Factors influencing the difference in dissolved ion inputs to the forest floor between deciduous and coniferous stands: comparison under high and low atmospheric deposition conditions

It is necessary to clear the relationship between physical and vegetation factors on the processes governing dissolved ion inputs to the forest floor to estimate correctly the values of atmospheric input to the forest. This study identified the factors influencing the differences in dissolved ion inputs to the forest floor between coniferous evergreen and broad-leaved deciduous species by analyzing the phenological variations of dry deposition and canopy exchange calculated by the canopy budget model under a high-deposition site near the city of Tokyo and a low-deposition site 84 km further away. At low-deposition site, vegetation factors such as capture efficiency did not explain the differences in Na+ or Cl− dry deposition. Leaf physiological characteristics influenced the differences in the Mg2+ and Ca2+ canopy leaching values, and phenology, leaf wettability, and diffusion processes from water film into leaves influenced the differences in NH4+ and NO3− input processes between tree types. At the high-deposition site, differences in the dry deposition of Na+, SO42−, Cl−, Mg2+, Ca2+, NH4+, and NO3− between tree types were influenced by differences in capture efficiency between coniferous and broad-leaved canopies in the leafed period and by the absence of leaves in deciduous species after leaf fall. These results indicated that atmospheric deposition affected the capture efficiency of coniferous trees for dry deposition and enhanced the difference of dissolved ion inputs to the forest floor between coniferous and deciduous species. Supplementary Information The online version contains supplementary material available at 10.1007/s10661-023-12132-6.


Introduction
Atmospheric deposition has caused a serious decline in forest health in Europe and Japan (Sase et al., 1998;Schütt & Cowling, 1985;Takamatsu et al., 2001) and the acidification of water and damage to fish and other aquatic life in lakes and rivers in Europe and North America (Baker, 1991;Rodhe, Vol:. (1234567890) 1972).However, emissions of SO 2 have decreased due to regulation and controls implemented in the 1970s (Smith et al., 2011), and emissions of NO x have decreased since the 1990s in Europe and since the 2000s in North America and Japan (Akimoto, 2003;EPA, 2022;Kopáček & Posch, 2011).Initial signs of the recovery from forest soil acidification, lake and river acidification, and biotic diversity have been reported in those regions due to the recovery of atmospheric conditions (Eimers et al., 2004;McHale et al., 2017;Sase et al., 2019;Wright et al., 2006).Therefore, correct and wide area estimation for values of atmospheric input to the forest is important to evaluate the recovery potential of the forest by reducing atmospheric deposition.
Stand deposition (SD) to the forest floor represents the total deposition supplied by throughfall (TF) and stemflow (SF).SD can be classified as wet deposition (WD; mainly precipitation), dry deposition (DD; gases and particles during dry periods), and canopy exchange (CE; canopy leaching or uptake) (Parker, 1983).WD is impacted by the strength and proximity of emission sources and meteorological factors, such as precipitation and wind speed.DD is affected by emission sources, meteorological factors, and vegetation factors such as the canopy's ability to capture pollutants (Andersen & Hovmand, 1999;Lovett et al., 1996).CE encompasses the exchange of gases, such as nitrogen compounds (e.g., NH 3 , NO, and NO 2 ), SO 2 , HNO 3 , and dissolved compounds (e.g., SO 4 2− , NO 3 − , NH 4 + ).The CE of gases occurs mainly via the stomata of vegetation (Sparks, 2009) and is controlled by stomatal conductance and gas concentrations.The CE of dissolved compounds is controlled by ion concentrations in leaves and precipitation characteristics (Lovett et al., 1996;Parker, 1983).Thus, the input of dissolved ions to the forest floor is influenced by both physical factors (e.g., the strength and proximity of emission sources and meteorological conditions) and vegetation factors (e.g., the canopy form and leaf ion concentrations).Understanding the influence of these physical and vegetation factors on dissolved ion input processes is necessary to clarify the differences in inputs to forests according to composition.
