Your search keyword '"Li, Guangde"' showing total 6 results

1. Sintering Temperature and Interphase Effects on Mechanical Properties of an Oxide Fiber-Reinforced Al2O3-SiO2 Composite Fabricated by Sol–Gel Method

Author

Hai-feng Cheng, Zhang Ao, Liu Shaopeng, Yang Xiang, Wang Yi, and Li Guangde

Subjects

0301 basic medicine, Materials science, 030102 biochemistry & molecular biology, Composite number, Sintering, 02 engineering and technology, 021001 nanoscience & nanotechnology, Microstructure, 03 medical and health sciences, Brittleness, Flexural strength, Ceramics and Composites, Interphase, Fiber, Composite material, 0210 nano-technology, Sol-gel

Abstract

Three-dimensional Nextel™ 440 fiber-reinforced Al2O3-SiO2 matrix (N440/Al2O3-SiO2) composites were fabricated by sol–gel method with sintering temperature from 1100 °C to 1400 °C. The interface engineering of the composites was carried out by employing PyC and FC interphase. The microstructure and mechanical properties of the composites were investigated. Results showed that the sintering temperature had remarkable effects on the mechanical properties of the composites. The average flexural strength of the composite without interphase decreased as the temperature increased, with fracture behaviour changing from ductile to brittle, and the highest flexural strength of 90.0 MPa was obtained for the composite fabricated at 1100 °C. However, the flexural strength of the composite with PyC interphase increased initially and then decreased, with fracture behaviour remaining ductile, and the highest flexural strength of 116.3 MPa was obtained for the composite fabricated at 1300 °C. Moreover, PyC and FC interphase could effectively weaken the interfacial bond strength and efficiently promote load transfer, thus improving the strength. For the composite fabricated at 1300 °C, the average flexural strength significantly increased after introducing the optimised PyC and FC interphase.

Published

2021

2. Oxidation behavior and high-temperature flexural property of CVD-SiC-coated PIP-C/SiC composites

Author

Xing Zhong-fang, Cao Jie, Wang Yi, Yi Lu, Sun Bei-zhi, Wen Jin, Xiang Yang, He Heng-ping, Li Guangde, and Zhou Si

Subjects

Materials science, chemistry.chemical_element, 02 engineering and technology, Chemical vapor deposition, engineering.material, 01 natural sciences, chemistry.chemical_compound, Coating, Flexural strength, 0103 physical sciences, Materials Chemistry, Silicon carbide, Composite material, 010302 applied physics, chemistry.chemical_classification, Process Chemistry and Technology, Retention ratio, Polymer, 021001 nanoscience & nanotechnology, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, chemistry, Ceramics and Composites, engineering, 0210 nano-technology, Pyrolysis, Carbon

Abstract

Polymer infiltration pyrolysis (PIP) was used to prepare carbon fiber-reinforced silicon carbide (C/SiC) composites, and chemical vapor deposition (CVD) was employed to fabricate SiC coating. The oxidation behavior at 1700 °C and the flexural property at 1200 °C were tested. SiC coating exerted remarkable oxidation effects on PIP-C/SiC composites. In the absence of coating, PIP-C/SiC composites lost 29.2% of its mass, with merely 6.74% of the original flexural strength retained. In contrast, CVD-SiC coated PIP-C/SiC composites had the mass loss of 10.2% and the flexural strength retention ratio of 23.4%. In high-temperature tests, SiC coating played an important role in the flexural strength of PIP-C/SiC composites. The flexural strength of uncoated composites became 330.7 MPa, and that of coated ones reduced from 655.3 to 531.2 MPa.

