antennary
简明释义
adj. 触角的
英英释义
Relating to or resembling antennae, especially in structure or function. | 与触角有关或相似,特别是在结构或功能上。 |
单词用法
触角附肢 | |
触角神经元 | |
触角感官 | |
触角形态 |
同义词
| 像天线的 | The insect's antenna-like structures help it sense its environment. | 昆虫的天线状结构帮助它感知环境。 | |
| 有天线的 | The antennaed design of the robot allows for better signal reception. | 机器人的天线设计使信号接收更好。 |
反义词
例句
1.The results showed that the peroxisome mainly exists in the R-cell of hepatopancreas and the labyrinth epithelium of antennary gland.
过氧化物酶体主要存在于肝胰腺细胞和触角腺的迷路上皮细胞中。
2.The results showed that the peroxisome mainly exists in the R-cell of hepatopancreas and the labyrinth epithelium of antennary gland.
过氧化物酶体主要存在于肝胰腺细胞和触角腺的迷路上皮细胞中。
3.During the mating ritual, the male used his antennary 触角的 signals to attract the female.
在交配仪式中,雄性利用他的antennary 触角的信号吸引雌性。
4.The antennary 触角的 receptors are sensitive to pheromones released by other members of the species.
这些antennary 触角的受体对其他同类释放的信息素非常敏感。
5.In the study of arthropods, the antennary 触角的 glands play a crucial role in communication.
在对节肢动物的研究中,antennary 触角的腺体在沟通中起着关键作用。
6.The insect's antennary 触角的 structures help it navigate through its environment.
这只昆虫的antennary 触角的结构帮助它在环境中导航。
7.The antennary 触角的 segments can vary significantly between different species of insects.
不同昆虫物种之间,antennary 触角的节段可能差异显著。
作文
In the fascinating world of biology, the study of insects often reveals a plethora of intriguing features that contribute to their survival and adaptation. One such feature is the structure known as the antennary (触角的), which plays a crucial role in how these creatures interact with their environment. Insects possess a pair of antennae, which are sensory appendages that allow them to detect chemical signals, vibrations, and even changes in temperature. This essay will explore the significance of antennary structures in the lives of insects and how they enhance their ability to thrive in various habitats.The antennary (触角的) organs are primarily responsible for olfactory functions, helping insects locate food sources, mates, and potential threats. For example, moths have highly developed antennary (触角的) structures that can detect pheromones released by female moths from great distances. This ability to sense chemical cues is vital for their reproduction, ensuring that males can find females to mate with, thus perpetuating the species.Moreover, the antennary (触角的) appendages also aid in navigation. Many insects, such as bees, use their antennae to orient themselves and communicate with one another. Bees perform a unique dance to convey information about the location of food sources, and their antennary (触角的) sensors help them gather additional information about the quality and distance of the food. This intricate communication system highlights the importance of antennary (触角的) structures in social insects, where cooperation and collaboration are essential for survival.The morphology of antennary (触角的) structures varies significantly among different insect species, reflecting their ecological niches. For instance, while some insects have long, slender antennae that enhance their ability to sense minute changes in the environment, others have short, robust antennae suited for different functions. This diversity showcases the evolutionary adaptations that insects have undergone over millions of years, allowing them to exploit various resources and environments effectively.In addition to their sensory functions, antennary (触角的) appendages also play a role in tactile perception. Insects often use their antennae to explore their surroundings, feeling textures and surfaces that help them identify suitable habitats or potential dangers. This tactile feedback is crucial for behaviors such as foraging, mating, and avoiding predators.Furthermore, the study of antennary (触角的) structures extends beyond entomology; it has applications in robotics and artificial intelligence. Researchers are inspired by the sophisticated sensory mechanisms of insects to develop more efficient robots capable of navigating complex environments. By mimicking the functionality of antennary (触角的) organs, engineers aim to create machines that can respond to stimuli in real-time, improving their performance in tasks such as search and rescue operations or environmental monitoring.In conclusion, the antennary (触角的) structures of insects are remarkable adaptations that enhance their survival and ecological success. From detecting pheromones to navigating their environment and facilitating communication, these sensory appendages are integral to the lives of insects. As we continue to study and understand the complexities of these structures, we gain valuable insights into both the natural world and potential technological innovations. The exploration of antennary (触角的) features not only enriches our knowledge of biology but also inspires advancements in various fields, demonstrating the interconnectedness of nature and technology.
在生物学的迷人世界中,昆虫的研究常常揭示出许多有趣的特征,这些特征有助于它们的生存和适应。其中一个特征就是被称为antennary(触角的)的结构,它在这些生物与环境互动的过程中起着至关重要的作用。昆虫拥有一对触角,这些感官附肢使它们能够探测化学信号、震动,甚至温度变化。本文将探讨antennary(触角的)结构在昆虫生活中的重要性,以及它们如何增强昆虫在各种栖息地中的生存能力。antennary(触角的)器官主要负责嗅觉功能,帮助昆虫定位食物来源、伴侣和潜在威胁。例如,蛾子具有高度发达的antennary(触角的)结构,可以在很远的距离探测到雌蛾释放的信息素。这种感知化学线索的能力对于它们的繁殖至关重要,确保雄性能够找到雌性进行交配,从而延续物种。此外,antennary(触角的)附肢还帮助导航。许多昆虫,如蜜蜂,利用它们的触角来定向并相互沟通。蜜蜂通过一种独特的舞蹈来传达有关食物来源位置的信息,而它们的antennary(触角的)传感器帮助它们收集关于食物质量和距离的额外信息。这种复杂的沟通系统突显了antennary(触角的)结构在社会性昆虫中的重要性,在这些昆虫中,合作与协作对于生存至关重要。不同昆虫物种的antennary(触角的)结构形态差异显著,反映了它们的生态位。例如,某些昆虫拥有细长的触角,可以增强它们感知微小环境变化的能力,而其他昆虫则拥有短而粗壮的触角,适合于不同的功能。这种多样性展示了昆虫在数百万年中经历的进化适应,使它们能够有效地利用各种资源和环境。除了感官功能,antennary(触角的)附肢还在触觉感知中发挥作用。昆虫常常使用它们的触角来探索周围环境,感知质地和表面,以帮助它们识别合适的栖息地或潜在危险。这种触觉反馈对于觅食、交配和避免捕食者等行为至关重要。此外,antennary(触角的)结构的研究不仅限于昆虫学;它在机器人技术和人工智能中也有应用。研究人员受到昆虫复杂感官机制的启发,开发出更高效的机器人,能够在复杂环境中导航。通过模仿antennary(触角的)器官的功能,工程师旨在创造能够实时响应刺激的机器,提高它们在搜索和救援行动或环境监测等任务中的表现。总之,昆虫的antennary(触角的)结构是显著的适应性特征,增强了它们的生存和生态成功。从探测信息素到导航环境以及促进沟通,这些感官附肢在昆虫的生活中不可或缺。随着我们继续研究和理解这些结构的复杂性,我们获得了对自然世界和潜在技术创新的宝贵见解。对antennary(触角的)特征的探索不仅丰富了我们对生物学的知识,也激励了各个领域的进步,展示了自然与技术之间的相互关联。