Physical factors can be investigated by comparing deposition trends in stands of the same species among different areas.For example, Imamura et al. (2020a) explained how physical factors (e.g., the distance from the center of Tokyo and elevation) affected the DD process in forests by comparing the WD and DD around Japanese cedar trees (Cryptomeria japonica (L.f.) D.Don) at seven sites within the Tokyo Metropolis.By contrast, to clarify vegetation factors, researchers have compared seasonal changes in DD and CE between coniferous and deciduous species at neighboring or nearby locations.Studies have performed seasonal comparisons of deciduous forests dominated by sugar maple (Acer saccharum Marsh.) and coniferous forests dominated by white pine (Pinus strobus L.) in Ontario, Canada (Neary & Gizyn, 1994); deciduous forests dominated by sugar maple and coniferous forests dominated by balsam fir (Abies balsamea (L.) Mill.) in Quebec, Canada (Houle et al., 1999); and deciduous forests dominated by silver birch (Betula pendula Roth) and coniferous forests dominated by Corsican pine (Pinus nigra ssp.laricio Maire) in Merksplas, Belgium (De Schrijver et al., 2004; Table 1).From these previous studies, the influence of vegetation factors (e.g., leaf capture efficiency, physiological activity, and leafless period in deciduous species) on the processes governing dissolved element inputs to the forest floor could be investigated by comparing seasonality between coniferous and deciduous species at neighboring locations.However, reported vegetation factors differed among previous studies.
De Schrijver et al. (2007) summarized the differences in annual SD between coniferous and deciduous stands reported in 38 case studies of sites with different atmospheric conditions.They found that, among stands, the Na + SD increased with open field deposition; there were no relationships of the variations in the SDs of K + , Ca 2+ , and Mg 2+ with open field deposition; moreover, the NH 4 + SD had a stronger correlation with open field deposition than did the NO 3 − SD (De Schrijver et al., 2007).From these results, we hypothesized that open field deposition, which is driven by physical factors, also affects the differences in DD and CE between coniferous and deciduous species, which are influenced by vegetation factors.The difference in atmospheric deposition could affect the different results about vegetation factors among previous studies.The present study aimed to identify factors influencing the differences in annual SDs between coniferous evergreen and broad-leaved deciduous species by comparing DD and CE between species during different phenological phases at sites that experience high and low atmospheric deposition values.
Precipitation, throughfall, and stemflow measurements Wet-only precipitation was collected using an automatic wet-only sampler at the First Nursery meteorological station at Tanashi (Imamura et al., 2018).Bulk precipitation was collected using a bulk sampler at the Koakasawa meteorological station at Chichibu and at the meteorological station at Tanashi.At Chichibu, six throughfall collectors arranged in two parallel lines of three samplers each were installed 1 m from broad-leaved deciduous species (F.crenata) (Fig. 2) (Imamura et al., 2012).Under the stand of coniferous evergreen species (C.japonica), throughfall samplers were placed at random, with six per site.Water samples were collected from the same three collectors to take into account the distance from the trunks (Fig. 2).SF was collected at each study plot.At Tanashi, under a broad-leaved deciduous (Q.acutissima) tree and C. japonica tree, TF samples were collected using five bulk samplers (Fig. 2 ) were measured using ion chromatography (LC-10A; Shimadzu Corp., Kyoto, Japan) and flame emission spectrometry (Z-2310; Hitachi High-Tech Science Corp., Tokyo, Japan).For quality control, each sample was assessed by comparing the measured and calculated conductivities of the water samples and the ion balances.

