So your heat capacity is zero.
所以你的热容是零。
So the heat capacity is zero again.
所以热容又是零。
And the heat capacity is a constant.
热容是常数。
Which means the heat capacity is zero.
那意味着热容为零。
So now we can look at the heat capacity.
那么现在让我们来看看热容。
So why should the heat capacity be zero?
那么为什么热容要为零?
And that means the heat capacity is zero.
那意味着热容等于零。
What's the heat capacity at high temperature?
高温时的热容是什么?
Today we're going to talk about heat capacity.
今天我们将要讨论热容的概念。
Because I do want to look at the heat capacity.
因为我想来看看热容。
So that's the vibrational heat capacity of a solid.
那么那就是固体的振动热容。
The heat capacity of water is relatively high.
水的热容量相对来说较高。
Well, what you find out is the heat capacity is zero.
好,你们发现热容是零。
What was the low temperature limit of the heat capacity?
热容的低温极限是什么?
But I want to talk a little bit about the heat capacity.
但我想谈论一点儿热容。
Why did the heat capacity go to zero at low temperature?
为什么热容在低温时是零?
Now, this looks kind of complicated for the heat capacity.
现在,这个热容看起来有一点复杂。
So in that case, the high temperature limiting heat capacity is zero.
所以在这种情况下,高温极限的热容是零。
Then the influence factors of massic heat capacity are analyzed.
利用它测定出许多种煤炭的质量热容,并分析其影响因素。
Of course it's really the same result for the energy and the heat capacity.
当然对于能量,和热容的确是同样的结果。
OK. Given that, then I want to talk a little bit further about the heat capacity.
好,在这样的假定之下,然后我想谈论更多的一点,关于热容的问题。
It was expected to be used in the high power solid state heat capacity laser.
晶体外观完整,无宏观缺陷,有望作为激光工作物质用于强固体热容激光器中。
But, the heat capacity of water is too high for offshore platform to warm up.
但是,由于水的高比热容,在平台上无法实现大批量水加热处理。
Marine temperatures change gradually because of the high heat capacity of water.
由于海水的比热大,海水温度是逐渐缓慢地变化的。
You can learn a tremendous amount about that by making measurements of the heat capacity.
你们能了解关于这些的极多的内容,通过测量热容。
Thermal effect is a fundamental issue for a high power solid state heat capacity laser.
介绍了能够实现高平均功率的两种固体激光器:固体薄片激光器和固体热容激光器。
Before a test can be performed, the heat capacity of the calorimeter must be determined.
在进行测试之前,必须确定量热计的热容量。
This paper Outlines Carnot cycle efficiency of ideal gas whose heat capacity is a constant.
概述了热容量为常量的理想气体的卡诺循环效率。
Heat capacity, thermal mass flow resistance is small, stop the heat, long continued heating.
热容量大,热质流动阻力小,停热后持续。
It is important breakthrough in the theoretical research of heat capacity of condensed material.
是百年来凝聚态物质热容理论研究中的重大突破。
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