biosystematics
简明释义
英[ˌbaɪəʊˌsɪstɪˈmætɪks]美[ˌbaɪoʊˌsɪstəˈmætɪks]
n. (生) 生物分类学;(生)生物系统学
英英释义
单词用法
生物系统分类学研究 | |
生物系统分类学方法 | |
应用生物系统分类学 | |
进行生物系统分类学研究 |
同义词
反义词
例句
1.The knowledge of biosystematics provides a foundation for nature monitoring and conservation.
生物系统学的知识是自然监测和保护的基础。
2.The knowledge of biosystematics provides a foundation for nature monitoring and conservation.
生物系统学的知识是自然监测和保护的基础。
3.By applying biosystematics, scientists can better understand the genetic diversity within populations.
通过应用生物系统分类学,科学家可以更好地理解种群内的遗传多样性。
4.The field of biosystematics is crucial for conservation efforts, as it identifies species at risk.
在保护工作中,生物系统分类学领域至关重要,因为它识别出濒危物种。
5.In marine biology, biosystematics helps classify various species and their ecological roles.
在海洋生物学中,生物系统分类学有助于对各种物种及其生态角色进行分类。
6.The study of plant diversity often relies on biosystematics, which is essential for understanding evolutionary relationships.
植物多样性的研究通常依赖于生物系统分类学,这对于理解进化关系至关重要。
7.Researchers use biosystematics to trace the lineage of different animal species.
研究人员使用生物系统分类学追踪不同动物物种的血统。
作文
Biosystematics is a branch of biology that focuses on the classification and identification of living organisms based on their evolutionary relationships. This scientific discipline plays a crucial role in understanding biodiversity and the complex web of life that exists on our planet. The term itself can be broken down into two parts: 'bio', which refers to life, and 'systematics', which involves the systematic categorization of organisms. By studying the genetic, morphological, and ecological characteristics of different species, biosystematics provides insights into how various organisms are related to one another. In recent years, the importance of biosystematics (生物系统分类学) has become increasingly evident, especially in the context of conservation efforts. As habitats are destroyed and species face extinction, understanding the relationships between organisms is vital for developing effective conservation strategies. For instance, identifying closely related species can help prioritize conservation efforts for those that share similar ecological roles or genetic backgrounds. This knowledge allows scientists to create more targeted approaches to preserve biodiversity.Moreover, biosystematics (生物系统分类学) aids in the discovery of new species. With advances in technology, particularly in genetic sequencing, researchers can analyze the DNA of organisms to uncover previously unrecognized species. This has significant implications for our understanding of evolution and the history of life on Earth. By classifying these new species within the broader context of existing classifications, scientists can better understand how life has evolved over time and how different species interact with each other and their environments.Another important aspect of biosystematics (生物系统分类学) is its application in agriculture and medicine. In agriculture, understanding the relationships between crop species can lead to the development of more resilient varieties that can withstand diseases and climate change. In medicine, knowing the evolutionary relationships among pathogens can inform treatment strategies and the development of vaccines. For example, the classification of bacteria and viruses through biosystematics (生物系统分类学) helps in tracking outbreaks and understanding the mechanisms of disease transmission.Despite its significance, biosystematics (生物系统分类学) faces challenges, particularly in the realm of data collection and integration. The vast amount of biological data generated from various sources, including field studies, genetic analyses, and ecological surveys, needs to be synthesized to create a comprehensive understanding of biodiversity. Furthermore, the rapid pace of environmental change necessitates a flexible and adaptive approach to classification, as new information continually emerges.In conclusion, biosystematics (生物系统分类学) is an essential field that enhances our understanding of life on Earth. Its applications in conservation, species discovery, agriculture, and medicine highlight its relevance in addressing some of the most pressing challenges facing humanity today. As we continue to explore the intricacies of life and its interconnectedness, the role of biosystematics (生物系统分类学) will undoubtedly grow, providing valuable insights that can help us navigate the complexities of our natural world.
生物系统分类学是生物学的一个分支,专注于基于生物的进化关系对生物进行分类和识别。这一科学学科在理解生物多样性和我们星球上存在的复杂生命网络方面发挥着至关重要的作用。这个术语可以分为两个部分:“bio”指的是生命,而“systematics”涉及生物的系统分类。通过研究不同物种的遗传、形态和生态特征,生物系统分类学提供了关于各种生物之间如何相互关联的见解。近年来,生物系统分类学的重要性变得越来越明显,尤其是在保护工作方面。随着栖息地的破坏和物种面临灭绝,了解生物之间的关系对于制定有效的保护战略至关重要。例如,识别密切相关的物种可以帮助优先考虑那些共享相似生态角色或遗传背景的保护工作。这一知识使科学家能够制定更有针对性的保护生物多样性的方式。此外,生物系统分类学还有助于新物种的发现。随着技术的进步,特别是在基因测序方面,研究人员可以分析生物的DNA,以揭示以前未被认识的物种。这对我们理解进化及地球生命历史具有重要意义。通过将这些新物种归类于现有分类的更广泛背景中,科学家可以更好地理解生命如何随着时间的推移而进化,以及不同物种如何相互作用以及与其环境的关系。生物系统分类学的另一个重要方面是其在农业和医学中的应用。在农业中,了解作物物种之间的关系可以导致开发出更具韧性的品种,从而抵御疾病和气候变化。在医学中,了解病原体之间的进化关系可以为治疗策略和疫苗的开发提供信息。例如,通过生物系统分类学对细菌和病毒的分类有助于追踪疫情和理解疾病传播机制。尽管其重要性显著,生物系统分类学仍面临挑战,特别是在数据收集和整合方面。从各种来源生成的生物数据的庞大数量,包括野外研究、遗传分析和生态调查,需要综合起来,以创建对生物多样性的全面理解。此外,环境变化的快速步伐需要一种灵活和适应性的分类方法,因为新的信息不断涌现。总之,生物系统分类学是一个重要领域,增强了我们对地球生命的理解。它在保护、新物种发现、农业和医学中的应用突显了它在应对当今人类面临的一些最紧迫挑战中的相关性。随着我们继续探索生命的复杂性及其相互联系,生物系统分类学的角色无疑将会增长,提供有价值的见解,帮助我们应对自然世界的复杂性。
