antennal

简明释义

英[ænˈtenəl]美[ænˈtenəl]

adj. 触角的

英英释义

单词用法

同义词

反义词

例句

1.The result shows that there are three regions in the antennal gland:coelomosac, labyrinth and nephridial canal.

结果表明，克氏原螯虾触角腺可分为端囊、迷路和肾管三部分。

2.The trichoid sensilla are arranged on the inner side (windward side) surface of the antennal stem and branch in each flagella segment.

在触角鞭节的每对侧枝的内侧(迎风面)着生许多毛状感受器。

3.The morphological structures of these antennal sensilla could be used for a useful character to identify or classify the families and genera in Blattodea.

触角感受器的形态结构也许能成为鉴别蜚蠊目科和属的有用特征。

4.Female beewolf digger wasps cultivate symbiotic Streptomyces bacteria in unique antennal glands and secrete them into their larval brood cells.

雌性狼蜂掘土蜂在其独特的触角腺里培育共生链霉菌，并将它们分泌到其幼虫的巢房中。

5.The general antennal structures are commonly seen within other chalcid wasps except for a specialized 'explore area' on the ventral apex of female antenna.

平腹小蜂的触角除了雌蜂触角末端腹面具有特化的斜截“探索区”以外，大体特征基本和其它小蜂相似。

6.Morphology of antennal sensilla of male black cutworm moth is observed with scanning electron microscope.

利用扫描电镜观察了小地老虎雄蛾触角感受器的种类、形态和分布。

7.Antennae are important sense organs in insects with antennal sensilla playing an important role for sensing and communication.

触角是昆虫重要的感觉器官，触角感器对昆虫感受外界环境、实现信息交流具有重要意义。

8.The general antennal structures are commonly seen within other chalcid wasps except for a specialized 'explore area' on the ventral apex of female antenna.

平腹小蜂的触角除了雌蜂触角末端腹面具有特化的斜截“探索区”以外，大体特征基本和其它小蜂相似。

9.The highest concentration of mercury was found in the antennal glands by mass spectrum analysis.

质谱分析表明，触角腺中汞的含量最高。

10.In the experiment, the antennal 触角的 response to stimuli was measured.

在实验中，测量了触角的对刺激的反应。

11.The antennal 触角的 glands play a crucial role in communication among ants.

触角的腺体在蚂蚁之间的交流中起着至关重要的作用。

12.Researchers found that the antennal 触角的 length varied significantly among different species.

研究人员发现，不同物种之间触角的长度差异显著。

13.The antennal 触角的 sensors are vital for detecting pheromones.

这些触角的传感器对于检测信息素至关重要。

14.The scientist studied the antennal 触角的 structures of various insect species.

