carbonization
简明释义
英[ˌkɑːbənaɪˈzeɪʃn]美[ˌkɑːrbənəˈzeɪʃn]
n. [化学] 碳化;干馏;碳化物
英英释义
The process of converting organic substances into carbon or carbon-containing residues through the removal of water and other volatile constituents. | 将有机物质通过去除水分和其他挥发成分转化为碳或含碳残留物的过程。 |
单词用法
生物质的碳化 | |
热碳化 | |
碳化过程 | |
碳化温度 | |
碳化反应 | |
碳化速率 | |
完全碳化 | |
部分碳化 |
同义词
反义词
| 脱碳 | The government is focusing on decarbonization to combat climate change. | 政府正专注于脱碳以应对气候变化。 | |
| 氧化 | Oxidation is a chemical reaction that can lead to the deterioration of materials. | 氧化是一种化学反应,可能导致材料的劣化。 |
例句
1.Hith temperature carbonization furnace is the key equipment during carbonization process.
实现这一转化的关键设备是碳化炉。
2.The treatment of semi-carbonization has heavy influence on making polyvinyl alcohol ion-exchange fiber.
半碳化处理对聚乙烯醇阳离子交换纤维制备的影响很大。
3.It's very important to prepare lime with high activity and improve carbonization process by taking effective measures.
因此,采取有效措施制备高活性度石灰和强化碳化反应过程具有十分重要的意义。
4.Concrete carbonization is not sufficient condition of steel corrosion.
混凝土的碳化不是钢筋锈蚀的充分条件。
5.Concrete carbonization is one of the main reasons affecting structure durability of the concrete.
混凝土碳化是影响混凝土结构耐久性的重要因素之一。
6.This entails the destruction of the equipment tested, through carbonization of the insulating material.
这意味着测试设备因绝缘部分的碳化而被破坏。
7.Influence factors of concrete carbonization are analysed in this paper.
本文分析了混凝土碳化的影响因素。
8.In the steel industry, carbonization is essential for producing high-quality coke.
在钢铁工业中,碳化对生产高质量的焦炭至关重要。
9.Researchers are studying the effects of carbonization on soil quality and fertility.
研究人员正在研究碳化对土壤质量和肥力的影响。
10.During the carbonization process, volatile substances are released, leaving behind carbon-rich material.
在碳化过程中,挥发性物质被释放,留下富含碳的材料。
11.The carbonization of biomass can help reduce waste and produce renewable energy.
生物质的碳化可以帮助减少废物并产生可再生能源。
12.The process of converting organic materials into charcoal is known as carbonization.
将有机材料转化为木炭的过程被称为碳化。
作文
The process of carbonization is a fascinating subject that encompasses both scientific principles and practical applications. In simple terms, carbonization refers to the transformation of organic materials into carbon-rich substances through the application of heat in the absence of oxygen. This method has been utilized for centuries, primarily in the production of charcoal, which serves as a critical energy source in various industries.To understand carbonization, one must first appreciate its significance in environmental sustainability. As the world grapples with the challenges of climate change and the depletion of fossil fuels, alternative energy sources have become increasingly important. Carbonization offers a viable solution by converting biomass—such as wood, agricultural residues, and even municipal waste—into charcoal, which can be used as a cleaner-burning fuel compared to traditional fossil fuels.Moreover, the carbonization process also plays a vital role in soil enhancement. The charcoal produced through this process can be added to soils to improve their structure and fertility. This practice, known as biochar application, not only helps in retaining soil moisture but also aids in carbon sequestration, effectively reducing greenhouse gas emissions. Thus, carbonization contributes to a circular economy by transforming waste materials into valuable resources while mitigating environmental impact.In addition to its environmental benefits, carbonization has significant industrial applications. For instance, in the production of activated carbon, the carbonization of organic materials is followed by activation processes that enhance the material's surface area and porosity. Activated carbon is widely used in water purification, air filtration, and even in the pharmaceutical industry for drug delivery systems.However, it is essential to recognize that the carbonization process must be managed carefully to minimize its environmental footprint. While it can produce beneficial products, improper practices can lead to emissions of harmful pollutants. Therefore, researchers and industry professionals are continuously exploring ways to optimize carbonization techniques, ensuring they are efficient and sustainable.In conclusion, carbonization is more than just a chemical process; it embodies a multifaceted approach to addressing some of the most pressing challenges of our time. By converting organic materials into carbon-rich substances, carbonization not only provides alternative energy sources but also enhances soil health and contributes to pollution control. As we move towards a more sustainable future, understanding and harnessing the potential of carbonization will be crucial in our efforts to create a greener planet. Through innovation and responsible practices, we can ensure that carbonization serves as a cornerstone in our transition to a more sustainable and resilient society.
碳化过程是一个迷人的主题,涵盖了科学原理和实际应用。简单来说,碳化指的是通过在缺氧条件下施加热量,将有机材料转化为富含碳的物质。这种方法已经被利用了几个世纪,主要用于木炭的生产,木炭在各个行业中作为关键的能源来源。要理解碳化,首先必须欣赏其在环境可持续性中的重要性。随着世界面临气候变化和化石燃料枯竭的挑战,替代能源来源变得越来越重要。碳化通过将生物质(如木材、农业残余物甚至城市废物)转化为木炭,提供了一种可行的解决方案,木炭可以作为比传统化石燃料更清洁的燃料。此外,碳化过程在土壤改良中也发挥着重要作用。通过这一过程生产的木炭可以添加到土壤中,以改善其结构和肥力。这种做法被称为生物炭施用,不仅有助于保持土壤湿度,还能促进碳封存,有效减少温室气体排放。因此,碳化通过将废弃物转化为有价值的资源,促进了循环经济,同时减轻了环境影响。除了环境益处,碳化在工业应用中也具有重要意义。例如,在活性炭的生产中,有机材料的碳化随后会进行激活处理,从而增强材料的表面积和孔隙率。活性炭广泛用于水净化、空气过滤,甚至在制药行业的药物输送系统中。然而,必须认识到,碳化过程必须谨慎管理,以尽量减少其对环境的影响。虽然它可以产生有益的产品,但不当的做法可能导致有害污染物的排放。因此,研究人员和行业专业人士不断探索优化碳化技术的方法,确保其高效且可持续。总之,碳化不仅仅是一个化学过程;它体现了一种多方面的方法,以应对我们时代的一些最紧迫的挑战。通过将有机材料转化为富含碳的物质,碳化不仅提供了替代能源来源,还改善了土壤健康并有助于污染控制。随着我们迈向更可持续的未来,理解和利用碳化的潜力将在我们创建更绿色星球的努力中至关重要。通过创新和负责任的实践,我们可以确保碳化成为我们过渡到更可持续和更有韧性的社会的基石。
