Your search keyword '"Wan, Songze"' showing total 8 results

1. Contrasting responses of soil phosphorus pool and bioavailability to alder expansion in a boreal peatland, Northeast China.

Author

Wan, Songze, Lin, Guigang, Liu, Bo, Ding, Yidong, Li, Suli, and Mao, Rong

Subjects

*PLANT biomass, *PHOSPHORUS in soils, *ACID phosphatase, *ALDER, *ACID soils

Abstract

• Alder expansion reduced soil P pool in the 0–40 cm depth. • Total P concentration increased in surface soils but reduced in deep soils after alder expansion. • Alder expansion increased plant-available P fractions by elevating acid phosphatase activity. • Alder expansion caused about ninefold increase in aboveground plant biomass. Dinitrogen (N 2)-fixing woody plants, mainly alder (Alnus) species, have widely expanded to boreal peatlands. However, little is known about the effect of N 2 -fixing plant expansion on soil phosphorus (P) dynamics and its potential mechanisms in these ecosystems. To clarify the response of soil P status to N 2 -fixing plant expansion, we compared the differences in aboveground plant biomass, soil total P pool, acid phosphatase activity, P sorption index, and four bioavailable P fractions (CaCl 2 , citrate, phosphatase enzyme, and HCl extractable P fractions) in the 0–10 cm, 10–20 cm, and 20–40 cm depths between A. sibirica islands and adjacent open peatlands in a boreal peatland, Northeast China. While alder expansion hardly affected bulk density and associated volume of the peats, it strongly decreased total P pool in the 0–40 cm soil depth because of approximately ninefold increases in aboveground plant biomass and associated P transfer from soils to plants. Soil total P concentration increased in the 0–10 cm depth, but declined in the 10–20 cm and 20–40 cm depths. At each depth, alder expansion increased soil acid phosphatase activity, and CaCl 2 and enzyme extractable P fractions, despite unchanged P sorption index and citrate extractable P fraction. Both CaCl 2 and enzyme extractable P fractions correlated positively with acid phosphatase activity, indicating that increased P bioavailability was primarily caused by elevated microbial mineralization of organic P. These findings highlight the contrasting responses of soil P pool and bioavailability to N 2 -fixing tree expansion, and suggest that N 2 -fixing tree expansion would reduce soil P pool via enhanced P bioavailability and subsequently increased plant P uptake in boreal peatlands. [ABSTRACT FROM AUTHOR]

Published

2022

2. Contributions of Understory and/or Overstory Vegetations to Soil Microbial PLFA and Nematode Diversities in Eucalyptus Monocultures.

Author

Zhao, Jie, Wan, Songze, Zhang, Chenlu, Liu, Zhanfeng, Zhou, Lixia, and Fu, Shenglei

Subjects

*SOIL microbiology, *NEMATODES, *EUCALYPTUS, *PLANT diversity, *SOIL biodiversity, *FATTY acids, *ECOSYSTEMS

Abstract

Ecological interactions between aboveground and belowground biodiversity have received many attentions in the recent decades. Although soil biodiversity declined with the decrease of plant diversity, many previous studies found plant species identities were more important than plant diversity in controlling soil biodiversity. This study focused on the responses of soil biodiversity to the altering of plant functional groups, namely overstory and understory vegetations, rather than plant diversity gradient. We conducted an experiment by removing overstory and/or understory vegetation to compare their effects on soil microbial phospholipid fatty acid (PLFA) and nematode diversities in eucalyptus monocultures. Our results indicated that both overstory and understory vegetations could affect soil microbial PLFA and nematode diversities, which manifested as the decrease in Shannon–Wiener diversity index (H′) and Pielou evenness index (J) and the increase in Simpson dominance index (λ) after vegetation removal. Soil microclimate change explained part of variance of soil biodiversity indices. Both overstory and understory vegetations positively correlated with soil microbial PLFA and nematode diversities. In addition, the alteration of soil biodiversity might be due to a mixing effect of bottom-up control and soil microclimate change after vegetation removal in the studied plantations. Given the studied ecosystem is common in humid subtropical and tropical region of the world, our findings might have great potential to extrapolate to large scales and could be conducive to ecosystem management and service. [ABSTRACT FROM AUTHOR]

Published

2014

3. Dicranopteris-dominated understory as major driver of intensive forest ecosystem in humid subtropical and tropical region

Author

Zhao, Jie, Wan, Songze, Li, Zhi’an, Shao, Yuanhu, Xu, Guoliang, Liu, Zhanfeng, Zhou, Lixia, and Fu, Shenglei

Subjects

*FOREST management, *FOREST litter decomposition, *SOIL moisture, *NEMATODES, *SOIL physics

