[Effects of community succession on plant reproductive allocation and ecological stoichiometry for two dominant species in the Hulunbuir Grassland, China]. / ç¾¤è½æ¼”æ›¿å¯¹å‘¼ä¼¦è´å°”è‰åœ°ä¸¤ç§ä¼˜åŠ¿æ¤ç‰©ç¹æ®–åˆ†é åŠç”Ÿæ€åŒ–å­¦è®¡é‡çš„å½±å“.

To explore the physiological and ecological adaptability of different dominant species during grassland community succession, we measured soil nutrients, plant biomass and C, N and P contents of two dominant species using the method of spatial sequences instead of chronosequences in the successive series of Agropyron michnoi community - A. michnoi + A. cristatam community - A. cristatam community in Hulunbuir Grassland. During the succession progress, the contents of soil total C, total C, available N and available P increased significantly. The N and P contents and N/P of leaves, stems and roots of A. michnoi and A. cristatam increased significantly, while the C/N showed opposite response. The leaf C content of A. michnoi and the C contents of leaves, stems and roots of A. cristatam significantly increased. The leaf C/P of A. michnoi and the C/P of leaves and roots of A. cristatem increased significantly, while the C/P of stems and roots of A. michnoi and the stem C/P of A. cristatem decreased significantly. In the community co-dominated by A. michnoi and A. cristatam, A. michnoi improved its interspecific competitiveness by reducing C content in stems and roots and increasing the C content in leaves, while A. cristatem adapted to environmental changes by reducing root to shoot ratio and reproductive ratio. A. michnoi was limited by N availability (N/P<14) in different communities, while A. cristatem was limited by P availability in single dominant community(N/P>16)and by both N and P in co-dominant community (14

Design and construction of linear laser encoders that possess high tolerance of mechanical runout.

A linearly diffracted laser encoder that has high tolerance of head-to-scale misalignment and a high signal-to-noise ratio is described. The preservation of parallelism between the incident and the diffracted beams, which can be attributed to a built-in folded 1x telescope, allows for the high alignment tolerance. It can be shown that, by coupling this newly developed circular polarization interferometer configuration with grating scale geometry optimization, one can eliminate the problems associated with signal distortion that arise from various efficiencies of the p- and the s-polarized light beams and obtain a high signal-to-noise ratio. Both theoretical and experimental results are presented to confirm the improved results and performance.