Two Galaxies in 'joust' before mega-merger
The galaxies, observed using two Chile-based telescopes, were seen as they existed about 11.4 billion years ago, approximately 2.4 billion years after the Big Bang event that initiated the universe.
At the heart of one of the galaxies resides a quasar, a highly luminous object powered by gas and other material falling into a supermassive black hole. The intense radiation across the electromagnetic spectrum unleashed by the quasar is seen disrupting clouds of gas and dust, known as molecular clouds, in the other galaxy.
It is molecular clouds that give rise to stars. But the effects of the quasar's radiation turned the clouds in the affected region into "only tiny dense cloudlets that are too small to form stars," said astrophysicist Sergei Balashev of the Ioffe Institute in Saint Petersburg, Russia, co-lead author of the study published on Wednesday in the journal Nature.
This is the first time such a phenomenon has been observed, Balashev said.
Stars form by the slow contraction under gravity of these clouds, with small centers taking shape that heat up and become new stars. But the galaxy affected by the quasar's radiation was left with fewer regions that could serve as such stellar nurseries, undermining its star formation rate.
The interaction between the two galaxies reminded the researchers of a medieval joust.
"Much like jousting knights charging toward one another, these galaxies are rapidly approaching. One of them — the quasar host — emits a powerful beam of radiation that pierces the companion galaxy, like a lance. This radiation 'wounds' its 'opponent' as it disrupts the gas," said astronomer and co-lead author Pasquier Noterdaeme of the Paris Institute of Astrophysics in France.
Supermassive black holes are found at the heart of many galaxies, including the Milky Way. The researchers estimated the mass of the one that serves as the engine of the quasar studied in this research at about 200 million times that of our sun.
The intense gravitational strength of the supermassive black hole pulls gas and other material toward it. As this stuff spirals inward at high speed, it heats up due to friction, forming a disk that emits extremely powerful radiation in two opposite directions, called biconical beams.
The ultraviolet light from one of these beams is what played havoc with the gas in the companion galaxy.
This supermassive black hole is much more massive than the one at the center of the Milky Way — called Sagittarius A*, or Sgr A* — which possesses roughly 4 million times the mass of the sun and is located about 26,000 light-years from Earth. A light-year is the distance light travels in a year, 9.5 trillion kilometers.
The researchers used the Atacama Large Millimeter/submillimeter Array, or ALMA, to characterize the two galaxies and used the European Southern Observatory's Very Large Telescope, or VLT, to probe the quasar as well as the gas in the companion galaxy.
The configuration of the galaxies as viewed from the perspective of Earth enabled the researchers to observe the radiation from the quasar passing directly through the companion galaxy.
Most galactic mergers that have been observed by astronomers occurred later in the history of the universe.
"Galaxies are typically found in groups, and gravitational interactions naturally lead to mergers over cosmic time," Noterdaeme said. "In line with current understanding, these two galaxies will eventually coalesce into a single larger galaxy. The quasar will fade as it exhausts the available fuel."
Hashtags
Try Our AI Features
Explore what Daily8 AI can do for you:
Comments
No comments yet...
Related Articles
Korea Herald
11 hours ago
- Korea Herald
LG AI Research taps machine learning experts as new heads
LG AI Research appointed Lee Hong-lak, vice president and chief scientist of AI, and Lim Woo-hyung, a senior researcher leading its Data Intelligence Lab, as the institute's new co-heads of research on Monday. The appointments follow the departure of former head Bae Kyung-hoon, who left the post after being appointed as Minister of Science and ICT in June. According to LG, Lee is a globally recognized scholar in machine learning and deep learning. Named among the world's top 10 AI researchers, he also serves as a professor of computer science and engineering at the University of Michigan. Lee will lead LG's Global AI Center in Ann Arbor, Michigan, focusing on next-generation AI technologies and global recruitment, LG said. "Lee is expected to help integrate cutting-edge AI advancements into LG's research efforts while identifying top-tier AI talent worldwide," LG said. Joining him as co-head is Lim, an expert in machine learning and speech recognition. Lim has led applied AI research using LG's hyperscale AI model, Exaone, contributing to real-world problem-solving across LG affiliates and industries, LG said. "Lim will oversee the overall operation of the institute in Korea and expand Exaone-based AI services across LG businesses," the company added.
