triphenylamine
简明释义
英[ˈtraɪˌfiːnɪləˈmiːn]美[ˈtraɪˌfenɪləˈmin]
n. 三苯胺
英英释义
单词用法
三苯胺的合成 | |
三苯胺衍生物 | |
三苯胺染料 | |
基于三苯胺的化合物 |
同义词
反义词
胺 | 胺类化合物常用于制药行业。 | ||
酚 | 酚类广泛用作防腐剂和消毒剂。 |
例句
1.The fluorescent tuning on and off can be achieved by the stimuli of acid, which will protonate the central nitrogen atom of triphenylamine unit to stop the PIET process.
通过加入酸将三苯胺中心氮原子进行质子化,切断其PIET过程,可实现荧光的淬灭与恢复的可逆性荧光调控。
2.The fluorescent tuning on and off can be achieved by the stimuli of acid, which will protonate the central nitrogen atom of triphenylamine unit to stop the PIET process.
通过加入酸将三苯胺中心氮原子进行质子化,切断其PIET过程,可实现荧光的淬灭与恢复的可逆性荧光调控。
3.A carbon paste of the novel carbon paste electrode is made of carbon material powder which is agglutinated by triphenylamine.
它的碳糊由导电的碳材料粉末经三苯胺粘合而成。
4.Two-photon Materials based on 1, 3, 5-triazine and Triphenylamine Styryl.
含1,3,5 -三嗪和三苯胺的二苯乙烯类双光子材料。
5.The dye used in this experiment contains triphenylamine, which acts as a carrier for electrons.
这个实验中使用的染料含有三苯胺,它作为电子的载体。
6.Researchers are studying the properties of triphenylamine to improve organic solar cells.
研究人员正在研究三苯胺的特性,以改善有机太阳能电池。
7.In the synthesis of some organic compounds, triphenylamine is used as a building block.
在一些有机化合物的合成中,三苯胺被用作构建块。
8.The thermal stability of triphenylamine makes it suitable for high-temperature applications.
由于三苯胺的热稳定性,它适用于高温应用。
9.We added triphenylamine to the solution to observe its reaction with other chemicals.
我们向溶液中添加了三苯胺以观察它与其他化学物质的反应。
作文
In the world of organic chemistry, there are countless compounds that play crucial roles in various applications. One such compound is triphenylamine, which is a fascinating molecule due to its unique properties and significance in multiple fields. Triphenylamine (三苯胺) is an organic compound with the formula (C6H5)3N. It consists of three phenyl groups attached to a nitrogen atom, and its structure is not only aesthetically pleasing but also functional. This compound has garnered attention for its use in the production of dyes, pigments, and as a component in organic semiconductors. The history of triphenylamine dates back to the late 19th century when it was first synthesized. Since then, researchers have explored its properties extensively. One of the most notable features of triphenylamine is its ability to act as a hole transport material in organic light-emitting diodes (OLEDs). In OLED technology, the efficiency and performance of displays and lighting systems can be significantly enhanced by using materials like triphenylamine. This is primarily due to its excellent charge transport properties, which facilitate the movement of positive charges (holes) through the organic layers of the device. Moreover, triphenylamine is also known for its role in the synthesis of various organic dyes. Its derivatives are often used in dye-sensitized solar cells (DSSCs), where they help convert sunlight into electricity. The incorporation of triphenylamine into these systems improves their efficiency, making them a promising alternative to traditional silicon-based solar cells. The ongoing research into optimizing triphenylamine and its derivatives continues to yield exciting results, paving the way for advancements in renewable energy technologies. In addition to its applications in electronics and solar energy, triphenylamine is also utilized in the field of molecular sensors. Researchers have developed sensors based on triphenylamine that can detect various analytes, including heavy metals and other environmental pollutants. These sensors leverage the unique electronic properties of triphenylamine to produce measurable signals in response to specific substances, thus contributing to environmental monitoring and safety. Despite its many advantages, working with triphenylamine requires caution, as it can pose health risks if not handled properly. Safety protocols must be followed to minimize exposure, particularly in laboratory settings where the compound may be synthesized or used. Understanding the properties and potential hazards of triphenylamine is essential for researchers and industrial practitioners alike. In conclusion, triphenylamine is more than just a simple organic compound; it is a versatile building block that plays significant roles in various advanced technologies. From enhancing the efficiency of OLEDs to contributing to the development of sustainable energy solutions, triphenylamine exemplifies the importance of organic chemistry in modern science and industry. As research continues to explore new applications and derivatives of triphenylamine, we can expect to see even more innovative uses for this remarkable compound in the future.
在有机化学的世界中,有无数化合物在各种应用中发挥着关键作用。其中一个这样的化合物是三苯胺,由于其独特的性质和在多个领域的重要性,它是一个引人注目的分子。三苯胺(triphenylamine)是一种有机化合物,化学式为(C6H5)3N。它由三个苯基团附着在一个氮原子上,其结构不仅美观而且功能性强。该化合物因其在染料、颜料生产以及作为有机半导体成分中的用途而受到关注。 三苯胺的历史可以追溯到19世纪末,当时首次合成了该化合物。从那时起,研究人员对其性质进行了广泛的探索。三苯胺最显著的特点之一是它能够作为有机发光二极管(OLED)中的孔传输材料。在OLED技术中,通过使用像三苯胺这样的材料,可以显著提高显示器和照明系统的效率和性能。这主要归功于其优良的电荷传输特性,这有助于正电荷(孔)在器件的有机层中移动。 此外,三苯胺还以其在各种有机染料合成中的作用而闻名。其衍生物常用于染料敏化太阳能电池(DSSC),帮助将阳光转化为电能。通过将三苯胺纳入这些系统中,提高了它们的效率,使其成为传统硅基太阳能电池的有前途的替代品。对优化三苯胺及其衍生物的持续研究不断取得令人兴奋的成果,为可再生能源技术的进步铺平了道路。 除了在电子和太阳能领域的应用外,三苯胺还被用于分子传感器领域。研究人员开发了基于三苯胺的传感器,可以检测各种分析物,包括重金属和其他环境污染物。这些传感器利用三苯胺独特的电子特性,对特定物质产生可测量的信号,从而有助于环境监测和安全。 尽管有许多优点,但处理三苯胺时需要谨慎,因为如果不正确处理可能会带来健康风险。在实验室环境中合成或使用该化合物时,必须遵循安全协议以减少暴露。了解三苯胺的性质和潜在危害对研究人员和工业从业者来说至关重要。 总之,三苯胺不仅仅是一个简单的有机化合物;它是一个多用途的构建块,在各种先进技术中发挥着重要作用。从提高OLED的效率到促进可持续能源解决方案的发展,三苯胺体现了有机化学在现代科学和工业中的重要性。随着研究继续探索三苯胺的新应用和衍生物,我们可以期待在未来看到这个显著化合物的更多创新用途。
文章标题:triphenylamine的意思是什么
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