carbonise
简明释义
v. 使成碳,使与碳化合(等于 carbonize)
第 三 人 称 单 数 c a r b o n i s e s
现 在 分 词 c a r b o n i s i n g
过 去 式 c a r b o n i s e d
过 去 分 词 c a r b o n i s e d
英英释义
To convert (a substance) into carbon or a carbon-containing residue, typically through the process of heating in the absence of oxygen. | 将(某种物质)转化为碳或含碳残留物,通常通过在缺氧的情况下加热的过程。 |
单词用法
同义词
| 木炭化 | 如果暴露在高温下,木材会被炭化。 | ||
| 焦炭化 | 煤可以被焦化以生产钢铁制造的燃料。 | ||
| 碳化 | The process of carbonizing organic materials is essential in producing charcoal. | 有机材料的碳化过程对生产木炭至关重要。 |
反义词
| 氧化 | 铁在潮湿环境中会氧化。 | ||
| 水合 | 植物需要适当的水合才能茁壮成长。 |
例句
1.We'll be competing for the engineering resources to deploy those wind farms in a global market where lots of other nations are trying to de-carbonise at the same time.
我们正在全球市场,为有能力配置这些风力发电场的工程师资源而竞争。其它国家也在进行减排工作。
2.We'll be competing for the engineering resources to deploy those wind farms in a global market where lots of other nations are trying to de-carbonise at the same time.
我们正在全球市场,为有能力配置这些风力发电场的工程师资源而竞争。其它国家也在进行减排工作。
3.In ancient times, people discovered that they could carbonise 碳化 food to preserve it for longer periods.
在古代,人们发现他们可以通过碳化 碳化食物来延长其保存时间。
4.The process of carbonising 碳化 organic materials can produce biochar, which is beneficial for soil health.
有机材料的碳化 碳化过程可以产生生物炭,这对土壤健康有益。
5.The factory specializes in processes that carbonise 碳化 various types of biomass for energy production.
这家工厂专门从事将各种类型的生物质进行碳化 碳化以生产能源的工艺。
6.When wood is heated in the absence of oxygen, it will carbonise 碳化 and turn into charcoal.
当木材在缺氧的情况下加热时,它会碳化 碳化并变成木炭。
7.During the experiment, we observed how different temperatures affect the rate at which materials carbonise 碳化.
在实验中,我们观察到不同温度如何影响材料的碳化 碳化速率。
作文
In recent years, the concept of sustainability has gained immense importance in various fields, particularly in energy production and waste management. One method that has emerged as a potential solution for reducing waste and generating energy is the process of pyrolysis, which can effectively carbonise organic materials. The term carbonise means to convert a substance into carbon or a carbon-containing residue through the application of heat in the absence of oxygen. This process not only helps in managing waste but also provides a renewable source of energy.The process of carbonising organic matter involves heating it to high temperatures, generally between 300 to 900 degrees Celsius, without any oxygen present. This lack of oxygen prevents combustion and allows the material to decompose thermally. As a result, the organic material breaks down into various useful products, such as biochar, oil, and gas. Biochar, in particular, has gained attention for its ability to improve soil health and sequester carbon, thus playing a vital role in mitigating climate change.One of the significant advantages of carbonisation is its ability to reduce the volume of waste significantly. For instance, agricultural residues, wood chips, and even municipal solid waste can be transformed into valuable resources rather than being sent to landfills. By carbonising these materials, we not only reduce the amount of waste that contributes to environmental pollution but also create opportunities for sustainable energy production.Moreover, the carbonisation process can be integrated into existing waste management systems. Instead of traditional incineration methods that release harmful emissions, carbonising waste can provide a cleaner alternative. The gases produced during the carbonisation process can be captured and utilized as a form of renewable energy, further enhancing the efficiency of waste management practices.The economic implications of carbonisation are also noteworthy. By converting waste into energy and useful byproducts, communities can create new jobs and stimulate local economies. The demand for biochar, for example, is increasing in agricultural sectors, where it is used to enhance soil fertility and retain moisture. This creates a market for carbonised products, thereby supporting local farmers and businesses.In conclusion, the process of carbonising organic materials presents a multifaceted solution to some of the pressing challenges we face today, including waste management and energy production. By embracing this innovative approach, we can reduce our environmental footprint, promote sustainability, and harness the potential of waste as a resource. The future of waste management lies in our ability to carbonise materials effectively, transforming them from mere refuse into valuable assets for our communities and the planet.
近年来,可持续发展的概念在各个领域中变得极为重要,尤其是在能源生产和废物管理方面。热解过程作为一种潜在的解决方案,已逐渐浮出水面,能够有效地碳化有机材料。术语碳化是指通过在缺氧环境下施加热量,将物质转化为碳或含碳残留物的过程。这一过程不仅有助于管理废物,还提供了一种可再生的能源来源。有机物的碳化过程涉及将其加热到高温,通常在300到900摄氏度之间,而不接触任何氧气。这种缺氧环境防止了燃烧,使材料能够热分解。因此,有机材料分解成各种有用的产品,如生物炭、油和气体。特别是生物炭因其改善土壤健康和固碳能力而受到关注,从而在缓解气候变化方面发挥着至关重要的作用。碳化的一个显著优势是能够显著减少废物的体积。例如,农业残余物、木屑甚至城市固体废物都可以转化为有价值的资源,而不是被送往填埋场。通过碳化这些材料,我们不仅减少了导致环境污染的废物数量,还创造了可持续能源生产的机会。此外,碳化过程可以与现有的废物管理系统相结合。与释放有害排放的传统焚烧方法相比,碳化废物可以提供更清洁的替代方案。在碳化过程中产生的气体可以被捕获并利用作为一种可再生能源,进一步提高废物管理实践的效率。碳化的经济影响也值得注意。通过将废物转化为能源和有用的副产品,社区可以创造新的就业机会并刺激地方经济。例如,生物炭在农业部门的需求正在增加,农民使用它来提高土壤肥力和保持水分。这为碳化产品创造了市场,从而支持当地农民和企业。总之,有机材料的碳化过程为我们今天面临的一些紧迫挑战提供了多方面的解决方案,包括废物管理和能源生产。通过采用这一创新方法,我们可以减少环境足迹,促进可持续发展,并利用废物作为资源的潜力。废物管理的未来在于我们有效地碳化材料的能力,将它们从单纯的垃圾转变为我们社区和地球的宝贵资产。
