1·Because, when you ask yourself that question, you should consider what is the thermal energy versus the bonding energy?
这是因为,对于这个问题,我们应当考虑到,什么样的热能,对应于键能?
2·The bonding energy and micro-defects are the major factors that affect the film refractive index and film quality.
影响非晶硅折射率及成膜质量的主要因素是原子键能以及微型缺陷;
3·The time constants of the slower decays are found to increase with the hydrogen-bonding energy in alcoholic solvents.
实验结果表明慢速弛豫过程的时间常数随醇溶剂分子间氢键键能的增强而增大。
4·If the bonding energy is very strongly negative, thermal energy isn't great enough to disrupt those bonds and allow those bonds to be broken and then have fluidity.
如果键能非常强,热能并不足以,打破这些化学键,破坏这些化学键,并使它们液化。
5·And the other thing to point out is that the energy that an anti-bonding orbital is raised by, is the same amount as a bonding orbital is lowered by.
另外一个要指出的事情是,反键轨道引起的能量升高,和成键轨道引起的能量降低是相同的。
6·Anti-bonding is even higher in energy than non-bonding.
反键能量比非成键更高。
7·Attachment of a proton to the more polarizable gases therefore gives significant energy toward bonding.
因此,把质子结合到更可极化的气体上,会释放很多能量,利于成键。 当然,这要求有小的、电负性的共配物。
8·We're going to release a lot of energy for bonding, it's going to more than make up for the fact that we actually had to spend some energy to promote that electron.
在成键时,会释放大量能量,这比补偿激发电子,的能量要多。
9·So we would label our anti-bonding orbital higher in energy than our 1 s atomic orbitals.
我们应该把反键轨道标在,高于1s原子轨道能量的地方。
10·And what you find is when you have a bonding orbital, the energy decreases compared to the atomic orbitals.
你们发现当你有个成键轨道的时候,相比原子轨道能量要降低。