Both quantum mechanics and chaos theory suggest a world constantly in flux.
量子力学和混沌理论都指出世界处在不断变化中。
It does happen in quantum mechanics.
它确实发生在量子力学中。
We really have to ask ourselves, why is quantum mechanics limited?
我们真的得问问自己,为什么量子力学是有限的?
In this example, we exploited the quantum mechanics principle of superposition.
在本例中,我们利用了量子力学的叠加原理。
Why are we using this model if it clearly doesn't take into account quantum mechanics?
如果这个模型显然没有考虑到量子力学,我们为什么要用它呢?
The predictions of quantum mechanics, however, give only the probability of an event, not a deterministic statement of whether or not the event will occur.
然而,量子力学的预测只给出事件发生的概率,而不是事件是否会发生的确定性陈述。
Quantum mechanics is a highly successful theory: it supplies methods for accurately calculating the results of diverse experiments, especially with minute particles.
量子力学是一种非常成功的理论:它提供了精确计算各种实验结果的方法,特别适用于微小粒子方面。
Because of this probabilism, Einstein remained strongly dissatisfied with the theory throughout his life, though he did not maintain that quantum mechanics is wrong.
由于这种概率性,爱因斯坦一生都强烈不满这个理论,尽管他并不认为量子力学是错误的。
Einstein's ideas have been tested by experiments performed since his death, and as most of these experiments support traditional quantum mechanics, Einstein's approach is almost certainly erroneous.
爱因斯坦的想法在他死后的实验中得到了验证,由于这些实验大多支持传统的量子力学,爱因斯坦的方法几乎必然是错误的。
But it does happen in quantum mechanics.
但它在量子力学中就发生了。
What could be weirder than quantum mechanics?
还有什么比量子力学更神奇?
I don't think we're talking about quantum mechanics here.
我不认为我们这里是在讨论量子力学的问题。
How Quantum Mechanics And General Relativity Play a part?
量子力学和广义相对论的影响。
Can you imagine living in a world before quantum mechanics?
你能设想下生活于量子力学出现前的世界的情形?
But, according to quantum mechanics, things can happen occasionally.
但是,根据量子力学(quantum mechanics),事件能够偶然地发生。
We really have to ask ourselves, why is quantum mechanics this limited?
我们真的得问问自己,为什么量子力学是有界的?
But at very low temperatures, the odd rules of quantum mechanics reign.
可是在极低的温度下,古怪的量子力学占了物理学的统治地位。
So, to take one example, how does quantum mechanics make the laser possible?
那么,举个例子,量子力学如何使激光成为可能的?
We remember that Lewis structures are an idea that are pre-quantum mechanics.
我们记得路易斯结构是一个,早于量子力学的概念。
In this example we exploited the quantum mechanics principle of superposition.
本例中,我们利用了量子力学的叠加原理。
Physicists have struggled to marry quantum mechanics with gravity for decades.
物理学家努力了几十年将万有引力结合到量子力学。
So, molecular orbital theory, on the other hand, is based on quantum mechanics.
另一方面分子轨道理论,是基于量子力学的。
Those were the early days in which the basis for quantum mechanics was established.
以上就是量子力学基础建立起来的早期岁月。
Quantum mechanics is fantastic for the other end of the spectrum - for small things.
量子力学在解释另一个极端——微小物体的时候发挥着了不起的作用。
Quantum mechanics has bequeathed a very weird picture of the universe to modern physicists.
量子力学传递给当代物理学家一幅非常奇异的宇宙图像。
Is that in your view the biggest fundamental leap that quantum mechanics allowed us to make?
你认为这是量子力学给我们的现实生活带来的最大飞跃么?
He rewrote the equations of general relativity to make them compatible with quantum mechanics.
他重写了广义相对论的方程,使它们能与量子力学兼容。
Thus were laid the foundations of the so-called Copenhagen interpretation of quantum mechanics.
就此为量子力学所称的“哥本哈根诠释”打下了基础。
Quantum mechanics tells us that small particles, such as electrons, can be in two places at once.
量子力学告诉我们,小粒子,比如电子,可以同时处于两个位置。
Quantum mechanics tells us that small particles, such as electrons, can be in two places at once.
量子力学告诉我们,小粒子,比如电子,可以同时处于两个位置。
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