理想气体

Week 6 Equilibrium state, basic concept of gas kinetics, pressure equation and temperature equation of ideal gas, theorem of equipartition of energy, internal energy of ideal gas.

第6周 平衡态、气体动理论的基本概念、理想气体的压强和温度公式。能量均分定理、理想气体的内能。

This paper refers to the definition of ideal gas and proves the equation of state from the view of kinetic theory, thermodynamics and statistical physics.

摘要给出理想气体的严格定义，并从分子运动论、热力学和统计物理等方面给出理想气体状态方程不同的证明方法。

Besides the previous research finding, the ideal gas equation and ideal gas, fluid dynamics and thermal dynamics were also included in the derivation of the equation of state of the detonation Wave.

目前国内可量测爆震波速度的仪器并不普遍，因此爆震波速度值得之不易，想利用爆震波速度来探讨爆破震动的特性更是难上加难，本文将依据理想气体方程式、流体动力学、热力学、理想气体多变定律和相关的经验公式，结合冲击波和爆震波传递时质量、能量和动量守恒的理论，推导爆震波的状态方程式，并藉由爆震波的状态方程式了解爆震波的特性及其应用。

Basic contents: calculation of specific heat of ideal gas; gas mixture

基本内容：理想气体比热的计算，理想混合气体

Secondly, the flow of condensation steam was compared with the flow of ideal gas. From the contrasted results, it can be found the difference between the condensative steam flowing and ideal-gas flowing. And, it also can be found out that it is inevitable to condense for steam flowing under the supersonic state. At the same time, the major areas which formed second drips have been displayed in the solved results. Finally, the flow of condensation steam in the 3-dimension model has been simulated.

其次，对比了具有凝结的蒸汽与理想气体之间的流动情况，经过对比可以发现凝结蒸汽在流动中与理想气体之间的差异，发现蒸汽的凝结在超音速状态下是不可避免的，并且在计算结果中通过图形显示出了形成二次水滴的主要区域。

Evidently, between the ideal gas and the real gas, the equation of the state of the ideal gas and Van der Waals' equation as well as the corresponding terms in them, the former is more abstract, while the latter more concrete; the former is simpler, while the latter is richer in its determinativeness.

显然，理想气体与真实气体比较，理想气体状态方程与范德瓦耳斯方程比较，包括其中各对应项的比较），前者更抽象，后者更具体；前者更简单，后者规定性更丰富。

We then add boundaries delineated forward/backward facing reflected shock, Mechanical equilibrium, M2=1 and reflected shock strong/weak separating conditions on the (M0,q1) map of shih(2004). This is followed by systematically investigating multiply possible three shock theoretical solutions of steady Mach reflections in perfect triatomic gases. Pressure-deflection shock polar solutions are used to help illustrate different solution behaviors of these theoretical three-shock solutions. M0 is flow Mach no. upstream of incident shock, M1 is flow Mach no. downstream of incident shock, M2 is flow Mach no. downstream of reflected shock,q1 is flow deflection downstream of incident shock.

随后本文由石(2004)论文中加入前后分界、机械平衡、M2=1及强弱分界条件，然后有系统地探讨三原子分子理想气体(r=1.2857 )稳态马赫反射参震波理论多重解之交点及其对应之压力-转折角震波极图解，并建构出此三原子分子理想气体稳态马赫反射流场三震波十阶多项式理论解於(Mo，q1)平面上之解域图，其中M0为入射震波上游流场马赫数，M1为入射震波下游流场马赫数，M2为入射震波下游流场马赫数，q1为入射震波下游流场转折角。

At the beginning,the necessity of taking quantum effect into consideration when studying Diesel cycle is put forward,and the prospects of the cycle application to practical uses are noted.