Abstract

Abstract: Dicranopteris is a common fern distributed throughout tropical and subtropical regions of the world. It often forms a mat-like understory, especially in open areas. A forest floor dominated by Dicranopteris plays an important role in ecosystem dynamics, but is often overlooked in ecological research. We conducted an experiment by removing overstory or understory Dicranopteris to compare their effects on soil microclimate, litter decomposition, soil decomposer food web and ecosystem nutrient cycling. Results of our field study showed that removal of a Dicranopteris-dominated understory leads to increased soil temperature and reduced soil moisture, subsequently, altering the components of the soil food web (microbial community, nematode and microarthropod densities) and reducing ecosystem processes of litter decomposition. When present, Dicranopteris forms a dense understory layer in subtropical and tropical regions, which is favorable for sustaining soil microclimates and acts as the major driver of soil biota and ecological processes in intensive forest ecosystems. [Copyright &y& Elsevier]

Published

2012

4. Bark controls tree branch-leached dissolved organic matter production and bioavailability in a subtropical forest.

Author

Xu, Jia-Wen, Yang, Na, Shi, Fu-Xi, Zhang, Yun, Wan, Songze, and Mao, Rong

Subjects

*DISSOLVED organic matter, *BARK, *BIOAVAILABILITY, *DECIDUOUS plants, *TREE branches, *TREES

Abstract

Bark is an essential component of tree branches, yet its role in controlling branch-leached dissolved organic matter (DOM) characteristics remains unknown in forests. Here, we collected branches (about 1.5 cm in diameter) of two evergreen coniferous trees, two deciduous broadleaf trees, and three evergreen broadleaf trees from a subtropical forest in southern China, and subsequently used a bark removal experiment to determine the effects of bark on branch-derived DOM quantity and bioavailability. Regardless of tree type, the presence of bark reduced tree branch-leached dissolved organic carbon (DOC), dissolved total nitrogen (DTN), and dissolved total phosphorus (DTP) productions. Moreover, DOC, DTN, and DTP productions leached from the branches containing bark were always much lower than the expected values summed from barks and the branches without bark. The presence of bark increased DOM aromaticity in the broadleaf tree branch leachates but reduced DOM aromaticity in the coniferous tree branch leachates. During 42 days of incubation, the presence of bark decreased broadleaf tree branch-leached DOM bioavailability and the relative increments of aromaticity, whereas the opposite trends were observed for the coniferous tree branch-leached DOM. Tree branch-derived DOM bioavailability correlated negatively with SUVA254 values, but exhibited no relationship with either DOC:DTN ratio or DOC:DTP ratio. These observations highlight that tree bark can prevent DOM leaching from branches and regulate branch-leached DOM bioavailability via its effect on DOM aromaticity in subtropical forests. [ABSTRACT FROM AUTHOR]

Published

2022

5. Navel orange fine root nutrient content and rhizosphere effects varied with tree ages and soil depths in a hilly red soil region of China.

Author

Guo, Chunlan, Chen, Fusheng, Li, Jianwei, Fang, Xiangmin, Wan, Songze, and Zhang, Lvshui

Subjects

*RED soils, *SOIL depth, *TREE age, *RHIZOSPHERE, *ROOT development, *ORANGES

Abstract

Root nutrients are required for the growth and development of roots and shoots, which are closely related to soil quality and fruit productivity. In this study, trees of contrasting stand ages, including young, middle-aged, and old trees, were selected in field sites with common management practices in the navel orange (Citrus sinensis) orchards of Southern China. The fine root N decreased with soil depth and the fine root P was higher of old trees (1.82 g kg-1) than young (1.57 g.kg-1) and middle-aged trees (1.37 g. kg-1). Soil organic C, total N, and P generally increased with plant age in the rhizosphere and bulk soils, while reverse trend was found for sucrase and urease activities. Interestingly, acid phosphatase activity was much higher at a lower depth (202 and 82 g.kg-1 OC d-1 for rhizosphere and bulk soils, respectively) than at an upper depth (46 and 43 g.kg-1 OC d-1 for rhizosphere and bulk soils, respectively). In conclusion, root and soil nutrients generally increased with plant growth. Fine root N decreased while fine root P remained unchanged with soil depth due to the content and rhizosphere effect of index at different soil layers related to N and P, respectively. [ABSTRACT FROM AUTHOR]

Published

2021

6. How understory vegetation affects the catalytic properties of soil extracellular hydrolases in a Chinese fir (Cunninghamia lanceolata) forest.

