N2O profiles in the enhanced CANON process via long-term N2H4 addition: minimized N2O production and the influence of exogenous N2H4 on N2O sources

Environmental Science and Pollution Research - Production of the greenhouse gas nitrous oxide (N2O) from the completely autotrophic nitrogen removal over nitrite (CANON) process is of growing...     

多循环CCRs法在分离燃煤锅炉尾部烟气中CO2方面的应用

随着温室效应和全球变暖的加剧,煤燃烧所排出的CO2作为引起温室效应的主要气体而引起人们的密切关注.由于燃煤锅炉所排放的尾气中所含的CO2的体积份额低、排放量大,而且处于微负压状态,因此目前控制和分离吸收CO2的方法,包括各类吸收法、吸附法、膜分离法和O2/CO2燃烧技术等,能够经济可行地适用于电力工业燃煤锅炉尾部烟气中CO2分离的方法非常少.与上述各类方法相比,钙基吸收剂CCRs(calcination/carbonation reactions)法是一种新兴的经济可行的分离燃煤锅炉尾部烟气中CO2的方法.对采用该法时,吸收剂的选择、吸收剂在多次CCRs过程中结构特点的变化、提高吸收剂对CO2的吸收容量以及防止吸收剂反应性的衰减等方面进行了详细的阐述.     

丁草胺对镉胁迫条件下水稻生长、镉积累及活性氧代谢的影响

以2个水稻品种(秀水110和秀水11)为材料,通过水培试验和土培试验研究了除草剂丁草胺对Cd2 胁迫条件下水稻植株生长、Cd2 积累和活性氧代谢的影响.研究结果表明.水培条件下,丁草胺浓度的增加显著地加剧了Cd2 胁迫条件下水稻生长抑制程度,进一步导致叶绿素含量显著下降,促进了2个品种水稻植株对Cd2 的吸收,引起水稻叶片的O-2产生速率、H202和MDA含量增加.且显著改变了SOD、CAT和G-POD活性;同条件下丁草胺浓度的增加使水稻叶片SOD/O-2、SOD/G-POD、SOD/CAT、CAT/H2O2和G-POD/H2O2的比值均发生了偏离;推测丁草胺加剧了水稻Cd2 胁迫时植株活性氧代谢不平衡过程.土培条件下,丁草胺对水稻糙米中Cd2 积累量也具有显著促进作用.     

胺基膦酸型离子交换(螯合)纤维酸碱性研究

通过电位滴定实验求定了氨基膦酸型螯合纤维的表面质子电荷密度σｓ、零电点ｐＨ（ＰＺＣ）的表面总吸附位Ｎｓ。并尝试了运用表面络合恒定容量模式求解此螯合纤维的表面固有酸度常数ｐＫａ１和ｐＫａ２。     

多循环CCRs法在分离燃煤锅炉尾部烟气中CO2方面的应用

随着温室效应和全球变暖的加剧，煤燃烧所排出的CO2作为引起温室效应的主要气体而引起人们的密切关注。由于燃煤锅炉所排放的尾气中所含的CO2的体积份额低、排放量大，而且处于微负压状态，因此目前控制和分离吸收CO2的方法，包括各类吸收法、吸附法、膜分离法和O2／CO2燃烧技术等，能够经济可行地适用于电力工业燃煤锅炉尾部烟气中CO2分离的方法非常少。与上述各类方法相比，钙基吸收剂CCRs（calcination／carbonation reactions）法是一种新兴的经济可行的分离燃煤锅炉尾部烟气中CO2的方法。对采用该法时，吸收剂的选择、吸收剂在多次CCRs过程中结构特点的变化、提高吸收剂对CO2的吸收容量以及防止吸收剂反应性的衰减等方面进行了详细的阐述。     

植物促生菌应用研究进展

植物促生菌即PGPB不仅在农业生产中促进植物生长以及防治植物病害,还逐渐应用于环境保护方面。文章从以下几方面就PGPB的研究进展进行了综述,包括PGPB在农业和环境中的应用、PGPB内生菌、生物防治型PGPB、PGPB的基因工程改良、PGPB剂型等。最后展望了该领域的研究方向。     

