$ production by the heterogeneous ${\mathrm{N}}_{\mathrm{2}}{\mathrm{O}}_{\mathrm{5}}$ $+$ ${\mathrm{Cl}}^{-}$ reaction is updated to a slower rate to account for organic coating of particles (McDuffie et al., 2018a, b).

Cycling of chlorine and iodine radicals is similar to previous versions of GEOS-Chem (Wang et al., 2019; Sherwen et al., 2016b), but cycling of bromine radicals is very different. We find a mean tropospheric $\mathrm{BrO}$ mixing ratio of 0.19 $\mathrm{ppt}$, much lower than previous GEOS-Chem estimates and reflecting the less effective heterogeneous recycling of bromine radicals. $\mathrm{BrO}$ is highest in the marine boundary layer (MBL), where SSA debromination is the main source, and in the upper troposphere due to photodecomposition of bromocarbons and transport from the stratosphere. Model results are consistent with MBL observations of $\mathrm{BrO}$ from coastal sites and ship cruises, though observations are often below the detection limit. Comparisons to vertical profiles from aircraft campaigns paints an inconsistent picture, with model $\mathrm{BrO}$ being lower than the CAST CIMS, CONTRAST DOAS, and TORERO DOAS measurements over the tropical Pacific but higher than the ATom CIMS measurements at high altitudes on Pacific and Atlantic transects. The TORERO and CONTRAST DOAS data show increasing $\mathrm{BrO}$ concentrations in the upper troposphere, but the ATom CIMS data do not. The aircraft observations are again below or close to detection limits. A more confident evaluation of tropospheric bromine radical chemistry will require more sensitive observations of $\mathrm{BrO}$ and its reservoirs in the future.

Our simulation shows a global mass-weighted mean Cl atom concentration of 630 $\mathrm{molecules}{\mathrm{cm}}^{-\mathrm{3}}$ in the troposphere. Oxidation by Cl atoms accounts for 0.8 % of the global loss of atmospheric methane and has larger effects on the global losses of ethane (14 %), propane (8 %), and higher alkanes (7 %). Reactive chlorine (${\mathrm{Cl}}^{\ast }$ $\equiv$ ${\mathrm{Cl}}_{\mathit{\text{y}}}$ $-$ $\mathrm{HCl}$) is mainly generated from $\mathrm{HCl}$ $+$ OH (7.3 $\mathrm{Tg}\mathrm{Cl}{\mathrm{a}}^{-\mathrm{1}}$), heterogeneous reactions of ${\mathrm{Cl}}^{-}$ in clouds (6 $\mathrm{Tg}\mathrm{Cl}{\mathrm{a}}^{-\mathrm{1}}$), and oxidation of organochlorines (3.3 $\mathrm{Tg}\mathrm{Cl}{\mathrm{a}}^{-\mathrm{1}}$). Comparisons of model results to observations in marine surface air and aircraft campaigns in this study and our previous work (Wang et al., 2019) show that the model is in general consistent with the range and distributions of observed $\mathrm{HCl}$ and ${\mathrm{ClNO}}_{\mathrm{2}}$ concentrations. The model cannot reproduce the high daytime $\mathrm{BrCl}$ and ${\mathrm{Cl}}_{\mathrm{2}}$ concentrations observed during ATom, and matching those values would require a fast ${\mathrm{Cl}}^{\ast }$ source. Whether this can be compatible with other ATom observations of VOCs and radicals needs future investigation. Our simulated IO mixing ratios are consistent with marine observations in surface air and from aircraft, showing high values in the tropical MBL and low uniform values in the free troposphere. Our simulated global mean tropospheric IO concentration is 0.08 $\mathrm{ppt}$.

Halogen chemistry decreases the global burden of tropospheric ozone in GEOS-Chem by 11 %. This reflects a 2 % decrease in ozone production (due to the sink of ${\mathrm{NO}}_{\mathit{\text{x}}}$ from formation and hydrolysis of Cl${\mathrm{NO}}_{\mathrm{3}}$ and ${\mathrm{BrNO}}_{\mathrm{3}}$) and an 11 % increase in ozone chemical loss (due to catalytic cycles involving iodine (8 %) and bromine (3 %)). The global mean tropospheric OH concentration decreases by 4.1 %, mostly due to the decrease in ozone. Tropospheric ozone concentrations in GEOS-Chem show no significant bias in the Southern Hemisphere relative to ozonesonde data but a low bias in the Northern Hemisphere that is also present in the absence of halogen chemistry. Addressing this low bias should be a priority for future research.