dissipative

简明释义

英[ˈdɪsɪpeɪtɪv]美[ˈdɪsɪˌpeɪtɪv]

adj. 浪费的；消耗的；消散的

英英释义

单词用法

同义词

反义词

例句

1.Standard Entropy, standard Dissipative Structure, Ordering, Operation Mechanism of standardization.

标准熵；标准耗散结构；有序化；标准化运行机制。

2.According to test datum, adaptive velocity scope of barrel dissipative mufflers is concluded.

根据试验数据，得到了筒式阻性消声器的适应流速范围。

3.The primary stands containing time factors was the start of "dissipative structure".

具有时间因素的初始林分，是“耗散结构”的起点。

4.The order and vigor in dissipative structure accord with the goal of industry structure changing.

耗散结构的有序与活力和产业结构转换的目标是一致的。

5.This is a coupled non parabolic dissipative dynamic system.

这是一个耦合的非抛物耗散动力系统。

6.In this paper, we investigate the entanglement dynamics of two entangled two-level atoms interacting with a single_mode field in a dissipative cavity.

研究了能量损耗腔中，两纠缠二能级原子与单模辐射场相互作用过程中原子的纠缠动力学。

7.Dissipative effects are not allowed in reversible process.

可逆过程中不存在耗散效应。

8.In thermodynamics, a dissipative system is one that loses energy to its surroundings, leading to a decrease in available energy.

在热力学中，dissipative 系统是指向其周围环境失去能量，从而导致可用能量减少的系统。

9.The dissipative nature of friction converts kinetic energy into thermal energy.

dissipative 摩擦的特性将动能转化为热能。

10.During the process of sound propagation, some energy is lost as dissipative effects occur.

在声音传播过程中，由于发生了dissipative 效应，一些能量会丧失。

11.In fluid dynamics, dissipative forces like viscosity play a crucial role in energy loss.

在流体动力学中，像粘度这样的dissipative 力在能量损失中起着至关重要的作用。

12.The dissipative structures in nonlinear systems can lead to unexpected behaviors.

非线性系统中的dissipative 结构可能导致意想不到的行为。

作文

In the realm of physics and engineering, the term dissipative refers to processes that involve the dissipation of energy. This concept is crucial in understanding how systems lose energy over time, often transforming it into less useful forms such as heat. For instance, when a car brakes, the kinetic energy of the vehicle is converted into thermal energy due to friction, which is a classic example of a dissipative process. This transformation is not only inevitable but also fundamental in various applications ranging from mechanical systems to thermodynamics. The significance of dissipative processes extends beyond simple energy loss; they play a pivotal role in maintaining the stability and functionality of many systems. In biological systems, for example, dissipative structures are essential for life. These structures, which arise in open systems far from equilibrium, allow organisms to maintain their complexity and organization despite the constant influx of energy and matter from their environment. The concept was famously illustrated by physicist Ilya Prigogine, who proposed that life itself is a result of dissipative processes that create order out of chaos. Moreover, in the field of climate science, dissipative phenomena are critical in understanding energy transfer within the atmosphere and oceans. When solar energy reaches the Earth, it is not merely absorbed; rather, it undergoes a series of transformations and dissipations that influence weather patterns and climate systems. The dissipative nature of these processes can lead to both stability and instability in climatic conditions, demonstrating the delicate balance that governs our planet’s environment. In engineering, the design of systems often takes dissipative effects into account to enhance efficiency and performance. For example, in the design of electronic circuits, engineers must consider the dissipative losses that occur due to resistance in materials. By minimizing these losses through better materials or innovative designs, engineers can significantly improve the overall efficiency of electronic devices. This highlights the importance of understanding dissipative mechanisms not only for theoretical insights but also for practical applications that impact technology and daily life. Furthermore, the concept of dissipative systems can be applied metaphorically to social and economic contexts. Just as energy dissipates in physical systems, resources in society can be seen as dissipative in nature. Wealth, for instance, can be lost or redistributed in ways that reflect the dissipative dynamics of human interactions and economic activities. Understanding these dynamics can help policymakers address issues like inequality and resource management more effectively. In conclusion, the term dissipative encompasses a wide range of phenomena across various fields, from physics to biology and even social sciences. Its implications are profound, revealing the underlying principles that govern energy flow and transformation in both natural and engineered systems. By studying dissipative processes, we gain valuable insights into the behavior of complex systems, enabling us to innovate and adapt in an ever-changing world. As we continue to explore the intricacies of dissipative mechanisms, we unlock new potentials for sustainability and efficiency in our technologies and societies.

在物理和工程领域，术语dissipative指的是涉及能量耗散的过程。这个概念对于理解系统如何随时间损失能量至关重要，通常将其转化为热等不太有用的形式。例如，当汽车刹车时，车辆的动能由于摩擦而转化为热能，这是一个经典的dissipative过程。这种转化不仅是不可避免的，而且在从机械系统到热力学的各种应用中都是基础性的。 dissipative过程的重要性超越了简单的能量损失；它们在维持许多系统的稳定性和功能性方面发挥着关键作用。在生物系统中，例如，dissipative结构对生命至关重要。这些结构产生于远离平衡的开放系统，使生物体能够在不断从环境中吸收能量和物质的情况下维持其复杂性和组织性。物理学家伊利亚·普里戈金（Ilya Prigogine）著名地提出，生命本身就是一种通过dissipative过程在混乱中创造秩序的结果。 此外，在气候科学领域，dissipative现象对于理解大气和海洋中的能量传递至关重要。当太阳能达到地球时，它并不是简单地被吸收；相反，它经历了一系列转化和耗散，这影响着天气模式和气候系统。这些过程的dissipative特性可以导致气候条件的稳定与不稳定，展示了支配我们星球环境的微妙平衡。 在工程中，系统的设计通常会考虑dissipative效应，以提高效率和性能。例如，在电子电路的设计中，工程师必须考虑由于材料的电阻而发生的dissipative损失。通过更好地选择材料或创新设计来最小化这些损失，工程师可以显著提高电子设备的整体效率。这突显了理解dissipative机制的重要性，不仅是为了理论见解，也是为了影响技术和日常生活的实际应用。 此外，dissipative系统的概念可以比喻性地应用于社会和经济背景。正如能量在物理系统中耗散一样，社会中的资源也可以被视为具有dissipative性质的。例如，财富可以以反映人类互动和经济活动的dissipative动态的方式丧失或重新分配。理解这些动态可以帮助政策制定者更有效地解决不平等和资源管理等问题。 总之，术语dissipative涵盖了各个领域的广泛现象，从物理学到生物学甚至社会科学。它的影响深远，揭示了支配自然和工程系统中能量流动和转化的基本原理。通过研究dissipative过程，我们获得了关于复杂系统行为的宝贵见解，使我们能够在不断变化的世界中进行创新和适应。随着我们继续探索dissipative机制的复杂性，我们为可持续性和效率在我们的技术和社会中打开了新的潜力。