Meteorological and air quality measurements
Meteorological observations of air temperature and relative humidity were conducted atop a 23-m-high meteorological tower at the deciduous forest site in Chichibu and a 26-m-high meteorological tower at the C. japonica plantation in Tanashi.Air temperature and relative humidity were measured using a thermohygrograph at Chichibu (CS500; Campbell Scientific, Inc., Logan, USA) and Tanashi (Hobo U23-002; Onset Computer Corp., Bourne, MA, USA).NO 2 and NO x (NO plus NO 2 ) filter samples were collected monthly from July 26, 2011, to July 5, 2012, on the meteorological tower in Chichibu using a passive sampler (OG-SN-S; Ogawa & Co., Ltd, Kobe, Japan).NO was calculated by subtraction.Water extracted from the exposed filter and blank filter was analyzed using the Saltzman method with a spectrophotometer (U-1800; Hitachi High-Tech Corporation, Tokyo, Japan).The limit of quantitation (LOQ) was calculated as ten times the standard deviation of the blanks (MacDougall et al., 1980).At Tanashi, these concentrations were obtained from national monitoring data obtained from July 14, 2011, to July 3, 2012, at the nearest monitoring site (located 1.2 km from Tanashi) (National Institute for Environmental Studies, 2022).

Estimation of dry deposition and canopy exchange
The TF and SF volumes were averaged across all collector samples at each site.The volume-weighted mean ion concentrations in TF and SF were then calculated.TF and SF depositions (mmol m −2 ) were calculated using the above datasets.During periods without observations, WD was calculated using bulk deposition and the bulk:wet-only concentration ratio at Tanashi (Imamura et al., 2018).Bulk deposition was used as a proxy for WD at Chichibu during all sampling periods.DD and CE were calculated with the canopy budget model (CBM) using WD, TF, and SF (Adriaenssens et al., 2013;Staelens et al., 2008).The DDs of K + , Mg 2+ , and Ca 2+ were estimated assuming that aerosols containing K + , Mg 2+ , and Ca 2+ were deposited onto the forest canopy at a rate equal to that of particulate Na + .Using the net throughfall (NTF):WD ratio of the Na + tracer ion, the DD rates of K + , Mg 2+ , and Ca 2+ were calculated as follows: where X is K + , Mg 2+ , or Ca 2+ .
The CL values of K + , Mg 2+ , and Ca 2+ were calculated by subtracting DD from NTF.The CL of basic cations (BC; K + + Mg 2+ + Ca 2+ ) should equal the CU of H + (Cronan & Reiners, 1983) and (2.1) Vol:.( 1234567890) NH 4 + (Roelofs et al., 1985) based on the ion charge balance of the canopy (Eq.2.2): H + has an exchange capacity six times larger than that of NH 4 + (Draaijers et al., 1998), which is accounted for by the relative uptake efficiency factor (xH = 6) in Eq. 2.3 to calculate the CU of NH 4 + (De Schrijver et al., 2004): The CU of H + was calculated by subtracting NH 4 from CU NH4+H .The DDs of NH 4 + and H + were calculated by subtracting CU from NTF.
The CU of NO 3 − was calculated based on the TF fluxes of NH 4 + and NO 3 − , using an efficiency factor of NH 4 + versus NO 3 − uptake (xNH 4 ) with a value of six (de Vries et al., 2001;Eq. 2.4).
Na + , Cl − , and SO 4 2− were defined only in terms of DD, i.e., not in terms of CL or CU.

Definition of seasons
At Chichibu, long-term video data indicate that the leaf-out period for the F. crenata canopy lasts from (2.2) May to November (Fujiwara & Saito, 2005); these 7 months were considered the growing season, and the remaining 5 months were considered the dormant season (Fig. 3).At Tanashi, the leaf-out period for Q. acutissima lasted from April until November based on visual observations; these 8 months were defined as the growing season, and the remaining 4 months were considered the dormant season (Fig. 3).
The 2-year average annual DD and CE values were separated into four phenological phases (Staelens et al., 2007;Van Stan et al., 2012).The leaf emergence and leaf senescence periods were defined as the first and last 2 months of the growing season, respectively, for all species (Fig. 3).The other months of the growing season were defined as the fully leafed period.The leafless period was equal to the duration of the dormant season (Fig. 3).

Data analysis
To elucidate the differences in annual SDs between coniferous and deciduous species, annual SDs between coniferous and deciduous stands were compared at original study sites (Chichibu and Tanashi) and previous study sites (Ontario; Neary & Gizyn, 1994, Quebec;Houle et al., 1999, Merksplas;De Schrijver et al., 2004).Previous studies have performed seasonal comparisons of deciduous and coniferous forests.A low atmospheric deposition site was defined as a lower wet deposition site compared to that at Chichibu.By contrast, a higher atmospheric deposition site was defined as a higher wet deposition site compared to that at Tanashi.DD and CE in annual, growing, and dormant seasons were calculated by the CBM at Chichibu, Tanashi, Ontario, Quebec, and Merksplas.In addition, only at Chichibu and Tanashi, monthly averaged DD and CE were calculated by the same method in the leaf emergence, fully leafed, leaf senescence, and leafless periods.A paired t-test was used to test the significant difference in annual and seasonal SD, DD, and CE between coniferous and deciduous stands.

