entropically

简明释义

英[enˈtrɒpɪkli;enˈtrəʊpɪkli]美[enˈtrɑːpɪkli]

与熵有关，关于熵

英英释义

单词用法

同义词

反义词

例句

1.we'll look at entropically driven processes.

我们来看看由熵驱动的过程。

2.we'll look at entropically driven processes.

我们来看看由熵驱动的过程。

3.And again, it's still entropically driven.

同样的，它仍是熵驱动的。

4.And we know it's entropically driven.

我们知道它是由熵驱动的。

5.The system tends to evolve towards a state that is more disordered, which can be described as becoming more entropically 熵增的 stable over time.

这个系统倾向于演变到一个更加无序的状态，这可以被描述为随着时间的推移变得更加熵增的稳定。

6.In thermodynamics, reactions that are entropically 熵增的 favorable will occur spontaneously at room temperature.

在热力学中，熵增的反应将在室温下自发发生。

7.When considering the distribution of molecules in a gas, we find that they spread out entropically 熵增地 to maximize entropy.

在考虑气体中分子分布时，我们发现它们以熵增地方式扩散，以最大化熵。

8.The entropically 熵增的 nature of mixing two different gases results in a higher overall entropy.

混合两种不同气体的熵增的特性导致整体熵增加。

9.This process is entropically 熵增的 driven, meaning it leads to increased disorder in the system.

这个过程是熵增的驱动的，这意味着它导致系统中的无序增加。

作文

In the study of thermodynamics, the concept of entropy is fundamental. It refers to the measure of disorder or randomness in a system. When we say that a process occurs entropically, we mean that it is driven by an increase in disorder. For instance, consider the melting of ice into water. At lower temperatures, the molecules in ice are arranged in a structured lattice, which is a low-entropy state. As the ice melts, the molecules gain energy and move freely, resulting in a higher-entropy state as they transition into liquid water. This example illustrates how natural processes tend to favor states of higher entropy, aligning with the second law of thermodynamics. In everyday life, we can observe entropically driven processes all around us. For example, when a room is left untidy, it tends to become more disordered over time. This is because systems naturally evolve towards states with higher entropy unless energy is input to maintain order. The act of cleaning a room requires effort and energy, which temporarily decreases the entropy of that space. However, without continued effort, the room will eventually return to its chaotic state. The implications of entropically driven processes extend beyond physical systems; they also apply to information and social dynamics. In information theory, for example, systems tend to become more disordered as information is lost or corrupted over time. Similarly, in social contexts, relationships may deteriorate or become less organized without active maintenance, reflecting an entropically influenced decline. Understanding the role of entropy helps us grasp why certain phenomena occur. For instance, when we mix different colored paints, the result is a uniform color that reflects a state of higher entropy. Initially, the separate colors represent a lower entropy state, but mixing them leads to greater disorder. This principle can be seen in various fields, from chemistry to ecology, where systems evolve towards equilibrium states characterized by maximum entropy. In conclusion, the term entropically encompasses the idea that many processes in nature are driven by a tendency towards increased disorder. Whether in physical, informational, or social systems, recognizing this tendency allows us to better understand and predict behaviors. The concept of entropy serves as a reminder of the natural inclination toward chaos, urging us to actively engage in maintaining order in our lives and environments. By acknowledging the entropically driven nature of the world, we can make more informed decisions about how we interact with our surroundings and manage our resources effectively.

在热力学研究中，熵的概念是基础。它指的是系统中无序或随机性的度量。当我们说一个过程是entropically驱动时，我们的意思是它是由无序的增加所推动的。例如，考虑冰融化成水的过程。在较低的温度下，冰中的分子排列成有结构的晶格，这是一个低熵状态。随着冰的融化，分子获得能量并自由移动，导致它们转变为液态水，从而产生更高的熵状态。这个例子说明了自然过程倾向于优先考虑高熵状态，这与热力学第二定律相一致。 在日常生活中，我们可以在周围观察到entropically驱动的过程。例如，当一个房间被留得杂乱时，它往往会随着时间的推移变得更加无序。这是因为系统自然地向高熵状态演变，除非输入能量以保持秩序。清理房间的行为需要努力和能量，这暂时降低了该空间的熵。然而，如果没有持续的努力，房间最终会返回到混乱的状态。 entropically驱动过程的影响超越了物理系统；它们也适用于信息和社会动态。例如，在信息理论中，系统往往随着时间的推移变得更加无序，因为信息丢失或被破坏。类似地，在社会背景中，关系可能会恶化或变得不那么有序，而无需积极维护，反映出entropically影响的衰退。 理解熵的作用帮助我们掌握某些现象发生的原因。例如，当我们将不同颜色的油漆混合时，结果是均匀的颜色，反映出一种更高熵状态的特征。最初，分开的颜色代表一种较低的熵状态，但将它们混合会导致更大的无序。这一原则可以在化学到生态学的各个领域中看到，系统向最大熵特征的平衡状态演变。 总之，entropically这个术语包含了许多自然过程是由增加无序的倾向驱动的思想。无论是在物理、信息还是社会系统中，认识到这一倾向使我们能够更好地理解和预测行为。熵的概念提醒我们自然倾向于混乱，促使我们积极参与维护生活和环境中的秩序。通过承认世界的entropically驱动性质，我们可以更明智地决定如何与周围环境互动并有效管理我们的资源。