Fluxes of dissolved organic carbon and nitrogen throughout Andisol, Spodosol and Inceptisol profiles under forest in Japan

Fujii, Kazumichi; Funakawa, Shinya; Shinjo, Hitoshi; Hayakawa, Chie; Mori, Keiko; Kosaki, Takashi

doi:10.1080/00380768.2011.637304

Cited by 16 publications

(6 citation statements)

References 52 publications

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“…In general terms, the increase in DOC concentration from precipitation to throughfall is almost certainly due to leaf leaching and microbial metabolites (biodegradable and hydrophilic neutral carbohydrates) that wash from the canopy during this process (Guggenberger and Zech 1994;Michalzik et al 2001;Levia et al 2012). In this study site, the mean concentration of DOC in throughfall (6.84 ± 0.45 mg C L À1 ) consistent with previous reports (3-35 mg C L À1 , Michalzik et al 2001;Fujii et al 2011a), while the mean concentration of DOC in the precipitation (2.98 ± 0.45 mg C L À1 ) was a little higher than that reported in other studies (1.8-2.7 mg C L À1 ; Currie et al 1996;Michalzik and Matzner 1999;Moreno et al 2001;Solinger et al 2001). Contrary to expectations, the DOC concentration in throughfall below the dwarf bamboo (7.08 ± 0.42 mg C L À1 ) was not notably different from that in throughfall above the dwarf bamboo (6.84 ± 0.45 mg C L À1 ) ( Table 2), which indicates that the bamboo canopy had little effect on the DOC concentration.…”

Section: Variations and Regulation Of Doc Concentrationsupporting

confidence: 88%

“…The growing season DOC flux was 311.5 kg ha À1 7 months À1 at the study site, which was in the upper range of those reported in other temperate forest ecosystems (100-400 kg C ha À1 year À1 , Michalzik et al 2001) and much higher than that reported in another deciduous forest in Steigerwald, Germany (85.9-208.2 kg C ha À1 year À1 ; Solinger et al 2001) and in Japan (52.6-343.6 kg C ha À1 year À1 ; Fujii et al 2011a). The magnitude of the DOC flux might be explained by several factors.…”

Section: Water Budgets and Dissolved Organic Carbon Flux During The Gmentioning

confidence: 51%

“…In Asia, the unique climatic and other environmental characteristics that distinguish the region from the relatively well-studied forests of Europe and the USA (Fujii et al 2011a), several studies about DOC flux have been conducted in subtropical forest (Liu and Sheu 2003;Xu et al 2005) or tropical forest (Fujii et al 2011b). To date, most of studies about DOC dynamics were focus on forested catchment or in soil profile (Kawasaki et al 2002(Kawasaki et al , 2005Kawahigashi 2011;Fujii et al 2011a). The investigations of linking the DOC fluxes in temperate forest ecosystems to the soil organic carbon in Japan were limited (Shibata et al 2001).…”

Section: Introductionmentioning

confidence: 99%

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Dissolved organic carbon (DOC) input to the soil: DOC fluxes and their partitions during the growing season in a cool‐temperate broad‐leaved deciduous forest, central Japan

