116 research outputs found
Effect of supervisor-subordinate Guanxi on employees work behavior: An empirical dynamic framework
Recently, the Chinese concept of guanxi (networks or business relationships) has drawn considerable attention and inspired researchers to explore its prevalence in diverse cultures. Accordingly, we examined the direct link between supervisor-subordinate guanxi and employee work behaviors (innovative work behavior and work engagement) by investigating the moderating effect of trust in the supervisor and the mediating effect of psychological empowerment. We collected data randomly from 510 employees (383 subordinates and 127 supervisors) working in China's manufacturing industry. The PROCESS macros operationalize the study constructs to test the presence of moderated mediation. All the hypothesized relationships are supported except the mediating role of psychological empowerment in the supervisor-subordinate guanxi and innovative work behavior relationships. The findings demonstrated that trust in supervisors strengthens the supervisor-subordinate guanxi's direct effect on psychological empowerment and its indirect impact on employeesā work behaviors. To promote positive employees and work behaviors, organizations can develop supervisor-subordinate guanxi that supports organizational goals
Food benefit and climate warming potential of nitrogen fertilizer uses in China
Ā© IOP Publishing, 2012. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Environmental Research Letters 7 (2012): 044020, doi:10.1088/1748-9326/7/4/044020.Chemical nitrogen (N) fertilizer has long been used to help meet the increasing food demands in China, the top N fertilizer consumer in the world. Growing concerns have been raised on the impacts of N fertilizer uses on food security and climate change, which is lack of quantification. Here we use a carbonānitrogen (CāN) coupled ecosystem model, to quantify the food benefit and climate consequence of agronomic N addition in China over the six decades from 1949 to 2008. Results show that N fertilizer-induced crop yield and soil C sequestration had reached their peaks, while nitrous oxide (N2O) emission continued rising as N was added. Since the early 2000s, stimulation of excessive N fertilizer uses to global climate warming through N2O emission was estimated to outweigh their climate benefit in increasing CO2 uptake. The net warming effect of N fertilizer uses, mainly centered in the North China Plain and the middle and lower reaches of Yangtze River Basin, with N2O emission completely counteracting or even exceeding, by more than a factor of 2, the CO2 sink. If we reduced the current N fertilizer level by 60% in 'over-fertilized' areas, N2O emission would substantially decrease without significantly influencing crop yield and soil C sequestration.This study has been supported by NASA IDS Program
(NNG04GM39C), NASA LCLUC Program (NNX08AL73G),
and the National Basic Research Program of China
(2010CB950900) and (2010CB950604)
Signature splitting inversion and backbending in 80Rb
High spin states of 80Rb are studied via the fusion-evaporation reactions
65Cu+19F, 66Zn+18O and 68Zn+16O with the beam energies of 75 MeV, 76 MeV and 80
MeV, respectively. Twenty-three new states with twenty-eight new \gamma
transitions were added to the previously proposed level scheme, where the
second negative-parity band is significantly pushed up to spins of 22^{-} and
15^{-} and two new sidebands are built on the known first negative-parity band.
Two successive band crossings with frequencies 0.51 MeV and 0.61 MeV in the
\alpha=0 branch as well as another one in the \alpha=1 branch of the second
negative-parity band are observed for the first time. Signature inversions
occur in the positive- and first negative-parity bands at the spins of 11\hbar
and 15\hbar, respectively. The signature splitting is seen obviously in the
second negative-parity band, but the signature inversion is not observed. It is
also found that the structure of the two negative-parity bands is similar to
that of its isotone ^{82}Y. Signature inversion in the positive-parity yrast
band with configuration \pi g_{9/2} \otimes \nu g_{9/2} in this nucleus is
discussed using the projected shell model (PSM)
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Terrestrial biosphere models need better representation of vegetation phenology: results from the North American Carbon Program Site Synthesis
Phenology, by controlling the seasonal activity of vegetation on the land surface, plays a fundamental role in regulating photosynthesis and other ecosystem processes, as well as competitive interactions and feedbacks to the climate system. We conducted an analysis to evaluate the representation of phenology, and the associated seasonality of ecosystem-scale CO2 exchange, in 14 models participating in the North American Carbon Program Site Synthesis. Model predictions were evaluated using long-term measurements (emphasizing the period 2000-2006) from 10 forested sites within the AmeriFlux and Fluxnet-Canada networks. In deciduous forests, almost all models consistently predicted that the growing season started earlier, and ended later, than was actually observed; biases of 2 weeks or more were typical. For these sites, most models were also unable to explain more than a small fraction of the observed interannual variability in phenological transition dates. Finally, for deciduous forests, misrepresentation of the seasonal cycle resulted in over-prediction of gross ecosystem photosynthesis by +160 Ā± 145 g C m-2 y-1 during the spring transition period, and +75 Ā± 130 g C m-2 y-1 during the autumn transition period (13% and 8% annual productivity, respectively) compensating for the tendency of most models to under-predict the magnitude of peak summertime photosynthetic rates. Models did a better job of predicting the seasonality of CO2 exchange for evergreen forests. These results highlight the need for improved understanding of the environmental controls on vegetation phenology, and incorporation of this knowledge into better phenological models. Existing models are unlikely to predict future responses of phenology to climate change accurately, and therefore will misrepresent the seasonality and interannual variability of key biosphere-atmosphere feedbacks and interactions in coupled global climate models.Engineering and Applied SciencesOrganismic and Evolutionary Biolog
Detecting quantitative trait loci for water use efficiency in rice using a recombinant inbred line population
Cloning and characterization of miRNAs from maize seedling roots under low phosphorus stress
MicroRNAs (miRNAs) are a class of small, non-coding regulatory RNAs that regulate gene expression by guiding target mRNA cleavage or translational inhibition in plants and animals. In this study, a small RNA library was constructed to identify conserved miRNAs as well as novel miRNAs in maize seedling roots under low level phosphorus stress. Twelve miRNAs were identified by high throughput sequencing of the library and subsequent analysis, two belong to conserved miRNA families (miRNA399b and miRNA156), and the remaining ten are novel and one of latter is conserved in gramineous species. Based on sequence homology, we predicted 125 potential target genes of these miRNAs and then expression patterns of 7 miRNAs were validated by semi-RT-PCR analysis. MiRNA399b, Zma-miR3, and their target genes (Zmpt1 and Zmpt2) were analyzed by real-time PCR. It is shown that both miRNA399b and Zma-miR3 are induced by low phosphorus stress and regulated by their target genes (Zmpt1 and Zmpt2). Moreover, Zma-miR3, regulated by two maize inorganic phosphate transporters as a newly identified miRNAs, would likely be directly involved in phosphate homeostasis, so was miRNA399b in Arabidopsis and rice. These results indicate that both conserved and maize-specific miRNAs play important roles in stress responses and other physiological processes correlated with phosphate starvation, regulated by their target genes. Identification of these differentially expressed miRNAs will facilitate us to uncover the molecular mechanisms underlying the progression of maize seedling roots development under low level phosphorus stress
North American terrestrial CO2 uptake largely offset by CH4 and N2O emissions: toward a full accounting of the greenhouse gas budget
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