Author

Yang, Yang, Zhang, Xinyu, Wang, Huimin, Fu, Xiaoli, Wen, Xuefa, Zhang, Chuang, Chen, Fusheng, and Wan, Songze

Subjects

*CHINA fir, *HYDROLASES, *SOIL enzymology, *CATALYTIC activity, *BIOMASS energy

Abstract

Abstract To study how the understory vegetation influences the catalytic properties of extracellular hydrolases, we established a paired treatment experiment, with understory vegetation and litter removed from one treatment (understory removal, UR) and litter removed and the understory vegetation left intact in the other (control, CK), in a subtropical Chinese fir (Cunninghamia lanceolata) plantation. We used fluorescent substrates to determine the maximum velocity (V max), the affinity of hydrolases to the substrates (K m), and the catalytic efficiency (V max /K m) of three extracellular hydrolases (β-1,4-glucosidase (βG), β-1,4-N-acetylglucosaminidase (NAG) and acid phosphatase (AP)). We found that the V max values for βG and NAG were 23.0% and 16.8% lower, respectively, in the UR treatment than in the CK treatment, and that the V max for AP was similar in both treatments. The K m and V max /K m for all the three hydrolases remained steady after the understory vegetation was removed. The soil C and N contents and the bacterial and fungal biomass were generally positively correlated with the V max values. Thus, understory vegetation had more influence on the activities (V max) than on the substrate affinities of extracellular hydrolases (K m). Microbes tended to concentrate on maintaining the catalytic efficiency when the SOC contents were between 15.8 and 20.3 g kg−1 when the understory vegetation was removed from a subtropical Chinese fir forest, and the catalytic efficiency could decrease under extremely low soil C contents. We suggest that understory vegetation should be maintained to sustain the potential microbial activity in subtropical Chinese fir forests. Highlights • The V max of βG and NAG, but not AP, decreased when understory vegetation was removed. • The K m and V max / K m values did not change when understory vegetation was removed. • Soil C and N and microbial biomass were mainly positively related to the V max. • Understory vegetation should be maintained to sustain potential microbial activity. [ABSTRACT FROM AUTHOR]

Published

2019

7. Effects of spent mushroom substrate-derived biochar on soil CO2 and N2O emissions depend on pyrolysis temperature.

Author

Deng, Bangliang, Shi, Yanzhen, Zhang, Ling, Fang, Haifu, Gao, Yu, Luo, Laicong, Feng, Weixun, Hu, Xiaofei, Wan, Songze, Huang, Wei, Guo, Xiaomin, and Siemann, Evan

Subjects

*BIOCHAR, *GREENHOUSE gas mitigation, *SOIL composition, *FOREST soils, *EDIBLE mushrooms

Abstract

Edible mushroom cultivation is an important industry in intensively managed forest understories. However, proper disposal of spent mushroom substrate (SMS) presents a challenge to its sustainable development. Biochar derived from SMS could be used to improve soil quality while providing a solution for SMS disposal. But SMS biochar pyrolyzed at different temperatures may alter carbon dioxide (CO 2) and nitrous oxide (N 2 O) emissions associated with global warming, especially under the context of nitrogen (N) addition and warming. We conducted a factorial incubation study to examine greenhouse gas emissions and N transformations in moso bamboo forest soil amended with SMS-biochar (control vs. pyrolyzed at 300, 450 or 600 °C) in different N-addition (0 or 100 mg N kg-1 soil) and temperature (20, 25 or 30 °C) treatments. Pyrolysis temperature affected pH, C and N of SMS-biochars. N-transformations depended on the interaction of pyrolysis temperature, N-addition, and incubation temperature but were generally lower with 450 °C biochar addition. Soil N 2 O emissions increased with N-addition and they were more sensitive to incubation temperatures without biochar. Soil CO 2 emissions increased with incubation temperature or biochar pyrolyzed at lower temperatures. Pyrolysis temperature might have regulated the effects of SMS-derived biochar on N 2 O emissions via changes in dissolved C, N, pH and associated changes in soil microbial community compositions. Because of the importance of sustainable development of this understory industry, amending soils with biochar produced at higher temperatures may be the best strategy for both the disposal of SMS and the mitigation of greenhouse gas emissions. Image 1 • PH of spent mushroom substrate (SMS) biochar increased with pyrolysis temperature. • SMS-biochar reduced the temperature sensitivity of soil N 2 O emission rates. • Lower pyrolysis temperature SMS-biochar increased CO 2 emissions. • Spent mushroom substrate biochar pyrolyzed at 450 °C decreased nitrification rate. [ABSTRACT FROM AUTHOR]

Published

2020

8. Invariant community structure of soil bacteria in subtropical coniferous and broadleaved forests.

Author

Wang, Xiaoli, Wang, Xiaoling, Zhang, Weixin, Shao, Yuanhu, Zou, Xiaoming, Liu, Tao, Zhou, Lixia, Wan, Songze, Rao, Xingquan, Li, Zhian, and Fu, Shenglei

Published

2016