semifluid
简明释义
英[ˌsemɪˈfluːɪd]美[ˌsemaɪˈflʊɪd]
adj. 半流质的
n. 半流质
英英释义
Having a consistency that is between solid and liquid; not completely fluid but also not solid. | 具有介于固体和液体之间的一种稠度;不是完全流动的,但也不是固体。 |
单词用法
半流体混合物 | |
半流体胶 | |
半流体物质 | |
以半流体形式 | |
半流体的特性 | |
半流体动力学 |
同义词
| 粘稠的 | 这糖浆具有粘稠的稠度。 | ||
| 胶状的 | 这种胶状物质常用于甜点中。 | ||
| 糊状的 | 这个糊状物对于食谱来说太稠了。 | ||
| 厚的 | 这种厚涂料需要更长时间才能干。 |
反义词
| 固体 | 冰淇淋在冷冻时是固体。 | ||
| 液体 | 水在室温下是液体。 |
例句
1.The net disappearance rate of DM, ADF and CL of RSP, DM of RSS in semifluid media was higher than that in liquid media.
半流体培养,稻草粉DM、ADF、CL净消失率和稻草秆DM净消失率都明显高于液体培养;
2.Semifluid mixtures of organic compounds consisting of resins dissolved in a volatile oil, turpentines can be distilled into the volatile oil of turpentine and the nonvolatile rosin.
它是半流质的有机化合物,由树脂在挥发性油中溶解而成,松脂可以被提炼成松脂挥发油和非挥发性松脂。
3.Semifluid mixtures of organic compounds consisting of resins dissolved in a volatile oil, turpentines can be distilled into the volatile oil of turpentine and the nonvolatile rosin.
它是半流质的有机化合物,由树脂在挥发性油中溶解而成,松脂可以被提炼成松脂挥发油和非挥发性松脂。
4.The mixture in the bowl was a thick, semifluid 半流体 consistency, perfect for making pancakes.
碗里的混合物是一种浓稠的半流体,非常适合做煎饼。
5.The artist used a semifluid 半流体 paint to create a unique texture on the canvas.
艺术家使用了一种半流体的油漆在画布上创造出独特的纹理。
6.In the lab, we observed that the semifluid 半流体 substance flowed slowly but steadily.
在实验室里,我们观察到这种半流体物质缓慢而稳定地流动。
7.During the cooking process, the sauce turned into a semifluid 半流体 state, enhancing its flavor.
在烹饪过程中,酱汁变成了半流体状态,增强了其风味。
8.The gel-like substance was classified as semifluid 半流体 due to its ability to maintain shape while flowing.
这种类似凝胶的物质被归类为半流体,因为它能够在流动时保持形状。
作文
In the realm of science and engineering, the term semifluid refers to a state of matter that exhibits properties between those of a solid and a liquid. This unique characteristic allows semifluid materials to flow under certain conditions while maintaining some structural integrity. Understanding semifluid substances is crucial in various applications, from food processing to pharmaceuticals and even in the development of new materials. For instance, consider the behavior of certain gels or pastes, which can be classified as semifluid. These materials are not completely liquid; they possess a viscosity that allows them to hold their shape to some extent. When pressure is applied, they flow, but when at rest, they can maintain a form. This duality makes semifluid substances incredibly useful in the culinary world, where chefs often rely on the unique textural properties of sauces and emulsions. In the medical field, understanding how semifluid substances behave can lead to innovations in drug delivery systems. For example, many topical creams and ointments are formulated to be semifluid, allowing them to spread easily over the skin while providing a barrier against moisture loss. The ability of these creams to maintain their shape while being easily applied is a testament to the importance of semifluid characteristics in product design. Moreover, in engineering, the study of semifluid materials can lead to advancements in construction and manufacturing processes. For example, concrete can exhibit semifluid properties when mixed with water and additives. It flows easily when poured into molds but hardens into a solid structure once it dries. This property is essential for creating durable buildings and infrastructure. Engineers must understand the semifluid nature of concrete to ensure proper mixing and pouring techniques, which ultimately affect the strength and stability of the final product. Additionally, the concept of semifluid is not limited to physical substances; it can also apply to abstract ideas in fields like economics and sociology. For instance, market trends can be seen as semifluid, where certain factors influence the flow of goods and services, yet the market retains some rigidity due to established practices and regulations. Analyzing these semifluid trends can provide valuable insights for businesses and policymakers alike. In conclusion, the term semifluid encapsulates a fascinating range of phenomena across various disciplines. From culinary arts to medicine and engineering, the properties of semifluid materials play a pivotal role in shaping our interactions with the world around us. As we continue to explore and innovate, a deeper understanding of semifluid substances will undoubtedly lead to new discoveries and technologies that enhance our daily lives.
在科学和工程领域,术语semifluid指的是一种物质状态,它表现出介于固体和液体之间的特性。这种独特的特性使得semifluid材料在某些条件下能够流动,同时保持一定的结构完整性。理解semifluid物质在各种应用中至关重要,从食品加工到制药,甚至在新材料的开发中。例如,考虑某些凝胶或膏体的行为,它们可以被归类为semifluid。这些材料并不是完全液态的;它们具有一定的粘度,使其在一定程度上能够保持形状。当施加压力时,它们会流动,但在静止时,它们可以保持形状。这种二元性使得semifluid物质在烹饪世界中非常有用,厨师们常常依赖于酱汁和乳化剂的独特质地特性。在医疗领域,理解semifluid物质的行为可以推动药物递送系统的创新。例如,许多外用霜剂和软膏的配方是semifluid的,使其能够轻松涂抹在皮肤上,同时提供防止水分流失的屏障。这些霜剂在保持形状的同时又易于涂抹的能力,是产品设计中semifluid特性的一个证明。此外,在工程学中,对semifluid材料的研究可以推动建筑和制造过程的进步。例如,当混合水和添加剂时,混凝土可以表现出semifluid特性。它在倒入模具时流动自如,但一旦干燥就会硬化成固体结构。这一特性对创建耐用的建筑和基础设施至关重要。工程师必须理解混凝土的semifluid性质,以确保适当的混合和浇筑技术,这最终影响到最终产品的强度和稳定性。此外,semifluid的概念不仅限于物理物质;它也可以应用于经济学和社会学等领域的抽象思想。例如,市场趋势可以被视为semifluid,其中某些因素影响商品和服务的流动,但由于既定的实践和法规,市场仍然保持一定的刚性。分析这些semifluid趋势可以为企业和政策制定者提供有价值的见解。总之,术语semifluid涵盖了各个学科中的一系列迷人现象。从烹饪艺术到医学和工程,semifluid材料的特性在塑造我们与周围世界的互动中发挥着关键作用。随着我们继续探索和创新,对semifluid物质的更深入理解无疑将导致新的发现和技术,从而提升我们的日常生活。
