photoinduced

简明释义

英[/ˌfoʊtoʊɪnˈduːst/]美[/ˌfoʊtoʊɪnˈduːst/]

adj. 光诱导的；光感生的

英英释义

单词用法

同义词

反义词

例句

1.The photoinduced electron transfer reaction between N-tosyl amides and 2-phenyl-N, N'-dimethyl benzimidazoline (PDMBI) provides an efficient approach for the deprotection of N-tosyl amides.

对甲苯磺酰基酰胺和2-苯基-N，N'-二甲基苯并咪唑啉（PDMBI）之间的光诱导电子转移反应，为酰胺的保护基——对甲苯磺酰基的脱除反应，提供了一条有效途径。

2.Second, on the basis of the characterization of photoinduced anisotropy, polarization holographic recordings are accomplished in the azo-containing liquid crystalline polymer.

其次，在光致各向异性研究的基础上，完成了两种偶氮液晶聚合物薄膜中的偏振全息记录。

3.The ultraviolet absorption in aqueous solutions, fluorescence emission properties, photoinduced isomerization phenomena and application properties of the two kinds of FBs were observed.

对比研究这两类增白剂在水溶液中的紫外吸收、荧光发射、光致异构化现象及其应用性能。

4.The photoinduced electron transfer reaction between N-tosyl amides and 2-phenyl-N, N'-dimethyl benzimidazoline (PDMBI) provides an efficient approach for the deprotection of N-tosyl amides.

对甲苯磺酰基酰胺和2-苯基-N，N'-二甲基苯并咪唑啉（PDMBI）之间的光诱导电子转移反应，为酰胺的保护基——对甲苯磺酰基的脱除反应，提供了一条有效途径。

5.Azoxybisbenzo-15-crown-5 was synthesized. Photoinduced trans-cis isomerization as well as its ability to extract alkali metals and rare earth metals' were dis-cussed.

合成了一种新的双冠醚，氧化偶氮双苯并15 -冠- 5。初步探讨了它的光异构现象及其对稀土和碱金属离子的萃取能力。

6.Photosynthesis is the most important chemical reaction on the earth For years, significant emphasis has been put on developing an understanding of photoinduced electron transfer.

光合作用是地球上最重要的化学反应。多年来，人们非常重视对伴随光合作用而产生的光致电子转移的研究。

7.The holographic diffraction efficiency spectrum was theoretically calculated from the photoinduced refractive index change spectrum.

由光致折射率变化曲线理论计算出了衍射效率随波长变化曲线。

8.The main factors governing photoinduced toxicity of the anthraquinone are molecular polarity, the ability of electron transition and the largest negative net atomic charges.

影响蒽醌类化合物对大型溞光敏化毒性的主要因素是分子的极性、电子的跃迁能力和原子最负净电荷。

9.Especially the characteristics of nonlinear optics, photo-isomerization and photoinduced anisotropy are emphasized, because they are crucial for optical storage.

其中着重介绍了光致异构和光致各向异性特性，这些特性对于光存储研究非常关键。

10.The process of energy conversion in solar cells is largely based on photoinduced 光诱导的 reactions that occur when sunlight hits the semiconductor material.

太阳能电池中能量转换的过程主要基于当阳光照射到半导体材料时发生的光诱导的反应。

11.Researchers discovered that the photoinduced 光诱导的 changes in the material's structure can enhance its conductivity.

研究人员发现，材料结构中的光诱导的变化可以增强其导电性。

12.In photochemistry, many reactions are initiated by photoinduced 光诱导的 electron transfer processes.

在光化学中，许多反应是由光诱导的电子转移过程引发的。

13.The experiment demonstrated that photoinduced 光诱导的 polymerization can be used to create new materials with unique properties.

实验表明，光诱导的聚合可以用于创造具有独特性质的新材料。

14.In plants, photoinduced 光诱导的 processes are crucial for photosynthesis and energy production.

