And what we find out is the wavelength of a Matsuzaka fastball is 1.1 times 10 to the -31 meters.
我们算出松阪快球的波长,是1,1乘以10的负31次方米。
It's a very, sort of a crunch and then downtime.
有时候紧张,有时候松一些。。
So,composition alone can't give you the answer to the question why is the plywood superior to the solid pine board?
只用组成成分无法解答,这个问题,为什么胶合板要优于松木板呢?
But in terms of us going to the grocery store and thinking about things, probably we're all breathing sighs of relief.
但是如果我们走进商店,以后想到这些的话,我们都应该松一口气。
But those who are easier graders than average will never feel guilty and toughen up.
而那些评分本来就比平均标准松的,根本不会觉得内疚,不会因此更严格。
And of course then there's the extreme bagel that you see here.
当然,还有更极端的松饼,你们看
The ribbon comes off.
丝带会松落的。
And the fancy word for that is Poisson.
有一个名词叫做泊松。
For example, if we're talking about a pitcher, like Matsuzaka, we might want to know the speed of his average fastball.
举例来说,如果我们谈到一个投手,就像松阪,我们想知道他投出,快球的平均速度。
They are a function of the instant atomic arrangement, how we arrange the atoms: same composition, simple example, one inch thick pine board, one inch thick plywood.
那是即时的原子排序,的功能,我们如何排序原子,同样的成分,简单的例子,一英寸厚的松木板,一英寸厚的胶合板。
So, if we're trying to figure out the wavelength of a Matsuzaka fastball, we need to consider the velocity first, which is 42 miles per hour.
如果我们尝试计算一个,松阪发出快球的波长,我们首先需要考虑速度,每小时为42英里。
So, that's for Matsuzaka, and even if you don't memorize all the wavelengths for all the pitchers.
所以,那是对于松阪的情况,即使你没有记住,所有的投手投出球的波长。
And the example we'll pick is considering, for example, a Matsuzaka fastball.
我们举例来考虑的是,一个松阪的快球。
A muffin serving size is the size of a light bulb.
一份松饼是灯泡这么大
So, first we have Matsuzaka at 94 miles per hour.
所以,首先我们知道松阪的,投球速度是94公里每小时。
Well it's very hard to find muffins that size.
找到这样大小的松饼简直不可能
So we can think about what is our most loosely-bound electron, what's that highest energy orbital, and it's going to be the 2 p orbital, that's going to be what's highest in energy.
我们来想一想,它“束缚得最松“的电子是哪一个,能量最高的轨道是哪一个?,它就是,2,p,轨道,是能量最高的轨道。
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