And other macroscopic quantities.
以及其他的宏观量。
Between the macroscopic and the microscopic.
而宏观量与微观量之间。
And continue to derive the macroscopic entropy changes.
继续得到宏观的熵变。
So it's a science that's based on macroscopic properties of matter.
所以它是一门,基于物质宏观性质的科学。
But it's all mixed up together in a homogeneous, macroscopic fashion.
但是它们在宏观上,以均匀的方式融合了。
The one that is at equilibrium, there is only one macroscopic state at equilibrium.
处于平衡的状态,并且只有一个平衡的宏观状态。
There are microcosmic and macroscopic differences in study on consumer behavior.
对消费者行为的研究有微观和宏观之分。
And then from that, statistically averaging, what are the macroscopic average energies.
然后通过统计平均,得到宏观的平均能量。
Then, it explains the macroscopic and microscopic effects of assets reorganization.
随后对资产重组的宏观和微观效应进行经济解释。
Changing the shape of an aircraft can be done at a microscopic as well as a macroscopic level.
我们既可以在微观上也可以在宏观上改变飞机的形状。
From a macroscopic view, art can be anything that is created to express something of you.
从肉眼看,艺术可以是任何东西创造出来展示在你面前。
Makes a macroscopic description by this on the current farmer social stratum differentiation.
以此对当前的农民阶层分化做一个宏观描述。
I should be able to start from my microscopic picture and get to macroscopic thermodynamic results.
我们能够从微观图像出发,最终得到宏观热力学的结果。
And then saying, well, OK, my macroscopic stuff is just a collection of those microscopic entities.
然后说,好的,我们的宏观物质,只是大量微观物体的集合。
Macroscopic classification for bituminous coal is one of the research tasks for coal petrology.
烟煤的宏观煤岩分类是煤岩学研究的内容之一。
And we should be able to calculate the entropy change that we saw before from a macroscopic perspective.
我们应该能计算出熵变,之前我们从宏观的角度得到过。
At a more macroscopic level, an entire Saxon transformation can also be manipulated as a SAX filter.
从更宏观的角度看,整个Saxon转换还可以当作SAX过滤器来进行操作。
The absorption term also is relatively straight forward, macroscopic absorption cross section times the flux.
吸收项也是相对直接的,宏观吸收横截面乘以流量。
And actually just like macroscopic thermodynamics, kinetics does take an empirical approach to the topic.
实际上就像热力学一样,动理学的研究方法也是经验性的。
To take what we know about the microscopic properties and try to go from there to the macroscopic results.
利用我们所知的,物质的微观属性,然后从微观属性得到物质的宏观属性。
The 'wave' properties of macroscopic matter are not apparent because the wavelength is undetectably small.
宏观物质的波动特性不明显,因为其波长很短,难以被察觉。
From these quantities alone, it turns out you'll be able to calculate every single macroscopic thermodynamic quantity.
仅仅从这些量,最终你可以计算,所有的宏观物理量。
So in other words, macroscopic thermodynamic properties come straight out of our microscopic model of statistical mechanics.
换句话说,宏观的热力学性质可以,从微观模型,的统计力学得到。
Usually nobody CARES about this field-at any macroscopic distance from the chip surface, the field is immeasurably small.
通常没人在乎这些磁场——只要离开晶片表面较远的距离,磁场就会小到难以测量。
And that is measured as a macroscopic cross section of absorption thermal divided by the integral of all energies in terms of absorptions.
那是被测量的,作为吸收热能的,宏观横截面,除以全部的,吸收的能量的乘积。
And the reason is, as we'll see shortly, it turns out that every single macroscopic thermodynamic function can be Derived by knowing just that.
原因在于,我们待会就会看到,这个求和可以推导,任何一个体系的宏观热力学量,得到结果之后。
Most recently, it turns out that a piece of levitating graphene can spin faster than any other macroscopic object, thanks to its incredible strength.
最新的研究表明,由于它超高的强度,这样一块石墨薄膜在悬空情况下可以比其它任何宏观物体转的更快。
What that suggests is that actually the simplest and most natural connection between Q and macroscopic thermodynamics is to the Helmholtz free energy.
这暗示我们,最简单最自然的联系,在Q和宏观热力学两之间,是和亥姆霍兹自由能的联系。
What that suggests is that actually the simplest and most natural connection between Q and macroscopic thermodynamics is to the Helmholtz free energy.
这暗示我们,最简单最自然的联系,在Q和宏观热力学两之间,是和亥姆霍兹自由能的联系。
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