susceptor

简明释义

[səˈseptə(r)][səˈseptər]

n. 感受器;承受器;基座;衬托器

英英释义

A material or substance that can absorb energy, particularly in the form of electromagnetic radiation, and convert it into heat.

一种能够吸收能量,特别是以电磁辐射形式存在的物质或物质,并将其转化为热量。

单词用法

thermal susceptor

热接收体

susceptor material

接收体材料

susceptor layer

接收体层

silicon susceptor

硅接收体

susceptor heating

接收体加热

susceptor-based process

基于接收体的过程

同义词

absorber

吸收体

The absorber in the experiment was designed to capture thermal energy.

实验中的吸收体旨在捕获热能。

receptor

受体

The receptor on the cell surface binds to specific molecules.

细胞表面的受体与特定分子结合。

反义词

insulator

绝缘体

The insulator prevents heat transfer.

绝缘体阻止热量传递。

non-reactive material

非反应性材料

Non-reactive materials are used in chemical storage.

非反应性材料用于化学储存。

例句

1.Using finite analytic solution we gave the numerical computation of the flow field in CVD reactor with tilted susceptor.

本文用有限分析方法,对带有倾斜基座的CVD反应器内流场进行了数值计算。

2.The susceptor rested on a pedestal whose shaft is connected to a motor that provides rotation.

器安装在轴承台上,它的支架与提供旋转的马达相接。

3.A flexible substrates is mounted on the cylindrical susceptor.

挠性衬底安装在圆柱形衬托器上。

4.In the other embodiment, the susceptor cross section is a polygon with a plurality of substrates mounted on its facets.

在另一个实施方式中,衬托器截面是多边形,且多个衬底安装在衬托器的面上。

5.In one embodiment, the process reactor has four composite injectors arranged substantially parallel to the axis of rotation of the cylindrical susceptor.

在一个实施方式中,处理反应器具有基本上平行于圆柱形衬托器的旋转轴设置的四个复合注入器。

6.In one embodiment, the process reactor has four composite injectors arranged substantially parallel to the axis of rotation of the cylindrical susceptor.

在一个实施方式中,处理反应器具有基本上平行于圆柱形衬托器的旋转轴设置的四个复合注入器。

7.The susceptor 受体 in this experiment helps to convert electromagnetic energy into heat.

本实验中的受体有助于将电磁能量转化为热能。

8.The design of the susceptor 受体 affects the overall performance of the heating process.

受体的设计影响加热过程的整体性能。

9.Silicon wafers can be coated with a susceptor 受体 material to improve thermal efficiency.

硅晶圆可以涂覆一种受体材料以提高热效率。

10.In microwave heating, a susceptor 受体 is often used to enhance the absorption of microwave energy.

在微波加热中,通常使用一个受体来增强微波能量的吸收。

11.In chemical vapor deposition, a susceptor 受体 plays a critical role in maintaining the temperature uniformity.

在化学气相沉积中,受体在保持温度均匀性方面发挥着关键作用。

作文

In the field of materials science and engineering, the term susceptor (受热体) plays a crucial role in various applications, particularly in the realm of semiconductor manufacturing and thermal processing. A susceptor is a material that absorbs energy and converts it into heat, which can then be used to process other materials. This property makes it indispensable in industries that require precise temperature control during manufacturing processes.One of the most common applications of a susceptor is in the production of thin films and coatings. In chemical vapor deposition (CVD) processes, for example, a susceptor is often employed to create a controlled environment for the deposition of thin films on substrates. The susceptor absorbs microwave energy, which heats it up and subsequently transfers this heat to the substrate, allowing for uniform film growth. This method is essential in producing high-quality semiconductor devices, where even minor variations in temperature can lead to significant defects in the final product.Moreover, susceptors are not limited to semiconductor manufacturing; they are also widely used in the food industry. In microwave cooking, susceptors are often found in packaging materials designed for heating food. These materials are engineered to absorb microwaves and convert them into heat, effectively cooking the food from the outside in. This technology has revolutionized the way we prepare meals, providing a convenient and efficient means of cooking that ensures even heating.The design and material selection of a susceptor are critical factors that influence its performance. Common materials used as susceptors include silicon carbide, graphite, and certain metals, each offering unique thermal properties and efficiencies. For instance, silicon carbide is known for its excellent thermal conductivity and stability at high temperatures, making it an ideal choice for many industrial applications.In addition to their practical applications, susceptors are also a topic of ongoing research. Scientists and engineers are continually exploring new materials and configurations to enhance the efficiency of susceptors. Innovations in nanotechnology have led to the development of advanced susceptors that can operate at lower temperatures while maintaining high levels of energy absorption. These advancements could lead to more energy-efficient manufacturing processes and contribute to sustainable practices in various industries.In conclusion, the concept of a susceptor (受热体) is integral to both technological advancements and everyday applications. Whether in the production of semiconductors or the convenience of microwave cooking, susceptors demonstrate their versatility and importance across multiple fields. As research continues to evolve, we can expect to see even more innovative uses for susceptors, further solidifying their role in modern science and technology.