Chen

Yoshitake

Iimura

et al. 2017

Ecological Research

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Dissolved organic carbon (DOC) plays an important role in C cycling in forest ecosystems. Here we measured the concentrations and fluxes of DOC in a cool‐temperate broad‐leaved deciduous forest (Takayama Forest) to quantify the contribution of DOC from different forest water flux conditions. Mean DOC concentration during the growing season increased in the sequence from bulk precipitation (2.98 ± 0.45 mg L−1), throughfall above dwarf bamboo (6.84 ± 0.45 mg L−1), throughfall below dwarf bamboo (7.08 ± 0.42 mg L−1), stemflow (15.05 ± 0.98 mg L−1), and litter leachate (21.33 ± 1.01 mg L−1). Litter leachate DOC concentration, being high in spring and autumn, which was fairly correlated with the amount of litterfall of bamboo and trees. In stemflow, the DOC concentration was high during early summer and gradually decreased, in addition, it also showed dramatic variation among different plant species. Litter leachate (72.5%) accounted for most of the DOC input to the soil during the growing season (311.5 kg C ha−1 7 months−1), while stemflow (1.6%) contributed the least. A great quantity of precipitation at the study site was associated with a subsequent high atmospheric contribution of DOC flux (8.6%), which was more than half of throughfall (16.5%). The high input of DOC to the soil and andisol soil characteristics at the Takayama Forest suggest that the DOC fluxes are vital to the soil carbon sequestration. Therefore, DOC fluxes should be taken into account when the carbon balance is assessed at forest ecosystems.

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Section: Variations and Regulation Of Doc Concentrationsupporting

confidence: 88%

Section: Water Budgets and Dissolved Organic Carbon Flux During The Gmentioning

confidence: 51%

Section: Introductionmentioning

confidence: 99%

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Dissolved organic carbon (DOC) input to the soil: DOC fluxes and their partitions during the growing season in a cool‐temperate broad‐leaved deciduous forest, central Japan

Chen

Yoshitake

Iimura

et al. 2017

Ecological Research

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“…Besides cushion plants in the A horizon, mean DOC concentrations in our study (3.1 -4.0 mg L -1 ) are close to the range of values measured in Andosols grasslands: 4.7 mg L -1 (by wick samplers, Pesántez et al, 2018) and 5 -7 mg L -1 (by lysimeters, Ugolini et al, 1988). DOC concentrations present a larger range when measured in soil solutions collected by lysimeters for Andosols under other vegetation covers (2 -28 mg L -1 , Aran et al, 2001;Chen et al, 2017;Fujii et al, 2011).…”

Section: Soil Water Dynamics Under Cushion-forming Plants and Tussock...supporting

confidence: 86%

Soil-vegetation-water interactions controlling solute flow and transport in volcanic ash soils of the high Andes

Páez‐Bimos

Molina

Calispa

et al. 2022

Preprint

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Abstract. Vegetation plays a key role in the hydrological and biogeochemical cycles. It can influence soil water fluxes and transport which are critical for chemical weathering and soil development. In this study, we investigated soil water balance and solute fluxes in two soil profiles with different vegetation types (cushion-forming plants vs. tussock grasses) by measuring soil water content, flux, and solute concentrations and by modeling soil hydrology. We also analyzed the role of soil water balance in soil chemical weathering. The influence of vegetation on soil water balance and solute fluxes is restricted to the A horizon. Evapotranspiration is 1.7 times higher and deep drainage is 3 times lower under cushion-forming plants than under tussock grass. Likewise, cushions transmit almost threefold less water from the A to lower horizons. This is attributed to the vertical distribution of soil properties associated with the root systems. Under cushion-forming plants, DOC and metals (Al, Fe) are mobilized in the A horizon. Solute fluxes that can be related to plant nutrient uptake (Mg, Ca, K) decline with depth as expected from bio-cycling of plant nutrients. Dissolved silica and bicarbonate are minimally influenced by vegetation and represent the largest contributions of solute fluxes. Soil chemical weathering is higher and constant with depth below tussock grasses; while lower and declining with depth under cushion-forming plants. This difference in soil weathering is attributed mainly to the water fluxes. Our findings reveal that vegetation can modify soil properties in the uppermost horizon altering the water balance, solute fluxes, and chemical weathering throughout the soil profile.

