11월 16, 2024

Wpick

지상에서 한국의 최신 개발 상황을 파악하세요

특수 상대성 이론의 실제 적용

특수 상대성 이론의 실제 적용

상대성 이론은 일반적으로 알버트 아인슈타인이 1905년에 출판한 특수 상대성 이론과 1915년에 출판된 일반 상대성 이론의 두 가지 상호 관련된 이론을 포함합니다. 특수 상대성 이론은 중력이 없는 모든 물리적 현상에 적용됩니다. 일반 상대성 이론은 만유인력의 법칙과 자연의 다른 힘들과의 관계를 설명합니다.

상대성 이론은 고전 물리학이 일부 관찰을 설명할 수 없기 때문에 20세기 초 알버트 아인슈타인에 의해 개발되었습니다. 그것은 특수 상대성 이론과 일반 상대성 이론의 두 가지 구성 요소를 가지고 있습니다.

특수상대성이론은 빛의 속도가 일정하다는 기본 개념에 기반을 두고 있으며 물리적 사건은 모든 관찰자에게 동일하게 나타나야 하며 상당한 중력 없이 모든 물리적 현상에 적용되어야 합니다. 일반 상대성 이론은 시간과 공간이 시공간의 두 측면이며 우리가 중력이라고 생각하는 것은 시공간의 뒤틀림이라는 생각입니다.

우주를 연구하는 과학자들은 “중용의 원칙”으로 알려진 가장 좋아하는 철학을 가지고 있습니다.[{” attribute=””>Milky Way galaxy compared to the rest of the universe.

Now, new research from the University of Colorado at Boulder (CU Boulder) adds yet another piece of evidence to the case for mediocrity: Galaxies are, on average, at rest with respect to the early universe. Jeremy Darling, a CU Boulder astrophysics professor, published this new cosmological finding on May 26, 2022, in the journal Astrophysical Journal Letters.

Thousands of Galaxies Hubble Space Telescope

This image made from a composite of September 2003 – January 2004 photos captured by the NASA/ESA Hubble Space Telescope shows nearly 10,000 galaxies in the deepest visible-light image of the cosmos, cutting across billions of light-years. Credit: Image courtesy of NASA, ESA, S. Beckwith (STScI), HUDF Team

“What this research is telling us is that we have a funny motion, but that funny motion is consistent with everything we know about the universe—there’s nothing special going on here,” said Darling. “We’re not special as a galaxy or as observers.”

Roughly 35 years ago, researchers discovered the cosmic microwave background, which is electromagnetic radiation left over from the universe’s formation during the Big Bang. The cosmic microwave background appears warmer in the direction of our motion and cooler away from the direction of our motion.

From this glow of the early universe, scientists can infer that the Sun—and the Earth orbiting around it—is moving in a certain direction, at a certain speed. Researchers find that our inferred velocity is a fraction of a percent of the speed of light—small, but not zero.

Jeremy Darling

Astrophysics professor Jeremy Darling studies galaxy evolution, massive black holes, star formation, and cosmology. Credit: University of Colorado at Boulder

Scientists can independently test this inference by counting the galaxies that are visible from Earth or adding up their brightness. They can do this thanks largely to Albert Einstein’s 1905 theory of special relativity, which explains how speed affects time and space. In this application, a person on Earth looking out into the universe in one direction—the same direction that the Sun and the Earth are moving—should see galaxies that are brighter, bluer, and more concentrated. Similarly, by looking in the other direction, the person should see galaxies that are darker, redder, and spaced farther apart.

But when investigators have tried to count galaxies in recent years—a process that’s difficult to do accurately—they’ve come up with numbers that suggest the Sun is moving much faster than previously thought, which is at odds with standard cosmology.

“It’s hard to count galaxies over the whole sky—you’re usually stuck with a hemisphere or less,” said Darling. “And, on top of that, our own galaxy gets in the way. It has dust that will cause you to find fewer galaxies and will make them look dimmer as you get closer to our galaxy.”

Darling was intrigued and perplexed by this cosmological puzzle, so he decided to investigate for himself. He also knew there were two recently released surveys that could help improve the accuracy of a galaxy count—and shed light on the velocity mystery: one called the Very Large Array Sky Survey (VLASS) in New Mexico, and the other called the Rapid Australian Square Kilometer Array Pathfinder Continuum Survey (RACS) in Australia.

“I love the idea that this basic principle that Einstein told us about a long time ago is something you can see. It’s a really esoteric thing that seems super weird, but if you go out and count galaxies, you could see this neat effect. It’s not quite as esoteric or weird as you might think.” — Jeremy Darling

Together, these surveys allowed Darling to study the entire sky by patching together views from the northern and southern hemispheres. Importantly, the new surveys also used radio waves, which made it easier to “see” through the dust of the Milky Way, thus improving the view of the universe.

When Darling analyzed the surveys, he found that the number of galaxies and their brightness was in perfect agreement with the velocity researchers had previously inferred from the cosmic microwave background.

“We find a bright direction and a dim direction—we find a direction where there are more galaxies and a direction where there are fewer galaxies,” he said. “The big difference is that it lines up with the early universe from the cosmic microwave background and it has the right speed. Our cosmology is just fine.”

Because Darling’s findings differ from past results, his paper will likely prompt various follow-up studies to confirm or dispute his results.

But in addition to pushing the field of cosmology forward, the findings are a good real-world example of Einstein’s special relativity theory—and they demonstrate how researchers are still putting the theory into practice, more than 100 years after the famed physicist first proposed it.

“I love the idea that this basic principle that Einstein told us about a long time ago is something you can see,” Darling said. “It’s a really esoteric thing that seems super weird, but if you go out and count galaxies, you could see this neat effect. It’s not quite as esoteric or weird as you might think.”

Reference: “The Universe is Brighter in the Direction of Our Motion: Galaxy Counts and Fluxes are Consistent with the CMB Dipole” by Jeremy Darling, 26 May 2022, Astrophysical Journal Letters.
DOI: 10.3847/2041-8213/ac6f08