fissility

fissility的音标为["fɪsɪləti]，基本翻译为“多裂性；易裂性”。

速记技巧：可以将该词拆分为“fissi”（意为“裂开”）和“-ility”（表示性质、状态）两部分，从而联想到该词的含义。

fissility这个词的词源可以追溯到拉丁语“fissus”和“fissura”，意思是“裂开”或“裂缝”。它的变化形式包括复数形式“fissili”和过去式“fissilit”以及形容词形式“fissile”。

相关单词：

1. “Fission” - 这是一个由fissility衍生出来的词汇，指的是原子核裂变的过程。这个词在科学和能源领域中非常常见。

2. “Fracture” - 这是一个与fissility相关的词汇，指的是物体由于外力作用而产生的裂缝或断裂。

3. “Split” - 这也是一个与fissility相关的词汇，指的是物体由于内部张力或外部压力而产生的裂缝或裂开。

4. “Fissure” - 这是一个名词形式，指的是裂缝或管道，通常在岩石或土壤中形成。

5. “Fissured” - 这是一个形容词形式，用来描述有裂缝或裂纹的物体或表面。

6. “Fissurability” - 这是一个与fissility相关的形容词，用来描述材料是否容易产生裂缝或裂纹。

7. “Fissurology” - 这是一个与fissures相关的学科，研究裂缝的形成、发展和分布。

8. “Fissurous” - 这是一个形容词形式，用来描述具有裂缝或裂纹的特性。

9. “Fissurophobia” - 这是一个词，指的是对裂缝或裂纹的恐惧。

10. “Fissilization” - 这是一个词，指的是裂开或形成裂缝的过程或现象。

fissility常用短语：

1. fissility rate 裂隙率

2. fissility factor 裂隙发育系数

3. fissility of rock 岩石的裂隙性

4. fissility of soil 土壤的裂隙性

5. fissility of soil material 土壤颗粒的裂隙性

6. fissility of sediment 沉积物的裂隙性

7. fissility of rock mass 岩体裂隙性

例句：

1. The fissility of the rock mass depends on its composition and structure. 岩体裂隙性取决于其组成和结构。

2. The fissility of soil material has a significant impact on its stability and water retention capacity. 土壤颗粒的裂隙性对其稳定性和保水能力有重要影响。

3. The fissility of sediment is closely related to its transportation and deposition processes. 沉积物的裂隙性与其搬运和沉积过程密切相关。

4. The fissility rate of the rock mass varies with its location and geological conditions. 岩体裂隙率因位置和地质条件而异。

5. The fissility factor is used to evaluate the potential for rock burst during rock excavation. 裂隙发育系数用于评估在岩石开挖过程中发生岩石爆裂的潜在可能性。

6. The soil has a high fissility, which requires careful engineering design and construction methods to ensure stability. 该土壤具有较高的裂隙性，需要仔细的工程设计和施工方法以确保稳定性。

7. The fissility of sedimentary rocks is often related to their origin and depositional environments. 沉积岩的裂隙性通常与其形成和沉积环境有关。

英文小作文：

Fissility is an important characteristic of rocks, soil, and sediment that determines their stability and water retention capacity. Fissility refers to the tendency of materials to develop cracks and fissures, which can lead to failure and degradation under stress and strain. Rocks, soil, and sediment with high fissility are more susceptible to deformation and failure under loading conditions, while those with low fissility are more resistant to deformation and damage.

Fissility varies widely among different materials and depends on their composition, structure, and geological conditions. Soils with high fissility tend to have poor stability and water retention capacity, which require careful engineering design and construction methods to ensure stability during construction and use. Rocks with high fissility may pose a risk of rock burst during excavation, which requires appropriate safety measures to minimize the risk of injury and property damage. On the other hand, rocks with low fissility are more suitable for engineering uses such as foundation support and retaining structures.

Therefore, fissility plays an important role in engineering design and construction methods, especially in environments where stress and strain are high or where safety is a concern. Understanding the fissility of materials and their relationship to geological conditions is crucial for effective engineering design and construction methods that ensure safety and long-term stability.