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删除35字节 、 2020年12月7日 (一) 14:23
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In thermodynamics, dissipation is the result of an irreversible process that takes place in homogeneous thermodynamic systems. A dissipative process is a process in which energy (internal, bulk flow kinetic, or system potential) is transformed from some initial form to some final form; the capacity of the final form to do mechanical work is less than that of the initial form. For example, heat transfer is dissipative because it is a transfer of internal energy from a hotter body to a colder one. Following the second law of thermodynamics, the entropy varies with temperature (reduces the capacity of the combination of the two bodies to do mechanical work), but never decreases in an isolated system.
 
In thermodynamics, dissipation is the result of an irreversible process that takes place in homogeneous thermodynamic systems. A dissipative process is a process in which energy (internal, bulk flow kinetic, or system potential) is transformed from some initial form to some final form; the capacity of the final form to do mechanical work is less than that of the initial form. For example, heat transfer is dissipative because it is a transfer of internal energy from a hotter body to a colder one. Following the second law of thermodynamics, the entropy varies with temperature (reduces the capacity of the combination of the two bodies to do mechanical work), but never decreases in an isolated system.
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在热力学中,<font color="#ff8000"> 耗散 Dissipation</font>是在均匀热力学系统中发生的不可逆性的结果。耗散过程是能量(内部的、[[整体流动动力学]]或系统势)从某种初始形式转化为某种最终形式的过程,最终形式做机械功的能力小于初始形式做机械功的能力。例如,热传递是耗散的,因为它是内能从一个较热的物体向一个较冷的物体的转移。根据热力学第二定律,熵随温度变化(降低了两个物体组合做机械功的能力) ,但是在一个孤立的系统中熵从不减少。
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在热力学中,<font color="#ff8000"> 耗散 dissipation</font>是在均匀热力学系统中发生的不可逆过程。耗散过程是能量(内能、[[整体流动动力学]]或系统势能)从某种初态转化为某种终态的过程,终态做机械功的能力小于初态做机械功的能力。例如,热传递是耗散的,因为它是内能从一个较热的物体向一个较冷的物体的转移。根据热力学第二定律,熵随温度变化(降低了两个物体组合做机械功的能力) ,但是在一个孤立的系统中熵从不减少。
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Waves or oscillations, lose energy over time, typically from friction or turbulence. In many cases, the "lost" energy raises the temperature of the system. For example, a wave that loses amplitude is said to dissipate. The precise nature of the effects depends on the nature of the wave: an atmospheric wave, for instance, may dissipate close to the surface due to friction with the land mass, and at higher levels due to radiative cooling.
 
Waves or oscillations, lose energy over time, typically from friction or turbulence. In many cases, the "lost" energy raises the temperature of the system. For example, a wave that loses amplitude is said to dissipate. The precise nature of the effects depends on the nature of the wave: an atmospheric wave, for instance, may dissipate close to the surface due to friction with the land mass, and at higher levels due to radiative cooling.
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波或振荡,随着时间的推移会失去能量,通常是由于摩擦或紊流。在许多情况下,“损失”的能量提高了系统的温度。例如,失去振幅的波叫做消散波。影响的确切性质取决于波的性质: 例如,大气波可能由于与地块的摩擦而于接近地表处消散,由于辐射冷却的缘故而在更高的水平上消散。
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波或振荡,通常会由于摩擦或紊流而随着时间的推移失去能量。在许多情况下,“损失”的能量提高了系统的温度。例如,失去振幅的波叫做消散波。影响的确切性质取决于波的性质: 例如,大气波可能由于与地块的摩擦而于接近地表处消散,由于辐射冷却的缘故而在更高的水平上消散。
     
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