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“…All three conditions are characteristics of a large portion of the Norwegian forest soils. In Japan, DOC flux rates from the O horizon were measured to 6-9 g C·m −2 ·year −1 , and of this flux, 0.9-2.8 g C·m −2 ·year −1 percolated into the B horizon (Fujii et al 2011). In the Fichtelgebirge, Bavaria, Germany, it was found that 2-5.5 kg C·m −2 (19%-50% of soil organic C) was sorbed, stabilized DOC in the soil profile (Kaiser and Kalbitz 2012;Kalbitz and Kaiser 2008).…”

Section: Factors Influencing Model Performance -Is Soil Type Important?mentioning

confidence: 99%

Underestimation of boreal forest soil carbon stocks related to soil classification and drainage

et al. 2016

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Soil organic carbon (C), accumulated over millennia, comprise more than half of the C stored in boreal and temperate forest landscapes. We used the Norwegian national forest inventory and soil survey network (n = 719, no deep organic soils) to explore the validity of a deterministic model representation of this pool (Yasso07). We statistically compared simulated and measured soil C stocks and related differences (measured -simulated) to site factors (drainage, topography, climate, vegetation, C-to-N ratio, and soil classification). Median C stocks were 5.0 kg C·m −2 (model) and 14.5 kg C·m −2 (measurements). Soil C differences related to site factors (r 2 of 0.16 to 0.37). For Brunisols, Gleysols, and wet Organic soils, differences related primarily to topographic wetness. For Regosols, Podzols, and Dystric Eluviated Brunisols, they related to climate, profile depth, and, in some cases, drainage class and site index. We argue that soil moisture regimes in our study area overrule tree productivity effects in the determination of soil C stocks and present conditions for soil formation that the model cannot (and does not explicitly) account for. These are processes such as humification and podsolization that involve eluviation and illuviation of dissolved organic C (DOC) with sesquioxides to form spodic B horizons and carbon enrichment due to hampered decomposition in frequently anoxic conditions.Key words: drainage, national forest inventory (NFI), SOC simulation, soil classification, soil-forming factors, soil moisture regime, soil survey, podsolization, Yasso07. Résumé :Le carbone (C) organique du sol accumulé au fil des millénaires correspond à plus de la moitié du C stocké dans les paysages forestiers boréaux et tempérés. Nous avons utilisé l'inventaire forestier national norvégien et le réseau d'inventaire des sols (n = 719, aucun sol organique épais) pour étudier la validité d'une représentation de ce réservoir (Yasso07) à l'aide d'un modèle déterministe. Nous avons statistiquement comparé les stocks de C du sol simulés et mesurés, et relié leurs différences (mesurés -simulés) à des caractéristiques de la station (drainage, topographie, climat, végétation, rapport de C à N et classification du sol). Les stocks médians de C atteignaient 5,0 (simulé) et 14,5 (mesuré) kg C·m -2 . Les différences de C du sol étaient reliées aux caractéristiques des stations (r 2 de 0,16 à 0,37). Pour les brunisols, les gleysols et les sols organiques humides, les différences étaient surtout reliées à l'humidité topographique. Pour les régosols, les podzols et les brunisols dystriques éluviés, les différences étaient reliées au climat, à la profondeur du profil et, dans certains cas, à la classe de drainage et à l'indice de qualité de station. Nous avançons que le régime d'humidité du sol de notre aire d'étude est un facteur plus important que les effets de la productivité ligneuse pour déterminer les stocks de C, et qu'il engendre des conditions de formation des sols dont le modèle ne peut tenir compte et ne tient pas ...

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Fluxes of dissolved organic carbon and nitrogen throughout Andisol, Spodosol and Inceptisol profiles under forest in Japan

Cited by 16 publications

References 52 publications

Dissolved organic carbon (DOC) input to the soil: DOC fluxes and their partitions during the growing season in a cool‐temperate broad‐leaved deciduous forest, central Japan

Dissolved organic carbon (DOC) input to the soil: DOC fluxes and their partitions during the growing season in a cool‐temperate broad‐leaved deciduous forest, central Japan

Soil-vegetation-water interactions controlling solute flow and transport in volcanic ash soils of the high Andes

Underestimation of boreal forest soil carbon stocks related to soil classification and drainage

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