carbonizing
简明释义
英[ˈkɑːrbənaɪzɪŋ]美[ˈkɑːrbənaɪzɪŋ]
v. 使……成碳,使……与碳化合(carbonize 的现在分词)
英英释义
The process of converting a substance into carbon or a carbon-containing residue through heating or chemical reactions. | 通过加热或化学反应将物质转化为碳或含碳残留物的过程。 |
单词用法
同义词
反义词
| 氧化 | 氧化铁的过程会导致生锈。 | ||
| 分解 | Decomposing organic matter is essential for nutrient cycling. | 有机物的分解对养分循环至关重要。 |
例句
1.The strength of autoclaved sample raised largely by carbonizing.
对蒸压后的试样进行碳化可以较大程度的提高强度。
2.The influence of carbonizing temperature and time was investigated by XRD in this study. The morphology and particle distribution of the powder were observed by SEM.
根据X射线衍射图研究了直接还原碳化温度及时间对反应产物的影响,用扫描电镜观察了粉末颗粒形貌和粒度分布。
3.The reasons are given why weak carbonizing flame of oxyacetylece is used for heating and why brazing seam area can't be polished.
论证了加热时氧——乙炔焰用微碳化焰的原因及焊缝结合区不能采用抛光的道理。
4.On the basis of the training of network, the mathematics model on the relationship between double glow plasma carbonizing and prediction of properties is built.
将人工神经网络理论和算法应用于双辉离子渗碳的研究,在对人工神经网络训练的基础上,建立了双辉离子渗碳工艺与渗层性能预报的数学模型。
5.The main results are as follows:1) The polyaniline was prepared by the oxypolymerization method at different conditions and the nitrogenous carbon material was obtained by carbonizing polyaniline.
并用循环伏安、恒流充放电和电化学阻抗等测试手段比较了不同条件下制备的碳材料的电化学性能。
6.Ginkgo wood vinegar constituents are various from the carbonizing temperatures.
银杏木醋液的组成成分与采集温度等有关。
7.The morphological struture of the rayon fibers during oxidizing and carbonizing process has been examined using optical and electron microscope technique.
使用光学和电子显微镜技术研究了纤维在氧化和碳化过程中的形态学结构。
8.The carbonizing process can significantly reduce the volume of waste material.
该碳化过程可以显著减少废料的体积。
9.The carbonizing of wood creates charcoal, which is used for grilling.
木材的碳化产生木炭,用于烧烤。
10.The process of carbonizing raw materials is essential for producing activated carbon.
原材料的碳化过程对于生产活性炭至关重要。
11.During the carbonizing phase, the temperature must be carefully controlled to ensure quality.
在碳化阶段,必须仔细控制温度以确保质量。
12.Researchers are studying the effects of carbonizing agricultural waste to produce biochar.
研究人员正在研究碳化农业废物以生产生物炭的效果。
作文
In recent years, the concept of sustainability has gained significant traction in various industries, particularly in energy production and material science. One of the innovative processes that have emerged in this context is the technique of carbonizing (碳化), which involves converting organic materials into carbon-rich solids through pyrolysis or other thermal processes. This method not only reduces waste but also produces valuable materials that can be used in various applications, such as activated carbon and biochar.The process of carbonizing (碳化) begins with the selection of suitable organic feedstock, which can include agricultural residues, wood chips, or even municipal solid waste. These materials are subjected to high temperatures in an oxygen-limited environment, which prevents combustion and allows for the breakdown of complex organic molecules. During this transformation, volatile compounds are released, and what remains is a stable form of carbon that can be utilized in several ways.One of the primary benefits of carbonizing (碳化) organic waste is its potential to mitigate environmental issues. For instance, when agricultural