Meteorology and air quality
Figure 4 presents the seasonal variations in meteorological parameters of the canopies at Chichibu and Tanashi from October 2010 to September 2012.The annual mean humidity was 79% and 70% at Chichibu and Tanashi, respectively.The relative humidity was higher at Chichibu than Tanashi throughout the year, particularly in summer when the relative humidity at Chichibu exceeded 80% from June to September.At Chichibu, the average absorption of the field blank for NO 2 and NO x was 0.16 (n = 4) and 0.21 (n = 4), respectively.The LOQ of absorption was 0.02 and 0.57 for NO 2 and NO x .Whereas all values of absorption for NO 2 were above the LOQ, those for NO x were below LOQ.Therefore, the average NO and NO 2 concentrations were below the LOQ and 1.2 ppb, respectively, at Chichibu.At Tanashi, the average NO and NO 2 concentrations were 5.5 ppb and 16.6 ppb, respectively.The NO 2 concentrations were > 10 times higher at Tanashi than Chichibu.
Differences in stand deposition between deciduous and coniferous species At Chichibu, there were no differences in the 2-year average annual SD and DD values for Na + (p = 0.05) and SO 4 2− (p = 0.61) between deciduous and coniferous species (Tables 2 and 3).By contrast, the average annual SD and DD values of Cl − were significantly higher for coniferous than deciduous species (p < 0.05) (Tables 2 and 3).At Tanashi, the average annual SD and DD values of Na + , Cl − , and SO 4 2− were significantly higher for coniferous than deciduous species (p < 0.001) (Tables 2 and  3).At Chichibu, the DD values were significantly higher for coniferous than deciduous species for Na + and Cl − in the leaf senescence period (p < 0.05) and Cl − and SO 4 2− in the leafless period (p < 0.05) (Fig. 5).The SO 4 2− DD value was significantly higher for deciduous than coniferous species in the fully leafed and leaf senescence periods (p < 0.05) (Fig. 5).At Tanashi, the DD values were significantly higher for coniferous than deciduous species during all phenological periods except the leaf senescence period for Na + (p < 0.05) and Cl − (p < 0.01) and the fully leafed and leafless periods for SO 4 2− (p < 0.01) (Fig. 5).
The annual K + SD value was non-significantly higher for deciduous than coniferous species at Chichibu (p = 0.50) and significantly at Tanashi  (p < 0.01) (Table 2).The annual Mg 2+ SD value did not differ between deciduous and coniferous species at Chichibu (p = 0.09) but was significantly higher for coniferous than deciduous species at Tanashi (p < 0.01) (Table 2).The annual SD value of Ca 2+ was significantly higher for coniferous than deciduous species at both Chichibu and Tanashi (p < 0.01) (Table 2).At Chichibu, the annual CL values of K + , Mg 2+ , and Ca 2+ were > 20 times higher than the DD values for both coniferous and deciduous species (Tables 3 and 4).At Tanashi, the annual K + DD value was about one-tenth the CL value for coniferous species, and the Mg 2+ and Ca 2+ DD values were about half the respective CL values (Tables 3 and  4).The Mg 2+ CL value was significantly higher for deciduous than coniferous species in the leaf emergence period at Chichibu (p < 0.01) (Fig. 6).At Tanashi, the CL values of K + (p < 0.01) and Mg 2+ (p < 0.05) were significantly higher for deciduous than coniferous species in the leaf emergence and fully leafed periods (Fig. 6).By contrast, the Mg 2+ CL value was significantly higher for coniferous than deciduous species in the leafless period at Chichibu (p < 0.05) and Tanashi (p < 0.001) (Fig. 6).The Ca 2+ CL value was significantly higher for coniferous than deciduous species in the fully leafed, leaf senescence, and leafless periods at Chichibu (p < 0.05) and in the leaf emergence and leafless periods at Tanashi (p < 0.05) (Fig. 6).
Coniferous species showed significantly higher DD values of Mg 2+ (p < 0.01) and Ca 2+ (p < 0.01) than deciduous species during all phenological periods except the leaf senescence period at Tanashi (Fig. 5).
The annual H + SD value was significantly higher for coniferous than deciduous species at Chichibu and Tanashi (p < 0.001) (Table 2).At Chichibu and Tanashi, SF represented 78% and 83%, respectively, of the annual H + SD value for coniferous species and 5% and 6%, respectively, for deciduous species (Table 2).
The annual NH 4 + SD value was significantly higher for deciduous than coniferous species at Chichibu (p < 0.01) (Table 2).By contrast, coniferous species showed significantly higher annual SD values of NH 4 + (p < 0.01) and NO 3 − (p < 0.001) than deciduous species at Tanashi (Table 2).At Chichibu, the annual NH 4 + DD value was non-significantly higher than the CU value for deciduous species (p = 0.54) (Tables 3 and 5).At Tanashi, the annual DD values of NH 4 + and NO 3 − were significantly higher than the respective CU values for coniferous and deciduous species (p < 0.001 and p < 0.05, respectively), and the DD values were significantly higher for coniferous than deciduous species (p < 0.01 and p < 0.001, respectively) (Tables 3 and 5).The NH 4 + CU value was significantly higher for deciduous than coniferous Values in parentheses are standard deviations  species in the leaf emergence and fully leafed periods at Chichibu and Tanashi (p < 0.05) (Fig. 7).The NH 4 + DD value was significantly higher for deciduous than coniferous species in the leaf emergence, fully leafed, and leaf senescence periods at Chichibu (p < 0.05) (Fig. 5).By contrast, the NH 4 + DD value was significantly higher for coniferous than deciduous species in the fully leafed and leafless periods at Tanashi (p < 0.01), while the NH 4 + DD value was significantly higher for deciduous than coniferous species in the leaf emergence period (p < 0.01) (Fig. 5).In addition, at Chichibu, the NO 3 − DD and CU values were significantly higher for deciduous than coniferous species in the leaf emergence period (p < 0.05) (Figs. 5   and 7).At Tanashi, the NO 3 − DD value was higher for coniferous than deciduous species during all phenological periods except the leaf senescence period (p < 0.01) (Fig. 5).