在植物中，光诱导的过程对光合作用和能量生产至关重要。

作文

In recent years, the study of materials that exhibit unique properties when exposed to light has gained significant attention in the field of science. One such phenomenon is known as photoinduced (光诱导的) effects, which refer to changes in a material's properties as a direct result of light exposure. This concept is particularly relevant in fields such as photochemistry, optoelectronics, and materials science. Understanding photoinduced (光诱导的) processes can lead to innovations in various applications, including solar energy conversion, photonic devices, and even medical therapies. The fundamental principle behind photoinduced (光诱导的) effects lies in the interaction between light and matter. When photons collide with certain materials, they can excite electrons to higher energy states. This transition can cause a variety of changes, such as alterations in conductivity, chemical reactivity, or even structural transformations. For instance, in photovoltaic cells, photoinduced (光诱导的) electron excitation is crucial for converting sunlight into electrical energy. The efficiency of these cells largely depends on how well the materials used can absorb light and facilitate the movement of excited electrons. Another fascinating application of photoinduced (光诱导的) phenomena is found in the realm of phototherapy. Certain biological processes can be enhanced or initiated by light, leading to therapeutic effects. For example, in the treatment of skin conditions, photoinduced (光诱导的) reactions can help promote healing and reduce inflammation. Researchers are continually exploring new ways to harness these light-driven processes to develop more effective treatments for various ailments. Moreover, the development of smart materials that respond to light is an exciting area of research. These materials can undergo reversible changes when exposed to specific wavelengths of light, making them ideal candidates for applications in robotics, sensors, and adaptive optics. The photoinduced (光诱导的) properties of these materials enable them to change shape, color, or other characteristics, allowing for dynamic functionality in response to environmental stimuli. Despite the promising advancements in the understanding and application of photoinduced (光诱导的) effects, challenges remain. Researchers must address issues related to stability, efficiency, and scalability of materials that exhibit these properties. Additionally, the precise control of photoinduced (光诱导的) reactions often requires sophisticated equipment and techniques, which may limit their practical applications in some cases. In conclusion, the exploration of photoinduced (光诱导的) phenomena presents a wealth of opportunities across various scientific disciplines. From renewable energy solutions to innovative medical therapies and smart materials, the implications of harnessing light-induced effects are vast and transformative. As research continues to unravel the complexities of these processes, we can expect to see even more groundbreaking advancements that leverage the power of light to create a better future.

近年来，研究在光照下表现出独特性质的材料在科学领域引起了重大关注。这样的现象被称为photoinduced（光诱导的）效应，指的是材料的性质因光照而直接发生变化的现象。这个概念在光化学、光电子学和材料科学等领域尤其相关。理解photoinduced（光诱导的）过程可以推动各种应用的创新，包括太阳能转换、光子设备甚至医疗疗法。 photoinduced（光诱导的）效应的基本原理在于光与物质之间的相互作用。当光子与某些材料碰撞时，它们可以激发电子到更高的能量状态。这种转变可以导致多种变化，例如导电性、化学反应性或甚至结构转变的改变。例如，在光伏电池中，photoinduced（光诱导的）电子激发对将阳光转换为电能至关重要。这些电池的效率在很大程度上取决于所用材料吸收光线和促进激发电子移动的能力。 photoinduced（光诱导的）现象的另一个迷人应用是在光疗领域。某些生物过程可以通过光增强或启动，从而产生治疗效果。例如，在皮肤病的治疗中，photoinduced（光诱导的）反应可以帮助促进愈合并减少炎症。研究人员正在不断探索利用这些光驱动过程开发更有效的治疗方法，以应对各种疾病。 此外，开发对光响应的智能材料也是一个令人兴奋的研究领域。这些材料在暴露于特定波长的光时可以发生可逆变化，使其成为机器人、传感器和自适应光学等应用的理想候选者。这些材料的photoinduced（光诱导的）特性使它们能够在环境刺激下改变形状、颜色或其他特征，从而实现动态功能。 尽管对photoinduced（光诱导的）效应的理解和应用取得了令人鼓舞的进展，但仍然存在挑战。研究人员必须解决与材料稳定性、效率和可扩展性相关的问题。此外，精确控制photoinduced（光诱导的）反应通常需要复杂的设备和技术，这在某些情况下可能限制其实际应用。 总之，探索photoinduced（光诱导的）现象在各个科学学科中提供了丰富的机会。从可再生能源解决方案到创新的医疗疗法和智能材料，利用光诱导效应的影响是广泛而变革性的。随着研究继续揭示这些过程的复杂性，我们可以期待看到更多利用光的力量创造更美好未来的突破性进展。