multicomponent

简明释义

英[ˌmʌltɪkəmˈpəʊnənt]美[mʌltikəmˈpoʊnənt]

adj. 多成分的；多部件的

英英释义

单词用法

同义词

反义词

例句

1.This natural antioxidant is a multicomponent mixture with good antioxidative effect, safe in use and is possible to take the place of synthetics.

该天然抗氧化剂是多组分的混合物，其抗氧化成分力咖啡酸、 绿原酸和多种氨基酸。

2.The geologic correlation of multiwave and multicomponent seismic data is the most important and fundamental work.

多波多分量地震地质层位对比是多波地震资料解释和应用中最关键、最基础的工作。

3.The model accounts simultaneously for electrochemical kinetics, hydrodynamics, and multicomponent transport.

模型同时考虑了电化学动力学、水动力学和多组分传递。

4.The technology of low temperature gas multicomponent permeation for nodular cast iron was studied.

对球墨铸铁的低温气体多元共渗技术进行了研究。

5.The preparation of multicomponent alloy can optimize material compositions and improve thermoelectric properties.

制备多元合金可以优化材料的成分，提高材料的热电性能。

6.The 20-step reaction mechanism and multicomponent diffusion were applied in the simulation.

采用20步的反应机理并应用多分量扩散进行了模拟计算。

7.Multicomponent spectral correlative chromatography is proposed based on orthogonal projection and correlative chromatography.

基于正交投影理论和相关色谱方法提出多组分光谱相关色谱。

8.The new drug is a multicomponent 多成分的 formulation that targets multiple pathways in the body.

这种新药是一种多成分的制剂，旨在针对身体中的多个通路。

9.In chemistry, a multicomponent 多成分的 reaction can produce complex molecules from simple starting materials.

在化学中，多成分的反应可以从简单的起始材料产生复杂的分子。

10.The engineering team developed a multicomponent 多成分的 system to improve efficiency in manufacturing processes.

工程团队开发了一种多成分的系统，以提高制造过程中的效率。

11.This recipe requires a multicomponent 多成分的 sauce that enhances the flavor of the dish.

这个食谱需要一种多成分的酱汁，以增强菜肴的味道。

12.The study focused on multicomponent 多成分的 materials for use in advanced electronics.

这项研究集中于用于先进电子产品的多成分的材料。

作文

In the modern world, technology has become increasingly sophisticated, leading to the development of various systems and products that are not only functional but also efficient. One significant aspect of this evolution is the rise of multicomponent systems, which are designed to integrate multiple elements to achieve a common goal. These multicomponent systems can be found in various fields, including engineering, medicine, and environmental science, showcasing their versatility and importance. To begin with, let us explore the concept of multicomponent systems in engineering. In mechanical engineering, for instance, a car engine is a classic example of a multicomponent system. It consists of various parts, such as the pistons, crankshaft, and fuel injectors, all working together to convert fuel into motion. The efficiency of the engine relies on the harmonious interaction of these components. If one part fails or operates suboptimally, the entire system's performance can be compromised. This interdependence highlights the necessity of understanding each component's role within the multicomponent framework. Furthermore, in the field of medicine, multicomponent therapies are becoming increasingly popular. These therapies combine different treatment modalities, such as medication, physical therapy, and psychological support, to address complex health issues. For example, in treating chronic pain, a multicomponent approach may include pain relief medications, exercise programs, and cognitive-behavioral therapy. This holistic method recognizes that addressing only one aspect of a patient's condition may not yield the best outcomes. Instead, by integrating multiple components, healthcare providers can tailor treatments to meet individual needs more effectively. Moreover, environmental science has also embraced multicomponent strategies to tackle issues such as pollution and climate change. For instance, a multicomponent approach to waste management might involve recycling, composting, and waste-to-energy technologies. Each of these components plays a critical role in reducing the overall environmental impact. By combining these strategies, communities can create a more sustainable waste management system that minimizes landfill use and conserves resources. The advantages of multicomponent systems extend beyond their ability to address complex problems. They also promote innovation and adaptability. For example, in software development, multicomponent architectures allow developers to create applications that can easily incorporate new features or adapt to changing user needs. This flexibility is crucial in today's fast-paced technological landscape, where user preferences and market demands can shift rapidly. However, managing multicomponent systems can also present challenges. Coordinating the interactions between various components requires careful planning and execution. Additionally, ensuring that each part functions optimally within the larger system necessitates ongoing monitoring and maintenance. This complexity underscores the importance of interdisciplinary collaboration, as expertise from different fields can contribute to the successful implementation of multicomponent solutions. In conclusion, the concept of multicomponent systems is integral to many areas of modern life. Whether in engineering, medicine, or environmental science, the ability to integrate multiple components for a common purpose leads to more effective and innovative solutions. As we continue to face complex challenges, embracing the multicomponent approach will be essential for fostering progress and improving outcomes across various domains.

在现代社会，技术变得越来越复杂，导致各种系统和产品的发展，这些系统和产品不仅功能强大，而且高效。这一演变的一个重要方面是多组分系统的兴起，这些系统旨在整合多个元素以实现共同目标。这些多组分系统可以在工程、医学和环境科学等多个领域中找到，展示了它们的多功能性和重要性。 首先，让我们探讨一下工程中多组分系统的概念。例如，在机械工程中，汽车发动机就是多组分系统的经典例子。它由多个部件组成，如活塞、曲轴和喷油器，这些部件共同工作将燃料转化为运动。发动机的效率依赖于这些组件之间的和谐互动。如果其中一个部件出现故障或运行不理想，整个系统的性能可能会受到影响。这种相互依赖性突显了理解每个组件在多组分框架内角色的必要性。 此外，在医学领域，多组分疗法越来越受欢迎。这些疗法结合了不同的治疗方式，如药物治疗、物理治疗和心理支持，以解决复杂的健康问题。例如，在治疗慢性疼痛时，多组分方法可能包括止痛药、锻炼程序和认知行为疗法。这种整体方法认识到，仅仅解决患者状况的一个方面可能无法产生最佳效果。相反，通过整合多个组件，医疗提供者可以更有效地量身定制治疗方案，以满足个人需求。 此外，环境科学也采用了多组分策略来应对污染和气候变化等问题。例如，针对废物管理的多组分方法可能涉及回收、堆肥和废物转化为能源技术。这些组件中的每一个在减少整体环境影响方面都发挥着关键作用。通过结合这些策略，社区可以创建一个更可持续的废物管理系统，从而最小化填埋场的使用并节约资源。 多组分系统的优势不仅在于它们能够解决复杂问题。它们还促进了创新和适应性。例如，在软件开发中，多组分架构允许开发人员创建可以轻松集成新功能或适应不断变化的用户需求的应用程序。这种灵活性在当今快速发展的技术环境中至关重要，因为用户偏好和市场需求可能迅速变化。 然而，管理多组分系统也会带来挑战。协调各个组件之间的相互作用需要仔细的规划和执行。此外，确保每个部分在更大系统中正常运作需要持续的监测和维护。这种复杂性强调了跨学科合作的重要性，因为来自不同领域的专业知识可以为成功实施多组分解决方案做出贡献。 总之，多组分系统的概念在现代生活的许多领域中都是不可或缺的。无论是在工程、医学还是环境科学中，将多个组件整合以实现共同目的都能带来更有效和创新的解决方案。随着我们继续面临复杂的挑战，拥抱多组分方法将对促进进步和改善各个领域的结果至关重要。