Sodium and chloride ions
At the low-atmospheric-deposition site (Chichibu), there were no differences in the annual Na + DD or SD values between coniferous and deciduous species (Tables 2 and 3) because significant differences were Values in parentheses are standard deviations  , K + , Mg 2+ , Ca 2+ , H + , NH 4 + , and NO 3 − during each canopy phenological phase for deciduous species and coniferous species (Cryptomeria japonica) at Chichibu and Tanashi.The leaf emergence, fully leafed, leaf senescence, and leafless periods are defined in Fig. 3. *A paired t-test, p < 0.05, **t-test, p < 0.01, ***t-test, p < 0.001 Vol:.( 1234567890) observed only in the leaf senescence period (Fig. 5).Similarly, in Ontario, Canada, where the Na + WD value was lower than that at Chichibu (Table 1), the annual SD value did not differ significantly between species (Neary & Gizyn, 1994) (Table 2) because the DD values did not differ between species in either the growing or dormant seasons (Table 3).In addition, at a low-atmospheric-deposition site in Quebec, Canada (Table 1), the Na + SD and DD values were similar between coniferous and deciduous species (Houle et al., 1999) (Tables 2 and 3).These results suggest that differences in the annual SD values of Na + between coniferous and deciduous species are minimally impacted by vegetation factors such as capture efficiency at low-deposition sites.
The annual Cl − SD value was higher for coniferous than deciduous species at Chichibu (Table 2).This resulted from the significantly higher Cl − DD value for coniferous than deciduous species during the leaf senescence and leafless periods (Fig. 5), which could be influenced by HCl gas concentrations at Chichibu.In Ontario and Quebec, where the Cl − WD values were lower than that at Chichibu (Table 1), there were no significant differences in annual Cl − SD values between species (Houle et al., 1999;Neary & Gizyn, 1994) (Table 2) because there were no differences in the DD values between species in the growing and dormant seasons (Table 3).Similar to Na + , the differences in annual Cl − SD values between coniferous and deciduous species are minimally influenced by vegetation factors such as capture efficiency at low-deposition sites.