科学家研究了不同昆虫物种的触角的结构。

作文

In the fascinating world of biology, one can often come across various specialized terms that describe the intricate features of living organisms. One such term is antennal, which refers to anything related to antennae, the sensory appendages found on the heads of many arthropods, including insects and crustaceans. Antennae play a crucial role in the survival of these creatures, serving as organs of touch, smell, and even taste. Understanding the function and anatomy of antennal structures can provide insights into how these animals interact with their environment. Antennae come in various shapes and sizes, adapted to the specific needs of different species. For instance, the long, feathery antennae of moths are designed to detect pheromones released by potential mates from great distances. This adaptation is vital for reproduction, ensuring the continuation of the species. On the other hand, the short, stubby antennal appendages of certain beetles may serve primarily for tactile feedback, helping them navigate through their habitats. The diversity in antennal morphology highlights the evolutionary pressures that shape these structures, optimizing them for particular ecological niches.Moreover, the study of antennal anatomy can reveal much about the behavior and ecology of arthropods. For example, researchers have found that the number and arrangement of sensory receptors on the antennal surface can influence an insect's ability to locate food or evade predators. In some species, the presence of specialized receptors allows them to detect vibrations or chemical signals in the air, enhancing their survival chances. This intricate relationship between structure and function underscores the importance of antennal adaptations in the evolutionary history of these organisms.Interestingly, the concept of antennal structures is not limited to the animal kingdom. In the realm of robotics and artificial intelligence, engineers often draw inspiration from biological systems. The design of robotic sensors can mimic antennal functions, enabling machines to perceive their surroundings more effectively. By studying how natural organisms utilize their antennal appendages, scientists can create more sophisticated and responsive technologies that improve human life.Furthermore, the significance of antennal features extends beyond individual species; it also plays a critical role in ecological interactions. For instance, pollinators such as bees rely heavily on their antennal senses to locate flowers and gather nectar. This relationship not only supports the survival of the bees but also facilitates the reproduction of flowering plants, highlighting the interconnectedness of ecosystems. The decline of bee populations due to habitat loss and pesticide use raises concerns about the future of these vital antennal interactions and their broader implications for biodiversity.In conclusion, the term antennal encompasses a wide range of biological phenomena that are essential for understanding the complexity of life forms on our planet. From the sensory capabilities of insects to the innovative applications in technology, the study of antennal structures reveals the intricate relationships between organisms and their environments. As we continue to explore the wonders of biology, the significance of antennal features will undoubtedly remain a key area of interest, shedding light on the remarkable adaptations and interactions that define the natural world.

在生物学的迷人世界中，人们经常会遇到各种专门术语，用于描述生物体复杂的特征。其中一个术语是antennal，它指的是与触角相关的任何事物，触角是许多节肢动物（包括昆虫和甲壳类动物）头部的感觉附肢。触角在这些生物的生存中起着至关重要的作用，作为触觉、嗅觉甚至味觉的器官。理解antennal结构的功能和解剖可以提供关于这些动物如何与环境互动的见解。触角有各种形状和大小，适应不同物种的特定需求。例如，蛾子的长羽毛状触角旨在探测远距离释放的潜在配偶的性信息素。这种适应对于繁殖至关重要，确保物种的延续。另一方面，某些甲虫的短而粗壮的antennal附肢可能主要用于触觉反馈，帮助它们在栖息地中导航。antennal形态的多样性突显了塑造这些结构的进化压力，使其优化以适应特定的生态位。此外，研究antennal解剖可以揭示许多关于节肢动物行为和生态的信息。例如，研究人员发现，antennal表面感受器的数量和排列可以影响昆虫定位食物或躲避捕食者的能力。在某些物种中，特定感受器的存在使它们能够探测空气中的振动或化学信号，从而增强它们的生存机会。这种结构与功能之间的复杂关系强调了antennal适应在这些生物进化历史中的重要性。有趣的是，antennal结构的概念并不限于动物王国。在机器人技术和人工智能领域，工程师们常常从生物系统中汲取灵感。机器人的传感器设计可以模仿antennal功能，使机器能够更有效地感知周围环境。通过研究自然生物如何利用其antennal附肢，科学家们可以创造出更复杂和响应更快的技术，从而改善人类生活。此外，antennal特征的重要性不仅限于个体物种；它在生态相互作用中也发挥着关键作用。例如，像蜜蜂这样的授粉者在很大程度上依赖其antennal感官来定位花朵和收集花蜜。这种关系不仅支持蜜蜂的生存，也促进开花植物的繁殖，突显了生态系统的相互联系。由于栖息地丧失和农药使用，蜜蜂种群的下降引发了对这些重要antennal相互作用及其对生物多样性的更广泛影响的担忧。总之，术语antennal涵盖了一系列生物现象，对于理解我们星球上生命形式的复杂性至关重要。从昆虫的感官能力到技术中的创新应用，对antennal结构的研究揭示了生物体与其环境之间的复杂关系。随着我们继续探索生物学的奇迹，antennal特征的重要性无疑将仍然是一个关键的研究领域，揭示定义自然世界的显著适应和相互作用。