Published

2018

3. Effects of irrigation with paper mill effluent on growth and nutrient status ofPopulus tomentosaseedlings

Author

王烨 Wang Ye, 贾黎明 Jia Liming, 崔向东 Cui Xiangdong, Dan Liu, Benye Xi, Guangde Li, Xiangdong Cui, 刘丹 Liu Dan, 席本野 Xi Benye, Jia Liming, 李广德 Li Guangde, 苏曼琳 Su Manlin, and Ye Wang

Subjects

chemistry.chemical_classification, Irrigation, Ecology, biology, Serial dilution, business.industry, Paper mill, biology.organism_classification, Horticulture, Nutrient, chemistry, Wastewater, Agronomy, Seedling, Organic matter, business, Effluent, Ecology, Evolution, Behavior and Systematics

Abstract

The pulp and paper industry is a very large consumer of fresh water,and almost all the input reappears as effluent requiring treatment and disposal.As poplar can recycle organic residues from wastewater due to its high water and nutrient use,paper mill effluent(PME) could serve as a source of water and nutrients for poplar plantations.Consequently,irrigating poplar plantations with PME will reduce the need for other inputs of irrigation and fertilization.However,some elements(e.g.Na) which commonly occur in PME also represent a potential risk to poplar growth,since they have only moderate tolerance to salinity.Improper irrigation can result in toxicities and nutrient imbalance in plants.We hypothesized that diluting PME with pure water to a suitable concentration could avoid negative effects and would have better irrigation and fertilization value.In this study,a pot experiment was conducted from June to September in 2009 to investigate the effect of irrigation with different dilutions of PME on(1) the growth and nutrient status of one-year-old triploid Populus tomentosa seedlings and(2) soil chemical properties.The experiment included five PME irrigation treatments which diluted the concentration of PME to 12.5%(1F7Q),16.7%(1F5Q),25%(1F3Q),33.3%(1F2Q) and 50%(1F1Q),respectively.A control pure water irrigation treatment(CK) was also included.At the end of the experiment,height,ground-level diameter,and biomass of the seedlings in all treatments were measured as indicators of plant growth,total N and P of stems,leaves,and roots were analyzed to indicate plant nutrient status,and soil chemical properties(pH,organic matter,total N,available N and P) were also measured.PME irrigation had no significant effect on the pH and available P content of the soil(P0.05),but percentages of organic matter,total N,and available N increased significantly with increasing concentration of PME(P0.05).With appropriate dilution,PME irrigation significantly increased the N content in roots and leaves and the P content in stems(P0.05),but had no significant influence on the P content in leaves and roots and the N content in stems(P0.05).The growth of P.tomentosa seedlings increased markedly when the concentration of PME increased from 12.5%(1F7Q) to 16.7%(1F5Q),but when the concentration continued to increase(1F3Q,1F2Q,1F1Q),increments in ground-level diameter and height decreased gradually.Relative to the CK treatment,the increment of ground-level diameter and height of P.tomentosa seedlings following only the 1F5Q treatment were significantly higher(102% and 47% respectively,P0.05).Biomass of P.tomentosa seedlings in the 1F5Q and 1F3Q treatments reached 247 and 230 g,respectively,which were significantly higher than the CK treatment(19.3% and 11.1%,P0.05).However,no significant difference was detected between the other PME treatments and CK(P0.05).In conclusion,PME irrigation promoted the growth of P.tomentosa seedlings,and increased plant nutrient status and soil fertility.When the dilution concentration of PME was appropriate,the growth of P.tomentosa seedlings was significantly improved by PME irrigation.Consequently,our findings suggest that PME can be used to irrigate P.tomentosa seedlings,but it should be diluted to an appropriate concentration.From our results,it is recommended that the dilution concentration of PME should be 16%—25%,and trials are needed to validate these conclusions under field conditions.