Potassium, magnesium, and calcium ions
The annual K + SD value was significantly higher for deciduous than coniferous species at Tanashi (Table 2) as a result of the low K + DD value (Table 3) and increased K + CL value for deciduous species in the leaf emergence and fully leafed periods (Fig. 6).
Although not significant, the same trend was observed at Chichibu (Fig. 6, Tables 2 and 3).Similarly, three other studies found higher annual K + SD values for deciduous than coniferous species because the K + CL values were higher for deciduous than coniferous species in the growing season, even though these correlations were not significant (De Schrijver et al., 2004;Houle et al., 1999;Neary & Gizyn, 1994) (Tables 2 and 4).Similar to Chichibu and Tanashi, the previous studies also reported lower annual K + DD than CL values (Tables 3 and 4).These trends indicate that differences in the annual K + SD value between coniferous and deciduous species are influenced by the CL value of deciduous species in the growing season, especially the leaf emergence and fully leafed periods, even at sites with different atmospheric deposition values.In Japan, deciduous broadleaved species generally have higher K + levels in their leaves than C. japonica (Table 6).In addition, broad leaves are susceptible to the leaching of K + (Rothe et al., 2002).The higher K + CL value in deciduous than coniferous species in the leaf emergence and fully leafed periods was assumed to be due to differences in leaf K + concentrations between deciduous and coniferous species.Therefore, differences in the K + SD value between coniferous and deciduous species are influenced by the physiological state and leaf K + concentration of tree species, regardless of the atmospheric deposition value.At Chichibu, the Mg 2+ CL value was higher for deciduous species in the leaf emergence period and coniferous species in the leafless period; meanwhile, the Ca 2+ CL was significantly higher for coniferous than deciduous species in the fully leafed and leafless periods (Fig. 6).Moreover, the annual Mg 2+ SD value did not differ between tree species, and the Ca 2+ SD value was significantly higher for coniferous than deciduous species (Table 2).The same trends were observed at low-deposition sites in Ontario and Quebec, Canada (Houle et al., 1999;Neary & Gizyn, 1994) (Table 2).This resulted from the higher Mg 2+ CL value for deciduous species in the growing period and coniferous species in the dormant season (Table 4).In Ontario, the Ca 2+ CL value was non-significantly higher for coniferous than deciduous species in the growing or dormant season; in Quebec, the Ca 2+ CL value was significantly higher for coniferous species in the dormant season (Table 4).Leaf Mg 2+ and Ca 2+ concentrations did not differ between deciduous species and C. japonica (Table 6); however, broad leaves are more susceptible to leaching of Mg 2+ than Ca 2+ (Rothe et al., 2002).The lack of differences in annual Mg 2+ SD values between coniferous and deciduous species resulted from differences in the Mg 2+ CL values of each species between the growing and dormant seasons at low-deposition sites.By contrast, the higher annual Ca 2+ SD value for coniferous than deciduous species resulted from higher CL from coniferous than deciduous species throughout the year.These results indicate that differences in annual Mg 2+ and Ca 2+ SD values between coniferous and deciduous species are influenced by the physiological characteristics of leaves at low-deposition sites.
The annual Mg 2+ and Ca 2+ DD values were > 20-fold lower than the respective CL values at the low-deposition site, Chichibu, but were only half the respective CL values at the high-deposition site (Tanashi; Tables 3 and 4).In addition, the Mg 2+ and Ca 2+ DD values were higher for coniferous than deciduous species during all phenological periods, except the leaf senescence period at Tanashi (Fig. 5).These trends indicate that Mg 2+ and Ca 2+ DD values also influence the differences in annual Mg 2+ and Ca 2+ SD values between coniferous and deciduous species at high-deposition sites.At a high-deposition site in Merksplas, Belgium (Table 1), the annual Mg 2+ and Ca 2+ SD values were higher for coniferous than deciduous species, although not significantly (De Schrijver et al., 2004) (Table 2); the Mg 2+ and Ca 2+ DD values were higher than the respective CL values and were also higher for coniferous than deciduous species throughout the year (Tables 3 and 4).These findings indicate that differences in annual Mg 2+ and Ca 2+ SD values between coniferous and deciduous species are affected by the CL and DD values at highdeposition sites.Mg 2+ and Ca 2+ CL and DD values between coniferous and deciduous species are influenced by the physiological characteristics of leaves and by stand capture efficiency, respectively.

Hydrogen ion
The higher annual H + SD for coniferous than deciduous species was the result of higher H + SF for coniferous than deciduous species (Table 2).Generally, conifers supply high amounts of H + via SF, due to the low pH of SF resulting from the comparatively higher dissolved organic concentrations of conifers (Inagaki et al., 1995;Parker, 1983;Thieme et al., 2019) and lower bark pH (Asplund et al., 2015) compared to deciduous species.Measurements in Ontario, Canada, revealed lower H + SF values for conifers than in this study (Table 2) because the five most dominant species were selected for SF sampling in the former study (Table 1), which also found higher H + SF levels for coniferous than deciduous species (Neary & Gizyn, 1994) (Table 2).Other studies conducted in Quebec, Canada, and Merksplas, Belgium, did not consider inputs of H + from SF in the evaluation of H + SD values, and the SD of conifers was not greater than that of deciduous species (De Schrijver et al., 2004;Houle et al., 1999)  SD value between coniferous and deciduous species are caused by differences in H + SF between species, regardless of atmospheric deposition values.

