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量子代数SUq(4)的多分量q相干态表示 总被引:1,自引:0,他引:1
引入SUq(4)的多分量q相干态,讨论了密度算符在这种相干态中的表示和生成元的非齐次微分实现. 相似文献
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细菌视紫红质的光学性质及其光子学应用 总被引:1,自引:0,他引:1
文章介绍了新型的生物光学材料--细菌视紫红质的光学性质及其在光子学领域中的应用,也报道了我们新取得的一些应用成果。 相似文献
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聚合所得初生聚乙烯的晶型伍青,张启兴,卢泽俭,王海华,欧阳巍,林尚安,张光华(中山大学高分子研究所,广州,510275)(中国科学院广州化学研究所)关键词聚乙烯,结晶,单斜晶,颗粒形态热力学稳定的聚乙烯晶型为正交晶系[1].当聚乙烯受一定应力作用时如... 相似文献
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We investigate the dependences of the diffraction efficiency of the first order self-diffracted beam in bacteriorhodopsin (bR) films on the illumination time, the intensity and wavelength of the incident light. When the blue light (λ = 488 nm) and low intensity red light (λ = 632.8 nm) are incident on the bR film respectively,the diffraction efficiencies increase from zero to a stable value with the illumination time. When the green light (λ = 533 nm) and high-intensity red light illuminate the bR film respectively, the diffraction efficiencies increase from zero to the maximum and then decrease to a stable value with the illumination time. Rise and decay times are dependent on the intensity and wavelength of the incident light. The maximal diffraction efficiency of the red light is twice as high as that of the green light. The highest diffraction efficiency of 5.4% is obtained at 633nm.The diffraction efficiency change with the time for the green light is larger than that for the blue and red light. 相似文献
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对细菌视紫红质膜在两束非同频光照射下的非线性吸收特性进行了详细的理论分析,并讨论了细菌视紫红质膜非线性吸收特性有光子学方面的一些新应用。 相似文献
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细菌视紫红质 (Bacteriorhodopsin,简称 b R)是由嗜盐菌中提取出的一种光敏蛋白质 ,它是一种新型的生物光子学材料。我们测量的 b R膜在黄光和蓝光束分别照射下的非线性透射特性表明 ,在光照开始阶段 ,光的透过率随时间延长而增加 ,然后逐渐达到一个稳定值。黄光和蓝光的透过特性的不同是蓝光达到最大透过率的时间比黄光短。 b R膜在黄光和蓝光双光束同时照射下的非线性透射特性的计算结果表明 ,在某一固定蓝光光强 ,蓝光的透过光强随黄光强度的增加而减小 ,甚至变为零。这说明黄光对蓝光有抑制作用 ,即黄光可以调控蓝光的透过率。这一奇异的透射特性可以用做新出现事物滤波器 相似文献
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A Novel Optical Filter for Removing Bright-Background Using an Enhanced Bacteriorhodopsin Thin Film 下载免费PDF全文
We found that the bacteriorhodopsin (bR) film has a special property of complementary suppression modulated transmission (CSMT). The yellow and the blue beams can be suppressed mutually when both the beams illumlnate the bR film simultaneously. When the blue beam carrying an image with a bright-background noise illuminates on the bR film and then a yellow beam with uniform intensity distribution illuminates the same area, the bright-background can be removed due to the CSMT. In our demonstration, the pattern model is letters “VLSF” with ground noise of small words and the ground noise is removed from the pattern by the new optical filter. 相似文献
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