广州南沙红树林湿地鸟类群落多样性(2005～2010)

为探讨城市化对鸟类群落的影响,2005～2010年对广州南沙红树林湿地鸟类群落多样性进行了研究.结果表明:共记录鸟类149种,隶属于16目42科97属;其中冬候鸟或旅鸟77种,占51.7%,留鸟63种,占42.3%,夏候鸟9种,占6.0%;鸟类群落呈现出较强的季节性,从总体上看,物种数和总数量呈现秋冬季高峰,夏季最低.红树林湿地区具有最高的鸟类物种多样性与科属多样性,物种多样性和科属多样性变化趋势表现为红树林湿地区>河涌林带区>水域区.南沙红树林湿地的保护对丰富鸟类群落多样性具有重要作用.     

Species-specific effects of P-solubilizing and N<Subscript>2</Subscript>-fixing bacteria on seedling growth of three salt-tolerant trees

Coastal afforestation suffers from low survival and slow growth due to harsh conditions and lack of robust seedlings. Inoculation of P-solubilizing bacteria (PSB) or N₂-fixing bacteria (NFB) are effective in promoting plant growth and thus potentially helpful for coastal afforestation. However, it remains unclear about the generality and specificity of these plant-growth-promoting-bacteria (PGPB) on the growth of salttolerant trees. We inoculated seedlings of two mangrove trees and one terrestrial salt-tolerant tree with pure cultures of PSB or mixed cultures of PSB and NFB. Plant biomass, height, base diameter and N and P concentrations were determined six months after bacterial inoculation. We found that inoculation of PGPB had an overall promoting effect on the seedling growth of three tree species, but the effects differed greatly (3–280% increase) among plant species and bacterial isolates or bacterial combinations. Only in the terrestrial tree, co-inoculations of PSB and NFB showed greater promoting effects than monocultures of PSB. Root: shoot ratios of seedlings were not changed by bacterial inoculation. Inoculation treatments moderately elevated N concentrations in shoots and roots and P concentrations only in roots of seedlings. Our results suggest that PGPB might have a general promoting effect on the seedling growth of salt-tolerant trees. Nevertheless, the magnitude of promoting effects and the comparative advantage of dual inoculation over single inoculation are species-specific. The generality and specificity of the plant-PGPB relationship are similar to the plantmycorrhizal symbiosis. In addition, tissue nutrient improvement might not be the main mechanism of the promoting effects by PGPB.     

Sulfur evolution in chemical looping combustion of coal with MnFe2O4 oxygen carrier

Chemical looping combustion （CLC） of coal has gained increasing attention as a novel combustion technology for its advantages in CO2 capture. Sulfur evolution from coal causes great harm from either the CLC operational or environmental perspective. In this research, a combined MnFe2O4 oxygen carrier （OC） was synthesized and its reaction with a typical Chinese high sulfur coal, Liuzhi （LZ） bituminous coal, was performed in a thermogravimetric analyzer （TGA）-Fourier transform infrared （FT-IR） spectrometer. Evolution of sulfur species during reaction of LZ coal with MnFeaO40C was systematically investigated through experimental means combined with thermodynamic simulation. TGA-FTIR analysis of the LZ reaction with MnFe2O4 indicated MnFe2O4 exhibited the desired superior reactivity compared to the single reference oxides Mn304 or Fe203, and SO2 produced was mainly related to oxidization of H2S by MnFe2O4. Experimental analysis of the LZ coal reaction with MnFe2O4, including X-ray diffraction and X-ray photoelectron spectroscopy analysis, verified that the main reduced counterparts of MnFe2O4 were Fe304 and MnO, in good agreement with the related thermodynamic simulation. The obtained MnO was beneficial to stabilize the reduced MnFe2O4 and avoid serious sintering, although the oxygen in MnO was not fully utilized. Meanwhile, most sulfur present in LZ coal was converted to solid MnS during LZ reaction with MnFe2O4, which was further oxidized to MnSO4. Finally, the formation of both MnS and such manganese silicates as Mn2SiO4 and MnSiO3 should be addressed to ensure the full regeneration of the reduced MnFe2O4.