Sulfur, ammonium, and nitrate ions
The CU of nitrogen is controlled by leaf physiological activities (e.g., stomatal opening and photosynthesis rates) (Krupa, 2003;Lovett et al., 1996;Parker, 1983) and passive diffusion processes from water film into leaves (Hansen, 1996;Lovett et al., 1996;Schaefer et al., 1988).In addition, some studies reported canopy nitrification by using a dual isotope approach (Guerrieri et al., 2015;Templer et al., 2015;Watanabe et al., 2016).However, CBM does not account for possible nitrogen transformations occurring in tree canopies by epiphytes and/or microbes associated with foliage (Guerrieri et al., 2021).Therefore, this chapter is just focused on leaf physiological activities and passive diffusion processes for CU of nitrogen.
Birch showed the highest uptake rates in the leaf developing stage by the 15 NH 4 + -labelled test (Adriaenssens et al., 2011).In addition, Adriaenssens et al. (2012) reported a strong negative net TF flux for NO 3 − in a beech canopy during the leaf development period, which was related to NO 3 − -N assimilation.At both Chichibu and Tanashi, we found that the NH 4 + CU value was significantly higher for deciduous than coniferous species during the leaf emergence period (Fig. 7).This trend is considered the result of increased CU by leaf physiological activities of deciduous species in the leaf emergence period.In addition, water films on leaves, which form when particles are dry-deposited under relatively humid conditions, reduce cuticular resistance (Burkhardt & Eiden, 1994).Gaseous deposition of NH 3 , NO y , and SO 2 from the atmosphere to the plant surface is increased in the presence of such films; as the gases dissolve into the water in the film, their concentrations rise, thereby enhancing passive diffusion from water film into the needle (Adriaenssens et al., 2012;Sase et al., 2008).De Schrijver et al. (2004) suggested that CU by deciduous species increases in the growing season when cuticles are thinner and wettability is greater.At the low-deposition site (Chichibu), we found that the SO 4 2− and NH 4 + DD values were significantly higher for deciduous than coniferous species in the fully leafed and leaf senescence periods (Fig. 5).The relative humidity during summer was higher at Chichibu than Tanashi because a large area around Chichibu is forested (Fig. 4).In addition, fog occurs frequently at Chichibu (Imamura et al., 2020b).Therefore, the increased SO 4 2− and NH 4 + DD values for deciduous species in the growing season are attributable to the result of the presence of water films on leaves.In addition, the NH 4 + CU value for deciduous species also could be increased in the growing season via passive diffusion from water film into leaves (Fig. 7).
While the NH 4 + CU value was significantly higher for deciduous than coniferous species in the leaf emergence period, the NH 4 + DD value was significantly higher for deciduous than coniferous species during the growing season (Figs. 5 and 7).Therefore, the annual NH 4 + SD value has been higher for deciduous than coniferous species because the annual NH 4 + DD value was higher than the annual NH 4 + CU value for deciduous species.The annual SO 4 2− SD value did not differ between coniferous and deciduous species (Table 2); this was the result of a higher SO 4 2− DD value for deciduous species in the fully leafed and leaf senescence periods and higher value for coniferous species in the leafless period (Fig. 5).At a low-deposition site in Quebec, Canada (Table 1), the significantly higher annual NH 4 + SD value for deciduous than coniferous species resulted from a higher NH 4 + DD value for the former species throughout the year (Houle et al., 1999) (Tables 2 and  3).Differences in the annual SO 4 2− SD value between deciduous and coniferous species were influenced by leaf wettability, and those of NH 4 + were influenced by leaf uptake (a phenological factor), as well as the DD and CU driven by leaf wettability and diffusion processes from water film into leaves at the low-deposition site.
The NO 3 − CU value was higher for deciduous than coniferous species in the leaf emergence period at Chichibu (Fig. 7).However, there was no difference between species in the NO 3 − DD value during other periods (Fig. 5).While the NH 4 + DD value for deciduous species increased in fully leafed and leaf senescence periods (relatively humid conditions), the NO 3 − DD value did not increase during same periods at Chichibu (Fig. 5).This is because water films had no impact on the diffusion processes, possibly due to low gas concentrations (NO: below the LOQ; NO 2 : 1.2 ppb).In Quebec, CU of NO 3 − was reported in the leaf senescence period.In addition, the annual NO 3 − SD value was significantly higher for deciduous than coniferous species because the NO 3 − DD value was higher for the former species throughout the year (Houle et al., 1999) (Tables 2 and 3).The gas concentrations in 1999 in Quebec (NO: 2.3 ppb; NO 2 : 8.0 ppb; National Air Pollution Surveillance Program, 2022) were higher than those at Chichibu during the present study; thus, water film formation increased the DD of NO 3 − for deciduous species.Overall, differences in the annual NO 3 − SD value between deciduous and coniferous species were influenced by both phenological factors and diffusion processes, although atmospheric gas concentrations also impact diffusion.
At Tanashi, the significantly higher annual SO 4 2− SD value for coniferous than deciduous species (Table 2) resulted from the higher SO 4 2− DD values for coniferous than deciduous species in the fully leafed and leafless periods (Fig. 5).The NH 4 + and NO 3 − CU values were higher in the leaf emergence period (Fig. 5), and the annual NH 4 + and NO 3 − DD values were significantly higher than the respective CU values for both species (Tables 3 and  5).In addition, the NH 4 + and NO 3 − DD values were higher for coniferous than deciduous species in the fully leafed and leafless periods (Fig. 5).Therefore, the annual NH 4 + and NO 3 − SD values were significantly higher for coniferous than deciduous species (Table 2).In Ontario, Canada, where the SO 4 2− WD value was higher than that at Tanashi (Table 1), the annual SO 4 2− SD value was significantly higher for coniferous than deciduous species (Neary & Gizyn, 1994) (Table 2) because DD was significantly higher for coniferous than deciduous species in the growing season (Table 3).Similarly, the annual SO 4 2− SD value was non-significantly higher for coniferous than deciduous species in Quebec (Houle et al., 1999) (Table 2) because the DD was higher for the former species in the growing and dormant seasons (Table 3).In Merksplas, Belgium, where the NH 4 + and NO 3 − WD values were higher than those in Tanashi (Table 1), the annual NH 4 + and NO 3 − DD values were higher than the respective CU values (Tables 3  and 5).In addition, the annual NH 4 + and NO 3 − DD and SD values were higher for coniferous than deciduous species (De Schrijver et al., 2004) (Tables 2  and 3).These results indicate that the annual SO 4 2− , Vol:. ( 1234567890) NH 4 + , and NO 3 − SD values are higher for coniferous than deciduous species as a result of increased DD (due to a higher capture efficiency) for coniferous species in the growing season, as well as the absence of leaves on deciduous species in the dormant season at high-deposition sites.

