faveolate

简明释义

英[fəˈviːəleɪt]美[fəˈviəˌlet]

adj. 蜂巢状的

英英释义

单词用法

同义词

反义词

例句

1.Results The CT manifestations of spinal tuberculosis were: 1mottling, patchy, caved or faveolate bone destructions (43/43 cases);

结果脊柱结核的CT表现为：①斑片、斑点状、洞穴状或蜂窝状骨质破坏（43/43例）；

2.Results The CT manifestations of spinal tuberculosis were: 1mottling, patchy, caved or faveolate bone destructions (43/43 cases);

结果脊柱结核的CT表现为：①斑片、斑点状、洞穴状或蜂窝状骨质破坏（43/43例）；

3.The CT manifestations of spinal tuberculosis were: mottling, patchy, caved or faveolate bone destructions.

脊柱结核的CT表现为：斑片、斑点状、洞穴状或蜂窝状骨质破坏。

4.The surface of the coral was distinctly faveolate, resembling a honeycomb structure.

珊瑚的表面明显是凹穴状的，类似于蜂巢结构。

5.In the botanical study, the leaves were described as faveolate, indicating their unique texture.

在植物学研究中，这些叶子被描述为凹穴状的，表明它们独特的质地。

6.The paleontologist noted that the fossils exhibited a faveolate pattern, providing clues about their environment.

古生物学家注意到这些化石显示出凹穴状的图案，为它们的环境提供了线索。

7.The faveolate appearance of the rock formations intrigued geologists studying erosion.

岩石形成的凹穴状的外观引起了研究侵蚀的地质学家的兴趣。

8.During the examination, the scientist remarked on the faveolate structure of the fungus.

在检查过程中，科学家提到这种真菌的凹穴状的结构。

作文

In the vast realm of biology, one can encounter a myriad of fascinating terms that describe the intricate structures and functions of living organisms. One such term is faveolate, which refers to a surface that is marked with small pits or depressions, resembling a honeycomb or a series of small cavities. This term is often used in the context of describing certain types of corals, sponges, and even some plants. Understanding the significance of faveolate structures can provide deeper insights into the adaptation and evolutionary strategies of these organisms. The natural world is full of examples where the faveolate architecture plays a crucial role in the survival and efficiency of species. For instance, many corals exhibit a faveolate pattern on their surfaces, which not only enhances their aesthetic appeal but also serves functional purposes. The small pits allow for greater surface area, facilitating gas exchange and nutrient absorption. This structural adaptation is vital for corals as they thrive in nutrient-poor waters, relying on symbiotic relationships with algae that live within their tissues. Moreover, the faveolate design can be observed in sponges, which are among the simplest multicellular organisms. Their bodies are riddled with tiny pores and channels, creating a faveolate appearance that maximizes water flow through their systems. This feature is essential for their feeding mechanism, as sponges filter water to extract food particles. The efficiency of this faveolate structure allows sponges to thrive in various aquatic environments, from shallow reefs to deep-sea habitats. Additionally, in the plant kingdom, certain species exhibit faveolate leaf patterns. These leaves often have small indentations or grooves that help in water retention and reduce evaporation. By adopting a faveolate morphology, these plants can survive in arid conditions, showcasing how form and function are intricately linked in nature. The study of faveolate structures extends beyond mere observation; it has practical applications in fields such as biomimicry and materials science. Scientists and engineers look to nature for inspiration when designing new materials and technologies. For example, the honeycomb structure found in beehives, which is inherently faveolate, is admired for its strength and lightweight properties. By mimicking this natural design, researchers can create more efficient building materials or energy-efficient panels. In conclusion, the term faveolate encapsulates a remarkable aspect of biological design that is prevalent across various life forms. From corals to sponges and even plants, the faveolate structures demonstrate the elegance of evolution and adaptation. By studying these features, we not only gain insight into the lives of these organisms but also unlock potential innovations for human use. The interconnection between nature's designs and our technological advancements underscores the importance of preserving biodiversity, as every organism contributes to the rich tapestry of life on Earth.

在生物学的广阔领域中，人们可以遇到许多迷人的术语，这些术语描述了生物体复杂的结构和功能。其中一个术语是faveolate，它指的是表面上有小凹坑或凹陷，类似于蜂巢或一系列小腔体。这个术语通常用于描述某些类型的珊瑚、海绵甚至一些植物。理解faveolate结构的重要性可以为我们提供更深入的见解，了解这些生物的适应性和进化策略。 自然界中充满了许多例子，faveolate建筑在物种的生存和效率中发挥着关键作用。例如，许多珊瑚在其表面上表现出faveolate图案，这不仅增强了它们的美学吸引力，还具有功能目的。这些小凹坑允许更大的表面积，促进气体交换和营养吸收。这种结构适应性对珊瑚至关重要，因为它们在营养贫乏的水域中生存，依赖于与生活在其组织内的藻类的共生关系。 此外，faveolate设计还可以在海绵中观察到，海绵是最简单的多细胞生物之一。它们的身体上布满微小的孔和通道，形成一种faveolate外观，最大限度地提高水流通过其系统的效率。这一特征对它们的喂食机制至关重要，因为海绵过滤水以提取食物颗粒。faveolate结构的高效性使得海绵能够在各种水生环境中繁荣，从浅水礁到深海栖息地。 此外，在植物王国中，某些物种表现出faveolate叶片图案。这些叶子通常有小的凹陷或沟槽，有助于水分保持并减少蒸发。通过采用faveolate形态，这些植物能够在干旱条件下生存，展示了自然中形式与功能之间的密切联系。 对faveolate结构的研究不仅仅是观察；它在仿生学和材料科学等领域具有实际应用。科学家和工程师在设计新材料和技术时从自然中寻找灵感。例如，蜂巢中发现的蜂窝结构，本质上是faveolate，因其强度和轻量化特性而受到赞赏。通过模仿这种自然设计，研究人员可以创造更高效的建筑材料或节能面板。 总之，faveolate这个术语概括了生物设计的一个显著方面，这在各种生命形式中普遍存在。从珊瑚到海绵甚至植物，faveolate结构展示了进化和适应的优雅。通过研究这些特征，我们不仅获得了对这些生物生活的洞察，还解锁了人类使用的潜在创新。自然设计与我们技术进步之间的相互联系强调了保护生物多样性的重要性，因为每个生物体都为地球上丰富的生命织锦做出了贡献。