📚 A-Level Physics Unit 5 Insert (Jan 2020) Formula Derivations | A-Level 物理单元5 2020年1月公式表推导
In the January 2020 A-Level Physics Unit 5 examination, students are provided with a formula insert that summarises key equations from thermodynamics, nuclear physics and oscillations. This article presents step-by-step derivations of those core formulas, linking macroscopic laws with microscopic models and mathematical principles. By working through these derivations, you gain a deeper understanding of the underlying physics and will be better prepared to apply the equations correctly in exams.
在2020年1月A-Level物理单元5的考试中,考生会收到一份公式表,归纳了热力学、核物理和振动中的关键方程。本文将这些核心公式进行逐步推导,将宏观定律与微观模型和数学原理联系起来。通过梳理这些推导过程,你可以更深刻地理解背后的物理,并在考试中更准确地运用这些方程。
1. Ideal Gas Equation and Microscopic Pressure | 理想气体方程与微观压强
The ideal gas equation, pV = nRT, combines the experimental gas laws (Boyle’s law, Charles’ law and Avogadro’s hypothesis). On a microscopic scale, the pressure exerted by a gas arises from the rate of change of momentum of molecules colliding with the container walls. For a single molecule of mass m travelling with speed ux perpendicular to a wall of a cubic box of side L, the momentum change per collision is 2m ux, and the time between collisions with that wall is 2L/ux. The average force on the wall due to one molecule is therefore F = (2m ux) / (2L/ux) = m ux2/L.
理想气体方程pV = nRT综合了实验气体定律(玻意耳定律、查理定律和阿伏伽德罗假说)。在微观尺度上,气体压强源于分子与容器壁碰撞时的动量变化率。对于质量为m、以速度ux垂直撞向边长为L的立方体箱壁的单个分子,每次碰撞的动量变化为2m ux,与同一器壁相邻两次碰撞的时间间隔为2L/ux。因此,一个分子对器壁的平均作用力为F = (2m ux) / (2L/ux) = m ux2/L。
Summing over all N molecules and taking the average of ux2, the total force on the wall is F = (m/L) Σ uxi2 = (N m / L) <ux2>, where <ux2> denotes the mean square x-component of speed. Because the motion is random, the mean square speed <c2> = <ux2> + <uy2> + <uz2> = 3 <ux2>. Hence
对所有N个分子求和,并取ux2的平均值,墙上的总力为F = (m/L) Σ uxi2 = (N m / L) <ux2>,其中<ux2>表示x方向速度分量平方的平均值。由于运动无规,均方速率<c2> = <ux2> + <uy2> + <uz2> = 3 <ux2>。因此
p = F / L2 = (N m / L3) <ux2> = (1/3) (N m / V) <c2> = (1/3) ρ <c2>
where ρ = N m / V is the gas density. For an ideal gas, the macroscopic equation can be written as pV = NkT, where k is the Boltzmann constant and N is the number of molecules. Equating (1/3) N m <c2> with NkT gives a direct link between the micro- and macro-worlds.
式中ρ = N m / V为气体密度。对于理想气体,宏观方程可写成pV = NkT,其中k为玻尔兹曼常数,N为分子数。令(1/3) N m <c2>等于NkT,便可直接联系微观与宏观世界。
2. Temperature and Average Kinetic Energy | 温度与平均动能的关系
From the equivalence pV = (1/3) N m <c2> and the ideal gas equation pV = NkT, we can cancel N and rearrange:
由等式pV = (1/3) N m <c2>和理想气体状态方程pV = NkT,可消去N并整理:
(1/3) m <c2> = kT
The average translational kinetic energy of a single molecule is KEavg = ½ m <c2>. Substituting gives KEavg = (3/2) kT. This result is crucial: it shows that the absolute temperature of an ideal gas is directly proportional to the average random kinetic energy of its particles. For one mole of gas (N = NA), the total internal kinetic energy is U = (3/2) nRT, where R = NA k.
单个分子的平均平动动能为KEavg = ½ m <c2>。代入得KEavg = (3/2) kT。这一结果至关重要:它表明理想气体的绝对温度与其粒子平均无规动能成正比。对一摩尔气体(N = NA),总的内动能U = (3/2) nRT,其中R = NAk。
3. Adiabatic Process Equation pVγ = constant | 绝热过程方程pVγ = 常数
In an adiabatic process, no heat enters or leaves the system (Q = 0). The first law of thermodynamics states ΔU = Q – W, so for an adiabatic change ΔU = -W = -p ΔV. For an ideal gas, the change in internal energy can also be written as ΔU = n Cv ΔT, where Cv is the molar heat capacity at constant volume. Therefore, n Cv ΔT = -p ΔV.
在绝热过程中,系统与外界无热量交换(Q = 0)。热力学第一定律ΔU = Q – W,因此绝热变化有ΔU = -W = -p ΔV。对于理想气体,内能变化也可写成ΔU = n Cv ΔT,其中Cv为等容摩尔热容。于是n Cv ΔT = -p ΔV。
For an ideal gas, pV = nRT. Differentiating both sides gives p dV + V dp = nR dT. Substituting dT from the energy relation, we have p dV + V dp = – (nR / n Cv) p dV = – (R / Cv) p dV. Using the relationship Cp – Cv = R, where Cp is the molar heat capacity at constant pressure, and introducing the adiabatic index γ = Cp / Cv, we write R/Cv = γ – 1. The differential equation becomes p dV + V dp = -(γ – 1) p dV, or V dp = -γ p dV.
对理想气体pV = nRT,两边微分得p dV + V dp = nR dT。利用能量关系代入dT,得到p dV + V dp = – (nR / n Cv) p dV = – (R / Cv) p dV。利用迈耶关系Cp – Cv = R,其中Cp为等压摩尔热容,并引入绝热指数γ = Cp / Cv,有R/Cv = γ – 1。上述微分方程化为p dV + V dp = -(γ – 1) p dV,即V dp = -γ p dV。
Separating variables and integrating:
分离变量并积分:
∫ dp/p = -γ ∫ dV/V ⇒ ln p = -γ ln V + constant
This yields ln(p Vγ) = constant, or
由此可得ln(p Vγ) = 常数,即
p Vγ = constant
which is the well-known adiabatic equation. Using pV = nRT, it can also be expressed as T Vγ – 1 = constant or T p(1 – γ)/γ = constant.
这就是著名的绝热过程方程。利用pV = nRT,还可表达为T Vγ – 1 = 常数或T p(1 – γ)/γ = 常数。
4. Efficiency of a Carnot Engine | 卡诺热机效率
A Carnot cycle consists of two reversible isothermal and two reversible adiabatic processes. For the high-temperature isothermal expansion at Th, the heat absorbed from the hot reservoir is Qh = nR Th ln(V2/V1). For the low-temperature isothermal compression at Tc, the heat rejected to the cold reservoir is Qc = nR Tc ln(V3/V4), with positive magnitude.
卡诺循环由两个可逆等温过程和两个可逆绝热过程组成。在高温Th下的等温膨胀中,从高温热源吸收的热量为Qh = nR Th ln(V2/V1)。在低温Tc下的等温压缩中,向低温热源放出的热量为Qc = nR Tc ln(V3/V4)(取正值)。
The two adiabatic stages link the volumes: Th V2γ – 1 = Tc V3γ – 1 and Th V1γ – 1 = Tc V4γ – 1. Dividing these two equations gives (V2/V1)γ – 1 = (V3/V4)γ – 1, hence V2/V1 = V3/V4. Therefore, the magnitudes of the heats satisfy Qc/Qh = Tc/Th.
两个绝热阶段将体积关联起来:Th V2<
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