waste is disposed of through traditional methods like open burning, it contributes to air pollution and greenhouse gas emissions. By contrast, carbonizing (碳化) this waste captures carbon in a solid form, thus preventing it from entering the atmosphere as CO2. Moreover, the byproducts of this process, such as bio-oil and syngas, can be harnessed as renewable energy sources, further promoting a circular economy.Another significant application of carbonizing (碳化) is in soil enhancement. The resulting biochar, a product of the carbonizing (碳化) process, is known for its ability to improve soil fertility and retain moisture. When added to agricultural soils, biochar can enhance nutrient availability, reduce the need for chemical fertilizers, and support sustainable farming practices. This is particularly important in the face of climate change, where soil degradation poses a serious threat to global food security.Furthermore, carbonizing (碳化) can play a crucial role in carbon sequestration strategies. By converting biomass into stable carbon forms, we can effectively store carbon that would otherwise contribute to atmospheric CO2 levels. This aligns with global efforts to combat climate change and achieve net-zero emissions. Countries around the world are exploring policies and incentives to promote carbonizing (碳化) technologies as part of their climate action plans.Despite its numerous advantages, the carbonizing (碳化) process is not without challenges. The economic viability of carbonizing (碳化) operations largely depends on the scale of production and the market demand for the end products. Additionally, there are technical hurdles related to optimizing the process to maximize yield and efficiency. Ongoing research and development are essential to address these issues and enhance the overall performance of carbonizing (碳化) technologies.In conclusion, carbonizing (碳化) represents a promising solution for managing organic waste while simultaneously contributing to environmental sustainability. As we continue to seek innovative ways to address the pressing challenges of waste management and climate change, the adoption of carbonizing (碳化) techniques could pave the way for a more sustainable future. By embracing this process, we can turn waste into valuable resources and take significant strides toward achieving our environmental goals.
近年来,可持续发展的概念在各个行业中得到了显著关注,特别是在能源生产和材料科学领域。其中出现的一种创新工艺是碳化(碳化)技术,它涉及通过热解或其他热工艺将有机材料转化为富含碳的固体。这种方法不仅减少了废物,还生产出可用于各种应用的有价值材料,如活性炭和生物炭。碳化(碳化)过程始于选择合适的有机原料,这些原料可以包括农业残余物、木屑,甚至城市固体废物。这些材料在缺氧环境中经历高温处理,防止燃烧并允许复杂有机分子的分解。在这一转化过程中,挥发性化合物被释放,剩下的是一种稳定的碳形式,可以用于多种方式。碳化(碳化)有机废物的主要好处之一是其减轻环境问题的潜力。例如,当农业废物通过传统方法如露天焚烧处理时,会导致空气污染和温室气体排放。相比之下,碳化(碳化)这些废物可以将碳捕获为固体形式,从而防止其以CO2的形式进入大气。此外,这一过程的副产品,如生物油和合成气,可以作为可再生能源来源进一步利用,促进循环经济。碳化(碳化)的另一个重要应用是土壤增强。生物炭,作为碳化(碳化)过程的产物,以其提高土壤肥力和保水能力而闻名。当添加到农业土壤中时,生物炭可以增强养分可用性,减少对化肥的需求,并支持可持续农业实践。这在气候变化面前尤为重要,因为土壤退化对全球粮食安全构成严重威胁。此外,碳化(碳化)在碳封存策略中也可以发挥关键作用。通过将生物质转化为稳定的碳形式,我们可以有效地储存本会贡献于大气CO2水平的碳。这与全球应对气候变化和实现净零排放的努力相一致。世界各国正在探索政策和激励措施,以促进碳化(碳化)技术作为其气候行动计划的一部分。尽管有众多优点,碳化(碳化)过程并非没有挑战。碳化(碳化)操作的经济可行性在很大程度上取决于生产规模和最终产品的市场需求。此外,与优化过程以最大化产量和效率相关的技术障碍也存在。持续的研究和开发对于解决这些问题并提高碳化(碳化)技术的整体性能至关重要。总之,碳化(碳化)代表了一种有前景的解决方案,用于管理有机废物,同时为环境可持续性做出贡献。随着我们继续寻求创新的方法来应对废物管理和气候变化的紧迫挑战,采用碳化(碳化)技术可能为更可持续的未来铺平道路。通过拥抱这一过程,我们可以将废物转化为有价值的资源,并在实现环境目标方面取得重大进展。