在分析了研究狄塞尔循环时需要考虑其量子效应的必要性以及该循环在实际社会生产中的广泛应用前景后，首先给出以理想气体为工作物质的狄塞尔循环的效率表达式，然后以理想费米气体为例，根据其状态方程及其热力学性质获得以理想量子气体为工作物质的狄塞尔循环的效率表达式，通过比较得出提高实际热机效率的主要途径。

On the basis of the concept of perfect quantum gas, a physical model of extreme relativity is established for perfect quantum gas, and also according to the conclusions of the state density of the extreme theory of relativity, the densities of quantum statistics′ particle numbers and energy, the extreme relativity′s result of the enthalpy、internal energy and heat capacity of the perfect quantum gas is obtained under the high temperature by strict theory inference.

在理想量子气体概念的基础上，首先建立极端相对论理想量子气体的物理模型；再根据极端相对论的态密度和量子统计的粒子数、能量的密度结论，通过严格的理论推导，得出理想量子气体在高温条件下的极端相对论性的焓、内能和热容量的结果，并将其热容量与高温条件下的理想量子气体、经典理想气体的热容量对比，指出极端相对论与非相对论两种模型、理想量子气体与经典理想气体两种模型的热容量之间的差异，同时分析这些差异的物理原因在于各自气体模型的态密度以及对应体系的波函数的对称性；最后阐明高温条件下极端相对论理想量子气体的热容量在量子统计方面的先进性及应用前景。

Finally it clarifies the advance in quantum statistics and the practical prospect of heat capacity of the extreme relativity's perfect quantum gas under high tamperature.

摘 要：在理想量子气体概念的基础上，首先建立极端相对论理想量子气体的物理模型；再根据极端相对论的态密度和量子统计的粒子数、能量的密度结论，通过严格的理论推导，得出理想量子气体在高温条件下的极端相对论性的焓、内能和热容量的结果，并将其热容量与高温条件下的理想量子气体、经典理想气体的热容量对比，指出极端相对论与非相对论两种模型、理想量子气体与经典理想气体两种模型的热容量之间的差异，同时分析这些差异的物理原因在于各自气体模型的态密度以及对应体系的波函数的对称性；最后阐明高温条件下极端相对论理想量子气体的热容量在量子统计方面的先进性及应用前景。

ideal gas equation：理想气体方程

ideal gas 理想气体 | ideal gas equation 理想气体方程 | ideal gas temperature scale 理想气体温标

ideal gas state equation：理想气体状态方程

ideal gas law 理想气体定律 | ideal gas state equation 理想气体状态方程 | ideal liquid 理想液体

ideal gas law equation：理想气体定律方程式

ideal gas constant 理想气体常数 | ideal gas law equation 理想气体定律方程式 | ideal gas temperature scale 理想气体温标

state equation of ideal gas：理想气体状态方程

理想气体绝热可逆过程方程 adiabatic reversible process equation of ideal gases | 理想气体状态方程 state equation of ideal gas | 理想稀溶液 ideal dilute solution

ideal gas：理想气体=>完全気体

ideal fuel 标准燃料 | ideal gas 理想气体=>完全気体 | ideal gas constant 理想气体常数

ideal gas model：理想气体模型

ideal gas 理想气体 | ideal gas model 理想气体模型 | ideal mechanical advantage 理想机械利益

adiabatic reversible process equation of：理想气体绝热可逆过程方程

理想气体反应的等温方程 isothermal equation of ideal gaseous | 理想气体绝热可逆过程方程 adiabatic reversible process equation of | 理想气体状态方程 state equation of ideal gas

adiabatic reversible process equation of ideal：理想气体绝热可逆过程方程

理想气体反应的等温方程 isothermal equation of ideal gaseous reactions | 理想气体绝热可逆过程方程 adiabatic reversible process equation of ideal | 理想气体状态方程 state equation of ideal gas

perfect gas equation：理想气体状态方程式

perfect gas 理想气体 | perfect gas equation 理想气体状态方程式 | perfect plasticity 理想塑性

perfect gas constant：理想气体常数

perfect gas ==> 理想气体 | perfect gas constant ==> 理想气体常数 | perfect gas equation ==> 理想气体状态方程式