Conclusion
This research explained the factors affecting the difference of dissolved ion inputs to the forest floor between coniferous and deciduous species by comparing seasonal variations of dry deposition and canopy exchange at two different atmospheric deposition conditions.Whereas this research is regional and based on limited observation data, this research cleared that the atmospheric deposition affected to vegetation factor, especially the capture efficiency of coniferous trees for Na + , Cl − , Mg 2+ , Ca 2+ , SO 4 2− , NH 4 + , and NO 3 − .In contrast, atmospheric deposition had no impact on canopy leaching of K + , Mg 2+ , and Ca 2+ and neutralization between species.This suggests that information on atmospheric depositions in the study area could be important to estimate correctly different values of dissolved ion inputs to forest floor between deciduous and coniferous forests.

Fig. 1
Fig. 1 Location of the Chichibu and Tanashi forest sites.The satellite image was obtained from Google Maps

Fig
Fig. 2 Canopy projection and locations of bulk throughfall samplers at the observation sites at (a) Chichibu and (b) Tanashi.Individual Fagus crenata, Quercus acutissima, and Cryptomeria japonica trees are denoted as Fc, Qa, and Cj, respectively.Stemflow water was collected from Cj1, Cj2, and Cj3 and from Qa1, Qa2, and Qa3, respectively, at Tanashi

Fig. 3
Fig. 3 Phenological periods at (a) Chichibu and (b) Tanashi.The leaf emergence period lasted 1 month (May at Chichibu and April at Tanashi).The fully leafed period was 4 months (June-September) at Chichibu and 5 months (May-September)

Fig. 4
Fig. 4 Monthly air temperature (°C) and relative humidity (%) by canopy height from October 2010 to September 2012 at (a) Chichibu and (b) Tanashi

Table 1
Comparison of deposition values and study site characteristics between this and previous studies * Watmough, S.A., & Dillon, P.J.
. Age structure and regeneration characteristic in a natural beech (Fagus japonica Maxim.And F. crenata Blume) forest in the Chichibu mountains, central Japan.

Table 2
Comparison of the average annual water and ion throughfall deposition (TF), stemflow deposition (SF), and stand deposition (SD) values between deciduous (Dec) and coniferous (Con) trees in this and previous studies Vol.: (0123456789)

Table 3
Comparison of the dry deposition values (mmol m −2 year −1 ) of Na + , Cl − , SO 4 Dec) and coniferous (Con) species during the annual, growing, and dormant periods in this and previous studies Vol.: (0123456789)

Table 4
Comparison of the canopy leaching values (mmol m −2 year −1 ) of K + ,

Table 5
Comparison of the canopy uptake values (mmol m −2 year −1 ) of H + , NH 4 (Table 2).Overall, the findings indicate that differences in the annual H +

Table 6
Average nutrient contents of leaves in Japan reported by previous studies Values in parentheses are standard deviations * Katagiri, S. (1996).V. Material production and nutrient cycling in various forest ecosystems.In Iwatsubo, G (Ed.), Modern Forestry 12 Forest ecology, (pp.189-293).Tokyo: Buneido Publishing Co., Ltd † Katagiri, S. (1977).Studies on mineral cycling in a deciduous broad-leaved forest at Sanbe forest of Shimane university (IV) Concentration of nutrient elements of trees.Bulletin of the Faculty of Agriculture, Shimane University, 11, 60-72 ‡ Tsutsumi, T. (1965).Amount of nutrients in trees of Cryptomeria japonica.Transactions of the meeting of the Japanese Vol.: (0123456789)