carbonized

简明释义

英[ˈkɑːbənʌɪzd]美[ˈkɑrbəˌnaɪzd]

v. （使）碳化；（使钢、铁）渗碳；给……涂碳；烧焦……的表面（carbonize 的过去式及过去分词）

英英释义

单词用法

同义词

反义词

例句

1.OBJECTIVE To determine the main active parts of crude Pollen Typhae, parched Pollen Typhae and carbonized Pollen Typhae.

目的确定生蒲黄、炒蒲黄、蒲黄炭止血作用主要活性部位。

2.The carbonized base material is then activated by a second heat - steam treatment (200-1600 C) while regulating oxygen and carbon dioxide levels.

炭化的基础材料，然后激活第二热-蒸汽处理（200-1600C），同时调节氧气和二氧化碳的含量。

3.If the engine is running in an idle speed too long, spark plug might be serious carbonized.

发动机长时间低速运行，可能导致火花塞积炭严重。

4.The effects of carbonizing conditions on the element compose and atom ratio of carbonized production from polyaniline resin were tested and analyzed.

测试分析了炭化条件对聚苯胺炭化产物元素组成和原子比的影响。

5.Heat treated layer, carbonized layer, hardened hard layers, superficial coating, steels, non-ferrous metal, micro and thin shaped components.

热处理、碳化、淬火硬化层，表面覆层，钢，有色金属，微小及薄形零件等。

6.To compare the hemostatic effect of Flos Sophorae in crude, parched and carbonized forms and its extracts, including rutin, quercetin and tannin.

目的比较生槐花、炒槐花、槐花炭及其提取物芦丁、槲皮素、鞣质的止血作用。

7.With the renewal of advanced instruments and means, it is necessary that breakthroughs be made in researches on wood-based carbonized materials.

随着先进的检测仪器与手段的日益更新，对木炭的研究实有必要更上一层楼。

8.Scientists are studying the effects of carbonized 碳化的 materials on soil quality.

科学家正在研究碳化的碳化的材料对土壤质量的影响。

9.The artist used carbonized 碳化的 charcoal to create stunning black and white drawings.

艺术家使用碳化的碳化的木炭创作出令人惊叹的黑白画作。

10.During the fire, the wooden beams were carbonized 碳化的, weakening the structure of the building.

在火灾中，木梁被碳化的碳化的，削弱了建筑物的结构。

11.The chef served a delicious dish of carbonized 碳化的 vegetables, giving them a smoky flavor.

厨师上了一道美味的碳化的碳化的蔬菜，赋予它们烟熏的味道。

12.The ancient pottery was found to be carbonized 碳化的, indicating it had been exposed to high temperatures.

发现古代陶器是碳化的碳化的，这表明它曾暴露在高温下。

作文

The process of turning organic materials into a carbon-rich substance is known as carbonized. This method has been utilized for centuries, particularly in the production of charcoal. Charcoal, which is widely used for grilling and cooking, is essentially carbonized wood. The carbonized product retains much of the original structure of the wood but is transformed into a material that burns hotter and cleaner than raw wood. In addition to its culinary uses, carbonized materials have significant implications in various industries. For example, in the field of construction, carbonized wood can be used to enhance the durability and resistance of timber against pests and decay. The carbonized layer created during the process acts as a protective barrier, making it an eco-friendly alternative to chemical treatments. Moreover, the carbonized process has gained attention in the context of sustainability and climate change. By converting agricultural waste into carbonized products, we can reduce greenhouse gas emissions while simultaneously creating valuable resources. This practice, known as pyrolysis, not only helps in managing waste but also sequesters carbon in a stable form, thus playing a role in mitigating climate change. In recent years, researchers have explored the potential of carbonized materials in various applications, including soil enhancement. When carbonized biomass is added to soils, it improves nutrient retention and enhances microbial activity, leading to healthier plant growth. This technique, often referred to as biochar application, is gaining popularity among farmers looking for sustainable agricultural practices. Furthermore, the art of carbonized wood has found its way into modern design and architecture. Designers are increasingly incorporating carbonized wood elements into their projects, appreciating its unique aesthetic qualities and environmental benefits. The deep, rich color of carbonized wood adds character to furniture and interiors while promoting a sustainable approach to material sourcing. Despite its many advantages, the carbonized process is not without challenges. The initial energy input required for carbonized production can be significant, and finding efficient methods to scale up production while minimizing emissions remains a key focus for researchers and industry professionals. Additionally, public awareness and acceptance of carbonized products are crucial for their widespread adoption. Education and outreach efforts can help consumers understand the benefits of carbonized materials and encourage their use in everyday applications. In conclusion, the concept of carbonized materials encompasses a wide range of applications and benefits. From enhancing the durability of wood to contributing to sustainable agriculture and design, the potential of carbonized products is vast. As we continue to explore innovative ways to utilize carbonized materials, it is essential to balance economic viability with environmental responsibility. Embracing carbonized technologies may lead us towards a more sustainable future, where waste is minimized, and resources are used efficiently.

将有机材料转化为富含碳的物质的过程被称为碳化。这种方法已经被使用了几个世纪，尤其是在木炭生产中。木炭广泛用于烧烤和烹饪，基本上是碳化的木材。碳化产品保留了木材的大部分原始结构，但转变为一种比原木燃烧更热、更清洁的材料。除了烹饪用途外，碳化材料在各个行业中也具有重要意义。例如，在建筑领域，碳化木材可以用来增强木材的耐久性以及对害虫和腐烂的抵抗力。在这个过程中产生的碳化层作为保护屏障，使其成为化学处理的环保替代品。此外，碳化过程在可持续性和气候变化方面引起了关注。通过将农业废弃物转化为碳化产品，我们可以减少温室气体排放，同时创造有价值的资源。这种被称为热解的做法不仅有助于管理废物，还能以稳定的形式固存碳，从而在减缓气候变化方面发挥作用。近年来，研究人员探索了碳化材料在各种应用中的潜力，包括土壤改良。当碳化生物质添加到土壤中时，可以改善营养物质的保持能力，并增强微生物活性，从而促进植物的健康生长。这种技术通常被称为生物炭施用，越来越受到寻求可持续农业实践的农民的欢迎。此外，碳化木材的艺术已逐渐融入现代设计和建筑。设计师越来越多地将碳化木材元素纳入他们的项目中，欣赏其独特的美学特性和环境效益。碳化木材的深色和丰富的色彩为家具和室内空间增添了个性，同时促进了可持续的材料采购方式。尽管有许多优点，但碳化过程并非没有挑战。生产碳化所需的初始能量投入可能相当可观，而寻找高效的方法来扩大生产规模同时最小化排放仍然是研究人员和行业专业人士的重点。此外，公众对碳化产品的认知和接受度对于其广泛采用至关重要。教育和宣传工作可以帮助消费者理解碳化材料的好处，并鼓励在日常应用中使用。总之，碳化材料的概念涵盖了广泛的应用和益处。从增强木材的耐久性到促进可持续农业和设计，碳化产品的潜力是巨大的。随着我们继续探索利用碳化材料的创新方法，平衡经济可行性与环境责任至关重要。拥抱碳化技术可能会引领我们走向一个更可持续的未来，在这个未来中，废物最小化，资源高效利用。