Chumin Huang scite author profile

Warming may have profound effects on nitrogen (N) cycling by changing plant N demand and underground N supply. However, large uncertainty exists regarding how warming affects the integrated N dynamic in tropical forests. We translocated model plant‐soil ecosystems from a high‐altitude site (600 m) to low‐altitude sites at 300 and 30 m to simulate warming by 1.0°C and 2.1°C, respectively, in tropical China. The effects of experimental warming on N components in plant, soil, leaching, and gas were studied over 6 years. Our results showed that foliar δ15N values and inorganic N (NH4‐N and NO3‐N) leaching were decreased under warming, with greater decreases under 2.1°C of warming than under 1.0°C of warming. The 2.1°C of warming enhanced plant growth, plant N uptake, N resorption, and fine root biomass, suggesting higher plant N demand. Soil total N concentrations, NO3‐N concentrations, microbial biomass N and arbuscular mycorrhizal fungal abundance were decreased under 2.1°C of warming, which probably restricted bioavailable N supply and arbuscular mycorrhizal contribution of N supply to plants. These changes in plants, soils and leaching indicated more closed N cycling under warming, the magnitude of which varied over time. The closed N cycling became pronounced during the first 3 years of warming where the sustained reductions in soil inorganic N could not meet plant N demand. Subsequently, the closed N cycling gradually mitigated, as observed by attenuated positive responses of plant growth and less negative responses of microbial biomass N to warming during the last 3 years. Overall, the more closed N cycling under warming could facilitate ecosystem N retention and affect production in these tropical forests, but these effects would be eventually mitigated with long‐term warming probably due to the restricted plant growth and microbial acclimation.

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Warming changes soil N and P supplies in model tropical forests

Lie

Lin

Huang

et al. 2019

Biol Fertil Soils

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Electrical explosion of aluminum wire for preparation of nanoparticles: an experimental study

Bai¹,

Shi²,

Huang³

et al. 2019

J. Phys. D: Appl. Phys.

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An experimental study on the characteristics of aluminum wire explosion in ambient gas is carried out. A compact experimental device is built to study the electrical parameters, morphology and size distribution of nanoparticles generated by wire explosion. The typical characteristics are obtained and the influence of the type and pressure of the ambient gas is investigated. The explosion process in argon indicates a longer time for breakdown development and larger deposited energy compared with those in helium. It is proposed that these differences are mainly due to different barrier effects on the formation of plasma channel. The nanoparticles formed in helium have a smaller average diameter, a more concentrated size distribution and a larger specific surface area. It is found that there exists a pressure of about 80 kPa, at which both the peak voltage and deposited energy possess the maximum values.

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Research on discharge and radiation characteristics of multi-electrode high power pulsed xenon flash lamp

Jia¹,

Mo²,

Huang³

et al. 2019

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Functional Composition Changes of a Subtropical Monsoon Evergreen Broad-Leaved Forest Under Environmental Change

Zou

Zhang

Zhou

et al. 2020

Forests

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Long-term studies have revealed that forest species composition was shifting under environment change and disturbance induced by loss of large trees. Yet, few studies explicitly analyzed their impacts on composition concurrently. To learn more about impacts of environment change and disturbance on driving forest community, we investigated shifts in functional composition over past 24 years in an old-growth subtropical forest in southern China. We analyzed nine traits that are mainly related to leaf nutrients, photosynthetic capacity, hydraulic conductivity, and drought tolerance of plants and examined hypotheses: (1) The functional composition change over time was directional instead of random fluctuation, (2) drought-tolerant species increased their abundance under soil dryness, (3) both environmental change and disturbance related to changes of functional composition significantly, and (4) initial trait values of quadrats strongly influenced their subsequent change rates in quadrat level (10 × 10 m). We found that species composition had shifted to favor species with high leaf nutrient content, high photosynthesis rate, high hydraulic conductivity, low water-use efficiency, and high drought tolerance traits, which was due to soil dryness and disturbance. These two factors explained 47–58% of quadrats’ trait value changes together. Considering rapidly increasing stem density, this pattern may indicate ecological processes of which disturbance provided numerous recruits of resource-acquisition strategy species and soil dryness conducted a selecting effect on shaping composition in the forest. Additionally, quadrats with initial trait values at the far end of change direction shifted faster in three traits, which also indicated that functional composition changes in quadrats were directional and homogenized. Our results implied that environment change and accompanied disturbance events possibly drove species composition change along a different trajectory in the subtropical forest that experienced high climatic variability.

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Chumin Huang

Warming leads to more closed nitrogen cycling in nitrogen‐rich tropical forests

Warming changes soil N and P supplies in model tropical forests

Electrical explosion of aluminum wire for preparation of nanoparticles: an experimental study

Research on discharge and radiation characteristics of multi-electrode high power pulsed xenon flash lamp

Functional Composition Changes of a Subtropical Monsoon Evergreen Broad-Leaved Forest Under Environmental Change

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