Welcome one and all! It’s time to grab your seat for the biggest battle in the soon-to-be-formed universe. That’s right— the Big Bang is about to go down! In one corner is the force that brings all matter together. It acts on any particle with mass, and its range is infinite— give it up for gravity! In the other corner, our contender can push matter away with spectacular strength. When the going gets tough, this fighter just gets tougher. That’s right, it’s pressure!
欢迎大家! 找好座位,准备迎接 即将形成的宇宙中 最激烈的战斗。 没错,宇宙大爆炸即将发生! 在一角是将所有物质 聚集一起的力量。 它作用于任何具有质量的粒子, 不受距离限制—— 让我们为重力鼓掌! 在另一角,我们的参与者 能以惊人的力量推开物质。 它面对负面情况更为坚韧。 没错,它就是压力!
Over the next several hundred thousand years, these two contenders will be wrestling for the fate of the universe. That’s right folks, the ripple effects of this historic match will shape the structure of the universe as we know it today. But what are these powers fighting over? We’ll find out when the Big Bang hits right... now!
在接下来的几十万年里, 这两位对手将为宇宙的命运而搏斗。 没错,各位,这场 历史性决斗的连锁反应 将决定我们今天所熟知的宇宙结构。 但这些力量正在比什么? 当大爆炸发生时,我们就会知道!
Let’s zoom in for the play-by-play.
让我们接近观察比赛的每一环节。
This epic event has brought three components into our infant universe. Dark matter, which only interacts with gravity. Baryonic matter, which makes up all matter you’ve ever seen, is affected by both gravity and pressure. And radiation composed of innumerable particles of light, also known as photons.
这场史诗般的事件将三个组成部分 带入我们的初代宇宙。 暗物质,只与重力相互作用。 重子物质,构成着 你所见过的一切物质, 同时受到重力和压力的影响。 以及由无数光的粒子形成的辐射, 也被称为光子。
In the moments just after the Big Bang, all three components are in equilibrium, meaning no one location is denser than another. But as the universe starts expanding, differences in density start to emerge. Gravity immediately gets to work pulling matter together. Dark matter begins to collect at the center of these increasingly dense regions, forming the foundations of future galaxies.
在大爆炸后的瞬间, 这三个组成部分处于平衡状态, 意味着没有一个地方是更为密集的。 但随着宇宙开始膨胀, 密度差异开始体现。 重力立即开始拉拢物质。 黑暗物质开始聚集在 愈加密集区域的中心, 构筑未来星系的基础。
Meanwhile, pressure begins gathering its strength. In this hot, high-energy environment, protons and electrons can’t come together to form atoms, so these loose particles zip around, freely interacting with ambient photons. The result is almost a fluid of baryonic matter and radiation. But the closer these baryonic particles get, the hotter the fluid becomes, pushing photons to ping around with incredible force. This is the power of pressure, specifically radiation pressure, battling to push things apart.
与此同时,压力也在积聚力量。 在这个高温、高能量的环境中, 质子和电子无法结合形成原子, 因此这些自由粒子在周围的 光子影响下自由运动, 产生一种带辐射的重子物质流体。 但当这些重子粒子彼此靠近时, 流体变得更热, 使光子以难以置信的力量四处弹射。 这就是压力的力量, 具体来说是辐射压力, 将物质分离开来。
With each of gravity’s vicious tugs squeezing photons and matter together, pressure exerts a forceful shove back. And as the two giants struggle, they heave this fluid back and forth— creating massive waves called baryonic acoustic oscillations. Moving at almost two thirds the speed of light these BAOs ripple across space, impacting the universe on the biggest scale imaginable. These rolling waves determine the distribution of matter throughout space, meaning that today— almost 14 billion years after this fight began— we're more likely to find galaxies at their peaks and empty space in their troughs. And that’s not all. We can still see these ripples in the background radiation of the universe, a permanent reminder of this epic brawl.
随着重力每一次强力地 把光子和物质挤压在一起, 压力产生强大的反作用力。 当这两个巨人搏斗时, 它们揉捏着这流体—— 产生名为重子声学振荡的巨大波纹。 以近三分之二的光速移动, 这些重子声学振荡在太空中传递, 对宇宙产生着最为巨大的影响。 这些波纹决定了 物质在空间中的分布; 这意味着今天——这场搏斗 开始将近 140 亿年后—— 我们更有可能在它们的高峰处找到星系, 而它们的波谷中是空旷的。 这还不是全部。 我们仍然可以在宇宙的 背景辐射中看到这些涟漪, 它们是这场史诗般的斗争的永久痕迹。
But after being locked in a stalemate for roughly 370,000 years, the tide of our battle finally begins to turn. After all this time, the heat from the Big Bang has dissipated significantly, cooling the universe down to a temperature at which loose electrons start to pair up with protons. Known as the “era of recombination,” this stops electrons from recklessly pinging around. This allows light to stream freely for the first time, illuminating the universe. These photons now only exert a tiny force on the neutral atoms they interact with, gradually reducing the power of pressure.
但在相持了大约 37 万年后, 我们战斗的局势终于开始转变。 经过这么长时间, 大爆炸产生的热量已经显著消散, 将宇宙冷却到了 电子开始与质子配对的温度。 这被称为“复合时代“, 这使得电子不再胡乱碰撞。 这使得光线第一次自由地流动, 照亮了宇宙。 这些光子现在只对和它们作用的 中性原子产生微弱的力, 逐渐减小了压力的重要性。
And with that, it’s time to crown our champion! The undefeated force, the most pervasive power in the universe: it’s gravity! And yet, this rivalry isn’t over. A similar battle continues between these two sworn enemies today, within every single star. As gravity pulls a star’s gas inward, pressure increases and pushes the matter back outward. This push and pull keeps the Sun, and all other stars, stable for billions of years. In fact, this clash of the titans is the same reason Earth’s atmosphere doesn’t collapse to the ground. So while their greatest fight might have ended, these two warriors are still to be locked in combat— even as a new challenger approaches.
既然这样,是时候 宣布我们的冠军了! 不败的力量,宇宙中最普遍的力: 重力! 然而,这场竞争还没有结束。 类似的战斗仍在今天 在每颗恒星内部持续进行。 当重力将恒星的气体向内拉时, 压力增加并将物质推向外部。 这种推拉使太阳和所有其他恒星 在数十亿年的时间里保持稳定。 事实上,这两位巨人的冲突也是 地球大气层不会降至地面的原因。 因此,尽管他们 最伟大的战斗已经结束, 这两位战士仍将继续格斗—— 即便一位新的挑战者出现。