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近日,中国科学院西安光机所瞬态光学与光子技术国家重点实验室非线性光子技术及应用课题组在超构表面非线性光子学领域取得重要进展,相关研究成果以“Ultrabroadband nonlinear enhancement of mid-infrared frequency upconversion in hyperbolic metamaterials”为题,发表于国际著名期刊Nanoscale Hori...
Researchers at MIT and several other institutions have developed a method for making photonic devices — similar to electronic devices but based on light rather than electricity — that can bend and str...
A research team at the University of Central Florida has demonstrated the fastest light pulse ever developed, a 53-attosecond X-ray flash.The group led by Professor Zenghu Chang beat its own record se...
Control of light-matter interaction is central to fundamental phenomena and technologies such as photosynthesis, lasers, LEDs and solar cells. City College of New York researchers have now demonstrate...
Researchers at the Georgia Institute of Technology and Peking University have found a new use for the ubiquitous PowerPoint slide: Producing self-folding three-dimensional origami structures from phot...
The darkest form of ultraviolet light, known as UV-C, is unique because of its reputation as a killer – of harmful organisms.With wavelengths of between 200 and 280 nanometers, this particular form of...
Since the Middle Ages, alchemists have sought to transmute elements, the most famous example being the long quest to turn lead into gold. Transmutation has been realized in modern times, but on a minu...
A groundbreaking new optical device, developed at NJIT’s Big Bear Solar Observatory (BBSO) to correct images of the Sun distorted by multiple layers of atmospheric turbulence, is providing scientists ...
Faster production of advanced, flexible electronics is among the potential benefits of a discovery by researchers at Oregon State University’s College of Engineering.Taking a deeper look at photonic s...
It’s a paradox that has long vexed researchers in the field of optics.To control a light source, another light source that uses as much energy — if not more — is often required. The setup works, but i...
据物理学家组织网近日报道,加拿大滑铁卢大学量子计算研究所(IQC)的科学家们创造了迄今最强的光—物质耦合新纪录,强度是之前的10倍多。研究人员表示,发表在《自然·物理学》杂志上的这一最新成果,将使很多目前无法进行的物理学研究成为可能。
据英国帝国理工学院(ICL)官网消息,该校研究人员表示,通过将光和单个电子“绑”在一起,或可制造出一种新形式的“耦合”光,其拥有光和电子的属性,有助科学家们研制出用光而非电子工作的电路,以及在可见尺度上研究量子物理现象。在普通物质中,光会与物质表面和内部的全套电子相互作用。但通过使用理论物理学对光和最新发现的拓扑绝缘体新材料的行为进行建模,ICL的科学家们发现,光只能同物质表面的一个电子相互作用,...
当一个分子发出闪光,发出的光子就不可能再返回。但据英国剑桥大学网站2016年6月13日报道,该校研究人员设法把单个分子放在一种微小的光腔里,让它发出的光子返回到分子中,在适当的时候再离开,让能量在光和分子之间来回振荡,形成一种分子和光的量子态强耦合。这一成果有助于开发量子技术,以及能控制物质物理和化学性质的新方法。相关研究发表于英国《自然》杂志。
In the quest to harvest light for electronics, the focal point is the moment when photons — light particles — encounter electrons, those negatively-charged subatomic particles that form the basis of o...
众所周知,旋光性——光偏振的旋转——在和其镜像不同的材料内部产生。不过,如果这种对称性是被照明的方向而非材料本身打破的,又会发生什么呢?对这一问题的好奇,促成了一种新的旋光性的发现。正如一组来自英国南安普敦大学的研究人员在美国物理联合会所属《应用物理学快报》上报告的,用反射光打破超材料的对称性,将使很多新颖的应用成为可能,因为它会引发在规模上前所未有的旋光性——远超此前已知的“像镜子一样”的旋光性...

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