Allometric equations to assess biomass, carbon and nitrogen content of black pine and red pine trees in southern Korea

Kim, Choonsig; Yoo, Byung Oh; Jung, Su Young; Lee, K.S.

doi:10.3832/ifor2164-010

Cited by 13 publications

(12 citation statements)

References 29 publications

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“…In regard to the contribution of CWD to N input in this study site, annual N input from CWD caused by annual tree mortality comprised approximately 11.1% of total N stock in CWD, and comprised less than 3.5% of 65.65 kg N ha −1 year −1 from total fine litterfall, indicating less contribution of CWD to N cycles than fine litter. However, the forests have a potential for the rapid increase in the amount of CWD following tree mortality, because the red pine forests have been widely threatened by severe pine wilt disease across the Eastern Asian countries [20,21].…”

Section: And N Contents Of Cwdmentioning

confidence: 99%

Carbon and Nitrogen Accumulation and Decomposition from Coarse Woody Debris in a Naturally Regenerated Korean Red Pine (Pinus densiflora S. et Z.) Forest

Noh

Yoon

Kim

et al. 2017

Forests

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Abstract:The contribution of coarse woody debris (CWD) to forest carbon (C) and nitrogen (N) dynamics is poorly quantified. This study quantified total C and N content in CWD and estimated the decomposition rates of CWD at different decay stages in a 70-year-old naturally regenerated Korean red pine forest (Pinus densiflora S. et Z.). The N concentration in CWD varied among species and decay classes (from 0.15% to 0.82%), and exhibited a decreasing pattern in C:N ratios with increasing decay class. Total CWD amounts of 4.84 Mg C ha −1 , dominated by pine logs (45.4%) and decay class III (40.0%), contained total N of 20.48 kg N ha −1 , which was approximately nine times the N input from annual tree mortality. In addition, this study demonstrated that the decay constant rate k was 0.2497 for needle litter, whereas k values were 0.0438, 0.0693, 0.1054, and 0.1947 for red pine CWD of decay class I, II, III, and IV, respectively. The decay rates were significantly related to wood density, N concentration, and C:N ratio across the decay classes of CWD. The results suggest that the C:N ratio of CWD is a key factor affecting its decomposition.

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Section: And N Contents Of Cwdmentioning

confidence: 99%

Carbon and Nitrogen Accumulation and Decomposition from Coarse Woody Debris in a Naturally Regenerated Korean Red Pine (Pinus densiflora S. et Z.) Forest

Noh

Yoon

Kim

et al. 2017

Forests

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“…The living standing trees of mature forest are in the peak period of growth, with large quantity and high quality, while the number of living standing trees of young forest is small and the quality is low. The lignification degree of standing trees in middle-aged and near-mature forests is higher, and the carbon content is also higher, while the lignification degree of standing trees in young and near-mature forests is lower, and the carbon content is also lower (Kim et al, 2017;Dong et al, 2018). These findings are important for understanding the dynamics and management of forest carbon pools.…”

Section: Analysis Of Carbon Characteristics Of Living Wood Shrub Gras...mentioning

confidence: 89%

Carbon storage and carbon pool characteristics of Larix gmelinii forest in Daxing’anling, Inner Mongolia, China

Zhao,

Yue,

Qin

et al. 2024

Front. For. Glob. Change

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Larix gmelinii is an important ecological construction tree species in northern China, and its carbon storage and distribution characteristics are of great significance for evaluating the carbon balance and climate effect of forest ecosystems. However, at present, there is a lack of systematic research on the carbon storage of L. gmelinii forests and its change with forest age. In this paper, the biomass and carbon density of L. gmelinii forests at different ages and the distribution of carbon storage in vegetation and soil were analyzed by means of sample plot investigation and model simulation in the northern forest area of Daxing’anling, Inner Mongolia. The influence of forest age on the carbon storage and carbon pool distribution characteristics of L. gmelinii forests and the mechanism of influencing factors were also discussed. Results show that: (1) As forest age increased, the total amount of carbon pools initially increased and then decreased, and the distribution structure of carbon pools showed a trend of transferring from soil to trees. The proportion of soil carbon pools gradually decreased (72.72–51.87%), while the proportion of tree carbon pools gradually increased (23.98–39.33%). The proportion of shrub and grass carbon pools was also relatively stable (0.51–0.53%). (2) Soil carbon pool was affected by the input and output of soil organic matter, soil depth, soil carbon content, and soil bulk density, shrub–grass carbon pool was affected by undergrowth light conditions and soil moisture, litter carbon pool was affected by litter input and output, and the carbon pool of trees was affected by the growth rate and carbon balance of trees. This study provides scientific basis and management suggestions for the carbon storage capacity of L. gmelinii forests and the mitigation of climate change.

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“…The variations in the C and N concentrations of the litterfall components are mainly determined by the species and sampling months (Thomas, Martin 2012;Kim et al 2019;See et al 2019;Erkan et al 2020). Many studies have reported that the C concentration of the litterfall is negatively correlated with the N and positively correlated with the lignin concentration (Macinnis-Ng, Schwendenmann 2015; Kim et al 2017;See et al 2019). In this study, the higher C concentration of the leaf litter in the P. densiflora than in the Q. variabilis stands could be due to the difference in the lignin and N concentrations determined by the genetic factors between the tree species (Thomas, Martin, 2012;See et al 2019).…”

Section: Discussionmentioning

confidence: 99%

Comparisons of carbon and nitrogen dynamics of litterfall components in adjacent Pinus densiflora and Quercus variabilis stands

Choi¹,

Baek²,

Kim³

et al. 2022

J. For. Sci.

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This study aimed to determine the effects of the stand and month on the carbon (C) and nitrogen (N) concentrations and the inputs of the litterfall components in adjacent Pinus densiflora and Quercus variabilis stands. The monthly C concentrations of the litterfall components were significantly higher in the P. densiflora stand than in the Q. variabilis stand, whereas the monthly N concentrations of the leaf and miscellaneous litter were higher in the Q. variabilis stand than in the P. densiflora stand. The coefficient variations of the N concentrations were higher than those of C concentrations of the litterfall components. The monthly C and N inputs of the leaf litter showed a unimodal pattern in the Q. variabilis stand, whereas multimodal patterns in the P. densiflora stand could be seen. The annual total C inputs were not significantly different between the P. densiflora [2 691 kg(C)·ha–1·yr–1] and Q. variabilis [2 439 kg(C)·ha–1·yr–1] stands. However, the annual total N inputs were significantly higher in the Q. variabilis [44.5 kg(N)·ha–1·yr–1] stand than in the P. densiflora [38.6 kg(N)·ha–1·yr–1] stand. These results indicate that the C and N dynamics in the litterfall components were affected by the species and sampling months in adjacent P. densiflora and Q. variabilis stands.

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Allometric equations to assess biomass, carbon and nitrogen content of black pine and red pine trees in southern Korea

Cited by 13 publications

References 29 publications

Carbon and Nitrogen Accumulation and Decomposition from Coarse Woody Debris in a Naturally Regenerated Korean Red Pine (Pinus densiflora S. et Z.) Forest

Carbon and Nitrogen Accumulation and Decomposition from Coarse Woody Debris in a Naturally Regenerated Korean Red Pine (Pinus densiflora S. et Z.) Forest

Carbon storage and carbon pool characteristics of Larix gmelinii forest in Daxing’anling, Inner Mongolia, China

Comparisons of carbon and nitrogen dynamics of litterfall components in adjacent Pinus densiflora and Quercus variabilis stands

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