Background: For various reasons such as agricultural and economical purposes, land-use changes are rapidly increasing not only in Korea but also in the world, leading to shifts in the characteristics of local carbon cycle.
Therefore, in order to understand the large-scale ecosystem carbon cycle, it is necessary first to understand vegetation on this local scale. As a result, it is essential to comprehend change of the carbon balance attributed by the land-use changes. In this study, we attempt to understand accumulated soil carbon (ASC) and soil respiration (Rs) related to carbon cycle in two ecosystems, artificially turned forest into pastureland from forest and a native deciduous temperate forest, resulted from different land-use in the same area.








Results: Rs were shown typical seasonal changes in the alpine pastureland (AP) and temperate deciduous forest (TDF). The annual average Rs was 160.5 mg CO2 m− 2 h− 1 in the AP, but it was 405.1 mg CO2 m− 2 h− 1 in the TDF, indicating that the Rs in the AP was lower about 54% than that in the TDF. Also, ASC in the AP was 124.49 Mg C ha− 1 from litter layer to 30-cm soil depth. The ASC was about 88.9 Mg C ha− 1, and it was 71.5% of that of the AP. The temperature factors in the AP was high about 4 °C on average compared to the TDF. In AP, it was observed high amount of sunlight entering near the soil surface which is related to high soil temperature is due to low canopy structure. This tendency is due to the smaller emission of organic carbon that is accumulated in the soil, which means a higher ASC in the AP compared to the TDF.








Conclusions: The artificial transformation of natural ecosystems into different ecosystems is proceeding widely in the world as well as Korea. The change in land-use type is caused to make the different characteristics of carbon cycle and storage in same region. For evaluating and predicting the carbon cycle in the vegetation modified by the human activity, it is necessary to understand the carbon cycle and storage characteristics of natural ecosystems and converted ecosystems. In this study, we studied the characteristics of ecosystem carbon cycle using different forms in the same region. The land-use changes from a TDF to AP leads to changes in dominant vegetation. Removal of canopy increased light and temperature conditions and slightly decreased SMC during the growing season. Also, land-use change led to an increase of ASC and decrease of Rs in AP. In terms of ecosystem carbon sequestration, AP showed a greater amount of carbon stored in the soil due to sustained supply of above-ground liters and lower degradation rate (soil respiration) than TDF in the high mountains. This shows that TDF and AP do not have much difference in terms of storage and circulation of carbon because the amount of carbon in the forest biomass is stored in the soil in the AP.

1 한봉호, "강원도 대관령 목장 현존식생 및 식물군집구조" 한국환경생태학회 27 (27): 579-591, 2013

2 Raich, J. W., "Vegetation and soil respiration: correlations and controls" 48 : 71-90, 2000

3 Fierer, N., "Variations in microbial community composition through two soil depth profiles" 35 : 167-176, 2003

4 Pregitzer, K. S., "Variation in sugar maple root respiration with root diameter and soil depth" 18 : 665-670, 1998

5 Protocol, K., "United Nations framework convention on climate change" 1997

6 Batjes, N. H., "Total carbon and nitrogen in the soils of the world" 65 : 10-21, 2014

7 Jobbagy, E. G., "The vertical distribution of soil organic carbon and its relation to climate and vegetation" 10 : 423-436, 2000

8 Wildung, R. E., "The interdependent effects of soil temperature and water content on soil respiration rate and plant root decomposition in arid grassland soils" 7 : 373-378, 1975

9 Sheng, H. A. O., "The dynamic response of soil respiration to land-use changes in subtropical China" 16 : 1107-1121, 2010

10 Houghton, R. A., "The annual net flux of carbon to the atmosphere from changes in land use 1850-1990" 51 : 298-313, 1999

11 Xu, Z., "Temperature sensitivity of soil respiration in China's forest ecosystems: Patterns and controls" 93 : 105-110, 2015

12 Davidson, E., "Soil water content and temperature as independent or confounded factors controlling soil respiration in a temperate mixed hardwood forest" 4 : 217-227, 1998

13 Wang, C., "Soil respiration in six temperate forests in China" 12 : 2103-2114, 2006

14 Vesterdal, L., "Soil respiration and rates of soil carbon turnover differ among six common European tree species" 264 : 185-196, 2012

15 Wang, G., "Soil organic carbon pool of grassland on the Qinghai-Tibetan plateau and its global implication" 291 : 207-217, 2002

16 Guo, L. B., "Soil carbon stocks and land use change: a meta analysis" 8 : 345-360, 2002

17 Hu, C., "Soil carbon stock and flux in plantation forest and grassland ecosystems in Loess Plateau, China" 24 : 423-435, 2014

18 Epron, D., "Soil $CO_2$ efflux in a beech forest: dependence on soil temperature and soil water content" 56 : 221-226, 1999

19 Lloyd, J., "On the temperature dependence of soil respiration" 8 : 315-323, 1994

20 Luyssaert, S., "Old-growth forests as global carbon sinks" 455 : 213-215, 2008

21 Canadell, J., "Maximum rooting depth of vegetation types at the global scale" 108 : 83-595, 1996

22 Climatological Normals of Korea, "Korea meteorological administration" 2011

23 Hooper, D. U., "Interactions between aboveground and belowground biodiversity in terrestrial ecosystems: patterns, mechanisms, and feedbacks" 50 : 1049-1061, 2000

24 White, R. P., "Grassland ecosystems" 81-, 2000

25 Davidson, E. A., "Effects of soil water content on soil respiration in forests and cattle pastures of eastern Amazonia" 48 : 53-69, 2000

26 Suseela, V., "Effects of soil moisture on the temperature sensitivity of heterotrophic respiration vary seasonally in an old-field climate change experiment" 18 : 336-348, 2012

27 Ohashi, M., "Contribution of root respiration to total soil respiration in a Japanese cedar (Cryptomeria japonica D. Don) artificial forest" 15 : 323-333, 2000

28 Pumpanen, J., "Comparison of different chamber techniques for measuring soil $CO_2$ efflux" 123 : 159-176, 2004

29 Wu, Y., "Comparing soil $CO_2$ emission in pine plantation and oak shrub: dynamics and correlations" 21 : 840-848, 2006

30 Pachauri, R. K., "Climate change 2014: synthesis report. Contribution of working groups I, II and III to the fifth assessment report of the intergovernmental panel on climate change" IPCC Secretariat 2014

31 Kellman, L., "Changes in seasonal soil respiration with pasture conversion to forest in Atlantic Canada" 82 : 101-109, 2007

32 Paul, K. I., "Change in soil carbon following afforestation" 168 : 241-257, 2002

33 Michelsen, A., "Carbon stocks, soil respiration and microbial biomass in fire-prone tropical grassland, woodland and forest ecosystems" 36 : 1707-1717, 2004

34 Dixon, R., "Carbon pools and flux of global forest ecosystems" 263 : 185-190, 1994

35 Musselman, R. C., "A review of the role of temperate forests in the global $CO_2$ balance" 41 : 798-807, 1991

36 Suh, S. U., "A chamber system with automatic opening and closing for continuously measuring soil respiration based on an open-flow dynamic method" 21 : 405-414, 2006