nitro

简明释义

英[ˈnaɪtrəʊ]美[ˈnaɪtroʊ]

n. 硝基

英英释义

单词用法

同义词

反义词

例句

1.And a super high contrast was obtained when 6 nitro benzimidazole and thiosalicylic acid were used together.

而硫代水杨酸与6硝基苯并咪唑配合使用时，得到了超高反差效果。

2.Donors such as amine and phenolic groups, when positioned ortho to a nitro group, are always involved in intramolecular hydrogen bonding.

在硝基邻位上存在的氢键给体如胺基，酚基时，总与硝基形成分子内氢键。

3.What's the nitro percentage in your fuel?

什么是硝基燃料中的比例？

4.In this paper carbonylation of nitro compounds with co-reagent based on secondary amine, primary amine and 4-aminopyridine is detailed.

本文介绍了二级胺、一级胺和4 -氨基吡啶为共试剂的硝基化合物的羰基化反应情况。

5.Nitro compound: Any of a class of chemical compounds in which the nitro group (-no2) forms part of the molecular structure.

硝基化合物：分子结构中含有硝基(-NO2)的任何一类化合物。

6.All K atoms coordinate with o atoms of phenolic hydroxyl group and nitro-group simultaneously.

所有的K离子均同时与酚羟基和硝基的氧原子配位。

7.Not recommended for use in chemical acid, nitro hydrocarbons, esters, ketones and compounds in chloroform.

不建议使用于强酸、硝基烃、酯类、氯仿及酮类的化学物之中。

8.For nitro derivatives of aminobenzenes and phenols, there is intermolecular Hydrogen bond in the molecule.

苯胺类硝基衍生物和苯酚的硝基衍生物分子中存在分子内氢键。

9."Sure enough, when the pain came again a few other times I took the nitro and boom, the pain was gone, " Morgan said.

Morgan说道“果真，当其它几次疼痛再次来临的时候，我吃了一些药片，疼痛消失了。”

10.The new sports car features a powerful nitro 氮气 system that boosts acceleration.

这款新跑车配备了强大的氮气系统，可以提升加速能力。

11.In the world of racing, many drivers rely on nitro 氮气 boosts to gain an edge over their competitors.

在赛车界，许多车手依靠氮气增压来获得竞争优势。

12.The chemist explained how nitro 氮气 compounds are used in various industrial applications.

化学家解释了氮气化合物在各种工业应用中的用途。

13.He added nitro 氮气 to the fuel mixture to enhance performance during the test run.

他在燃料混合物中添加了氮气以增强测试运行时的性能。

14.Many energy drinks contain nitro 氮气 for a quick boost of energy.

许多能量饮料含有氮气，以提供快速的能量提升。

作文

In the world of automotive engineering, the term nitro refers to a powerful substance that can significantly enhance the performance of a vehicle's engine. Specifically, nitro is often associated with nitrous oxide (N2O), a gas that can be injected into an internal combustion engine to increase its power output. This technology has been popularized in motorsports, where every fraction of a second counts, and drivers are always looking for ways to gain an edge over their competitors. The science behind nitro is fascinating. When nitrous oxide is injected into the engine, it breaks down at high temperatures, releasing oxygen. This additional oxygen allows for more fuel to be burned, which in turn produces more power. This process can lead to dramatic increases in horsepower, making cars equipped with nitro systems incredibly fast. However, using nitro also comes with risks, as it can put a significant strain on the engine components, potentially leading to mechanical failure if not managed properly. Beyond the realm of racing, nitro has found its way into various other fields. For instance, in the realm of pharmaceuticals, compounds containing nitro groups are crucial in the synthesis of many drugs. These compounds often exhibit unique chemical properties that make them valuable in medicinal chemistry. The nitro group can alter the reactivity and solubility of molecules, allowing chemists to design drugs that can effectively target specific diseases. Moreover, nitro compounds are also commonly used in the production of explosives. The most well-known example is nitroglycerin, which is used in dynamite. The explosive properties of nitro compounds arise from their ability to release a large amount of gas and heat when they decompose, making them useful in construction, mining, and demolition. Despite its many applications, the use of nitro requires careful handling due to its potential hazards. In automotive applications, improper use of nitro can lead to catastrophic engine failures or accidents. Similarly, in the pharmaceutical and explosive industries, strict regulations govern the handling and storage of nitro compounds to ensure safety. In conclusion, the term nitro encapsulates a wide array of meanings across different domains. Whether it’s boosting a car’s performance on the racetrack, aiding in drug development, or serving as a key ingredient in explosives, nitro plays a vital role in modern technology and industry. Understanding the implications and applications of nitro can lead to innovations that improve efficiency and effectiveness in various fields. As we continue to explore the potential of nitro compounds, it is essential to balance their benefits with the necessary precautions to ensure safe and responsible use.

在汽车工程的世界里，术语nitro指的是一种强大的物质，可以显著增强车辆发动机的性能。具体来说，nitro通常与一氧化二氮（N2O）相关，这是一种可以注入内燃机以增加功率输出的气体。这项技术在赛车运动中得到了普及，在那里每一秒钟的时间都是至关重要的，驾驶员总是在寻找方法以获得竞争对手的优势。 nitro背后的科学令人着迷。当一氧化二氮被注入发动机时，它在高温下分解，释放出氧气。这额外的氧气允许更多的燃料被燃烧，从而产生更多的功率。这个过程可以导致马力的戏剧性增加，使得装备有nitro系统的汽车变得极其快速。然而，使用nitro也伴随着风险，因为它可能会对发动机部件造成重大压力，如果没有妥善管理，可能导致机械故障。 除了赛车领域，nitro还进入了其他多个领域。例如，在制药领域，含有nitro基团的化合物在许多药物的合成中至关重要。这些化合物通常具有独特的化学性质，使其在医药化学中具有价值。nitro基团可以改变分子的反应性和溶解度，允许化学家设计能够有效靶向特定疾病的药物。 此外，nitro化合物还常用于炸药的生产。最著名的例子是硝化甘油，它用于炸药。nitro化合物的爆炸性源于它们在分解时释放大量气体和热量，使其在建筑、采矿和拆除中非常有用。 尽管有许多应用，但由于潜在的危险，使用nitro需要小心处理。在汽车应用中，不当使用nitro可能导致灾难性的发动机故障或事故。同样，在制药和炸药行业，严格的法规规范着nitro化合物的处理和储存，以确保安全。 总之，术语nitro在不同领域中包含了广泛的含义。无论是在赛道上提升汽车性能、帮助药物开发，还是作为炸药的关键成分，nitro在现代技术和工业中发挥着重要作用。理解nitro的影响和应用可以带来提高各个领域效率和有效性的创新。随着我们继续探索nitro化合物的潜力，平衡其好处与必要的预防措施以确保安全和负责任的使用是至关重要的。