All driven by entropy of mixing.
所有这些都是由混合熵引起的。
So that's our entropy of mixing.
那就是我们混合物的熵。
Just from the entropy of mixing.
因为混合熵。
Entropy of mixing comes in here.
熵从这来。
Let's now look at the entropy of mixing.
让我们来看看混合熵。
And it's all driven by entropy of mixing.
这些的基本原因都是熵的混合。
So entropy of mixing is really super important.
所以混合中的熵是非常重要的。
What's the magic word? Entropy of mixing, right.
魔幻词汇是什么?混合熵。
And the entropy of mixing was really super important.
混合熵非常重要。
So we can just explicitly calculate the entropy of mixing.
这样我们能更明确地,计算混合后的熵。
The entropy of mixing of reactants and products wasn't there.
没有反应物和生成物的熵。
Because you've got entropy of mixing happening in all of this.
因为我们得到的是所有这些混合的熵。
If entropy of mixing wasn't there, I would start from up here.
如果没有混合熵,那么就是从这里开始。
Without entropy of mixing, we would be sitting on this curve here.
没有混合熵,我们得到的就是这条曲线。
Specifically, how entropy of mixing really becomes key to equilibrium.
特别地,为什么熵的混合,对于平衡态如此重要。
So now I've got the entropy of mixing even in a condensed phase the liquid.
那么现在我们已经得到混合物的熵,即使对相对浓缩的液相。
B So when you mix a and B, you're going to have the same entropy of mixing.
当混合a和,有同样的混合熵。
Without entropy of mixing, then everything would go directly to the products.
没有混合熵的话,所有的东西都会变成产物。
I add a little bit of inert gas, there's a little bit more entropy of mixing.
加入一点惰性气体,就会有一点混合熵。
But the entropy of mixing is causing my initial state and my final state to go down.
但是熵会导致初始状态,和末状态下降。
D Because if I have equal amounts of a, B, c, and d, that's a lot of entropy of mixing there.
因为如果我们有等量的A,B,C和,那么混合熵会很大。
If I have nothing, if I have no a here, up here and just the inert gas, then there's no entropy of mixing.
如果没有A物质,而只有惰性气体的话,那么就不会有混合熵。
Right. There's more entropy of mixing if you've got a mixture in the liquid than if you have a pure gas up there.
对,最终的熵会更大,如果你把液体混合的话,会比纯物质的熵大。
If that's not zero, unlike the ideal case, now unlike before, where we just had entropy driving the mixture, now there's an energy of mixing.
如果那不是零,和理想的情况不同,和以前不同,以前我们只有熵来驱动混合,现在有混合能。
The entropy generation and the exergy loss vary similarily with the change of mixing ratio, they first increased then decreased and both reached a maximum at a fraction of COG around 48%.
随着混合比例的增加,混合熵增加和损的变化规律相同,即先增大再减小,且在焦炉煤气体积分数约为48%处达到极大熵增加和损。
This last equation does not contradict the entropy-of-mixing formula.
此式与混合熵公式并不矛盾。
The mixing degree of atomic initial state has no influence on the entropy squeezing of the atom in motion.
原子初态的混合度对运动原子的信息熵压缩几乎没有影响。
The law states that entropy increases during irreversible processes such as spontaneous mixing of hot and cold gases, uncontrolled expansion of a gas into a vacuum, and combustion of fuel.
根据这一定律,在热气体与冷气体的自发混合、气体向真空的自由膨胀以及燃料的燃烧之类的不可逆过程中,熵都是增加的。
Based on thermodynamic principles, entropy generation and exergy loss of BFG (Blast Furnace Gas) and COG (Coke Oven Gas) during mixing were studied.
从热力学原理出发,研究了高、焦炉煤气混合过程的熵增加和损失。
Based on thermodynamic principles, entropy generation and exergy loss of BFG (Blast Furnace Gas) and COG (Coke Oven Gas) during mixing were studied.
从热力学原理出发,研究了高、焦炉煤气混合过程的熵增加和损失。
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