Bush, the Texas oilman, is expected to talk about energy conversation in his State of the Union speech this week.
预计德州石油大亨布什将在本周的国情咨文演讲中谈到能源问题。
If you have no specialized skills, there's little reason to uproot to another state and be the last in line for a low-paying job at a new auto plant or a green-energy startup.
如果你没有专业技能,你就没有什么理由背井离乡去到另一个州,在一家新的汽车厂或者新的绿色能源公司中干低级的活,拿微薄的薪水。
This energy here is very simply the energy of the initial state minus the energy of the final state.
很简单的,这个能量等于初始能量减去末能量。
The steady-state creep strain rate is a power function of deviatoric stress and exponential function of temperature and energy.
稳定蠕变应变率本构方程是作用在盐岩上的应力偏量的幂次函数和能量与温度的指数函数。
It refers to a system state where the energy, the state of every one of those atoms or molecules is specified.
这个能量涉及一个系统的状态,这个状态下的每个原子,和分子的状态都是确定的。
We could worry about its vibrational or rotational energy, or electronic state.
我们也需要知道,他的振动和转动能量,或者电子状态。
And what's the probability that some molecule, one of the oxygen molecules somewhere in this room, is in a certain energy state. Right?
某些分子或者某个氧原子,位于屋子的某处,处于某个能量状态的,概率是多少?
Chemical energy, which is everything from wood to crude oil to gasoline to coal, consists of playing with the electrons, changing their energy state.
从木头、原油、汽油到煤炭,它们中释放出来的化学能量是通过改变其中电子的能量状态实现的。
This is sort of a leakage from a potential future time span to space expansion towards a lower energy state, as the storage of events in time needs additional energy, just like battery charging.
这种潜在未来时间的泄漏跨越到空间膨胀到低能量状态,正如事件在时间方面的累积需要额外的能量一样,比如电池充电。
Private oligopolies and state energy monopolies still survive in Mexico, for example.
比如,在墨西哥仍存在私有寡头和国有能源垄断。
And the truth is that yes, this costs energy, we're going up to a higher energy state.
事实上,它需要消耗能量,我们到了一个更高的能量状态。
So it's going to be favorable for the electrons instead to go to that lower energy state and be within the molecular orbital.
所以对于电子来说,更倾向于能量更低的轨道,呆在分子轨道里。
So the next highest energy state would be like this.
所以下一个较高的能态将会像这样。
We start at this lower energy state and go up that means we need to absorb a photon, we have to take in energy.
我们从一个低能级开始,到一个高能级去,这意味着需要吸收一个光子,我们要获得能量。
In the conduction band, it will occupy the lowest-energy state it can find (right-hand well).
在传导带,它会占据所能找到的最低能级(比如说右边这个)。
In this case, that means the excitons in the outer layer flow to the inner layer, where they can exist in a lower (but still excited) energy state.
因此,这就意味着激子从纳米管外层流向内层,并以较低(但仍为激发态)的能态存在于纳米管中。
When the injected electrons find the lower-energy state occupied, they spill over into the other state; realigned with their holes, they release their extra energy as photons.
当注入的电子找到已经被占据的更低能级,他们就会溢出,进入其他状态:和它们的凹陷重新组合,并且以光子的形式释放多余能量。
MIT researchers fill up the lower-energy state with extra electrons from phosphorous atoms, which they add to the germanium.
MIT的研究者们将较低这个能级用磷原子所带电子来填充,他们加入到锗中的即是这种东西。
That is the ground state energy of atomic hydrogen.
同时也是氢原子基态的能量值。
This state corresponds to a lowest energy state in the first quantum well.
此状态对应第一个量子阱的最低能态。
The extra electron fills up the lower-energy state in the conduction band, causing excited electrons to, effectively, spill over into the higher-energy, photon-emitting state.
这个额外的电子填充了传导带的较低能级,有效的导致了被激发的电子溢入较高,释放光子的能级。
Only by promoting energy state can we thoroughly change our life!
彻底改变人生,唯有提升能量状态!
This is for you to translate into what matter state, energy state or what level of strength you want to do.
至于如何转换到特定的物质状态,能量状态或者什么样的强度水平就是你们自己的事了。
Most of it's in the cool, boring depths of space, sitting around in its lowest energy state.
绝大部分都只是游荡于寒冷寂寞的深空中,在最低能级状态下终日无所事事。
Because he came from energy state to the matter state.
因为他是从能量状态到物质状态。
In addition, the flight path optimization algorithm based on energy state approximation is summarized.
而且,总结了基于能量状态近似法的飞行轨迹优化算法。
Only by promoting energy state can we thoroughly change our life!
完全扭转人生,惟有晋升能量状况!
In this material, the particles are all in their lowest possible energy state and behave as a single entity.
这种物质中的粒子都会处于其可能的最低能量状态并以单一实体形式行动。
Three functional agility metrics such as combat cycle time, dynamic speed turn plots and relative energy state are analyzed.
分析采用优化操纵策略对功能敏捷性的三种评估尺度(战斗周期时间、动态速率转弯图和相对能量状态)的影响。
Three functional agility metrics such as combat cycle time, dynamic speed turn plots and relative energy state are analyzed.
分析采用优化操纵策略对功能敏捷性的三种评估尺度(战斗周期时间、动态速率转弯图和相对能量状态)的影响。
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