Published

2013

4. Effects of soil water potential on the growth and physiological characteristics ofPopulus tomentosapulpwood plantation under subsurface drip irrigation

Author

邸楠 Di Nan, 黄祥丰 Huang Xiangfeng, 李广德 Li Guangde, 席本野 Xi Benye, 高园园 Gao Yuanyuan, 王烨 Wang Ye, and 贾黎明 Jia Liming

Subjects

Irrigation, Horticulture, Water potential, Ecology, Field experiment, Soil water, Pulpwood, Sowing, Environmental science, Drip irrigation, Water content, Ecology, Evolution, Behavior and Systematics

Abstract

Subsurface drip irrigation(SDI) is an intensive silvicultural practice which has the potential to increase productivity of triploid Populus tomentosa pulpwood plantations.In order to efficiently apply SDI in the cultivation of P.tomentosa pulpwood plantations,it is necessary to determine irrigation timing.A field experiment was conducted to investigate the effect of soil water potential(ψsoil) on the growth and physiological characteristics of 6—7 year old trees under SDI in a P.tomentosa pulpwood plantation.The experiment included three ψsoil treatments,which initiated irrigation when the ψsoil at 20 cm soil depth and 10 cm distance from a drip emitter reached-25,-50,and-75 kPa,respectively.A control non-irrigation treatment(CK) was also included.Meteorological factors,ψsoil,groundwater level,and tree growth were monitored hourly,daily,every 1—10 days,and monthly for two years,respectively.Soil water content at 20 and 50 cm depth,pre-dawn leaf water potential(ψpd),and trunk sap flow rate were measured in selected periods.Results showed that relative to CK,SDI could improve diameter,height,and individual volume increment of P.tomentosa.Irrespective of SDI treatment,SDI on average increased annual volume growth of the 6-and 7-year-old plantations by 24% and 28%,respectively over the CK treatment.Annual volume growth of the 6-year-old plantation following the-25 kPa treatment reached 39.90 m3 hm-2a-1,which was 43.5% higher than the CK treatment(P0.01).Relative to the-50 and-75 kPa treatments,annual volume growth in the-25 kPa treatment was 20% and 31% higher(P0.01) in the 6-year-old plantation,respectively,and 13% and 14% higher(P0.05) in the 7-year-old plantation,respectively.Relative to CK during the fast growing period(April—July) of P.tomentosa,SDI increased the soil water content at 20 and 50 cm depth by 35% and 27%,respectively;increased average daily trunk sap flow rate(SFmean) by 46%;and increased ψpd by 41%.The ψsoil threshold for initiating irrigation had no significant effect(P0.05) on the SFmean and ψpd of P.tomentosa.However,among the three ψsoil treatments,the average SFmean and ψpd values were highest following the-25 kPa treatment.The increase of soil water availability in the 0—20 cm soil layer(i.e.,active rooting zone) was also greatest in the-25 kPa treatment.These results may explain why the-25 kPa treatment had the highest tree growth rate among the three ψsoil treatments.Overall,the observed increase in soil water content,SFmean,and ψpd indicate that these are the mechanisms by which SDI significantly improves P.tomentosa tree growth.In conclusion,our findings suggest that SDI should be promoted in the cultivation of P.tomentosa pulpwood plantations.To realize optimum tree growth,irrigation should be initiated when the ψsoil at 20 cm depth and 10 cm distance from a drip emitter reaches-25 kPa.Furthermore,it is recommended that irrigation should be applied between April and July,and terminated between August and October when planting P.tomentosa in regions similar to our experimental plantation.

Published

2012

5. Studying the transpiring water consumption of triploidPopulus tomentosaat the individual tree and the stand scale by using the thermal dissipation technology

Author

李广德 LI Guangde, 富丰珍 FU Fengzhen, 席本野 XI Benye, 王烨 WANG Ye, and 贾黎明 JIA Liming

Subjects

Ecology, Ecology, Evolution, Behavior and Systematics

Published

2016

6. Research advances in allelopathy of Quercus L

Author

Li GuangDe, Li XiaoWen, and Jia LiMing

Subjects

Plant ecology, Ecology, Botany, Forestry, Biology, Allelopathy

Abstract

The term allelopathy refers to biochemical interaction between all types of plants including microorganisms through production of chemical compounds that escape into the environment and exist widely in Quercus L. The development of investigations into types of allelochemicals, their compounding and spreading pathways, as well as expression of allelopathy in Quercus L. are reviewed in this paper. We have closely and systematically emphasized the functional mechanisms of allelopathy in forest plants for our next research project on allelopathy in Quercus L.

Published

2007