Korea Herald
12 hours ago
- Korea Herald
CorestemChemon Expands Global CRO Reach with ATG Lifetech, Targeting Next-Gen Preclinical Services
Strategic partnership to deliver transcriptomics-powered, organoid-based preclinical testing for high-impact drug discovery SEOUL, South Korea, July 21, 2025 /PRNewswire/ -- CorestemChemon, a leading GLP-certified preclinical CRO based in South Korea, has entered into a strategic partnership with ATG Lifetech, a biotechnology company specializing in transcriptome analytics and organoid-based modeling. This collaboration aims to deliver next-generation, precision-driven non-clinical solutions to pharmaceutical companies and biotech ventures across the U.S., Europe, and Asia. Through this partnership, the two companies will co-develop: "ATG Lifetech's disruptive transcriptome and organoid platforms will significantly elevate the scientific fidelity of our preclinical services," said a CorestemChemon spokesperson. "This alliance positions us to compete as a global CRO partner offering best-in-class biological relevance and regulatory readiness." Organoid-based assays are increasingly recognized for their translational advantage, offering up to 5x greater predictive accuracy in toxicity and efficacy screening compared to conventional 2D cell cultures, according to industry benchmarks. When integrated with whole-transcriptome analysis, these platforms enable earlier go/no-go decisions in drug pipelines, helping clients de-risk clinical entry and reduce overall development timelines. "Investors should note that this partnership directly supports CorestemChemon's strategic growth plan to expand high-margin, IP-driven CRO services globally. Revenue-generating service offerings are expected to begin rolling out by late 2025, with significant global demand already projected." ATG Lifetech brings validated expertise from its international collaborations, including with ACROBiosystems (Switzerland), and has been selected as a core developer in several South Korean government-backed biopharma initiatives. The two companies plan to showcase their joint research outputs at a major toxicology and preclinical science conference in Q4 2025. Global service launches will follow, focused on biotech and pharmaceutical customers in need of high-content, biologically faithful preclinical testing. CorestemChemon (KOSDAQ: 166480) is a full-service preclinical CRO with over two decades of experience in GLP-based toxicology, pharmacokinetics, and regulatory compliance. The company operates multiple AAALAC-certified facilities and partners with leading biopharmaceutical innovators across Asia, the U.S., and Europe.
![[Lee Byung-jong] Time for Korea's brain gain](/_next/image?url=https%3A%2F%2Fwimg.heraldcorp.com%2Fnews%2Fcms%2F2025%2F07%2F17%2Fnews-p.v1.20250717.a8050bbc61a64e1d9d7de93ad98b4acc_T1.jpg&w=3840&q=100)
Korea Herald
4 days ago
- Korea Herald
[Lee Byung-jong] Time for Korea's brain gain
There was a time when South Korean scientists and engineers left their country in droves, seeking better research environments and more rewarding careers abroad —especially in the United States. For decades, this outflow of talent, often referred to as brain drain, was seen as a symptom of Korea's limited scientific infrastructure and rigid institutional culture. But today, the situation is changing. South Korea has emerged as a serious player in research and development, and its universities and companies are becoming increasingly competitive. Now, many of those once-lost talents are coming home — and more could follow. This trend could accelerate in light of policy shifts in the United States. The Trump administration has cut research funding and accused academic institutions of being "liberal strongholds,' pushing many scholars to consider opportunities abroad. As a result, countries around the world have begun courting scientists and academics disillusioned with the American system, offering them better support, autonomy and respect for their work. Canada, for example, has positioned itself as a haven for displaced US-based academics, offering generous funding and robust institutional support. The University of Toronto has successfully recruited several leading researchers from American universities in recent years. Similar efforts are underway in Europe. Aix-Marseille University in France recently offered 15 positions specifically aimed at US-based scholars. Across the continent, institutions in the UK, Germany and elsewhere are actively attracting American talent, especially as diplomatic and trade tensions with the US continue to rise. China is another key player in this new global race for talent. Armed with extensive government funding, a vast research infrastructure, and a clear national strategy, China has been aggressively courting global experts. Many China-born scientists and engineers, educated and employed in the US, are returning home, driven partly by growing anti-China sentiment in the US. However, China's ambitions face a critical limitation: a lack of academic freedom. For many international scholars, concerns about censorship and political interference make China a less appealing destination. Hong Kong once offered an alternative, but increasing control from Beijing has narrowed that window as well. In this global context, South Korea stands out as a country with both the motivation and the means to benefit from the US brain drain. Although it is still an emerging power in basic sciences, Korea has made impressive strides. Its universities may not yet be counted among the global elite, but their quality has improved dramatically. World-class research institutions like KAIST, Postech and the Institute for Basic Science are helping close the gap. Historically, most researchers returning to Korea have been Korean nationals who studied or worked abroad. Foreign scholars remain a rarity in Korean academia, largely due to systemic challenges: relatively low compensation, a rigid academic culture, hierarchical management in companies and significant language barriers. Many universities and research institutions still prioritize Korean-language communication and maintain promotion systems that can be opaque or overly rigid, discouraging interdisciplinary and creative work. Despite these challenges, Korea has the potential to become a global R&D hub. It invests over 4 percent of its gross domestic product in R&D — among the highest rates in the world — and the government has long recognized science and technology as essential to national development. Major conglomerates such as Samsung, SK, Hyundai, LG and Posco pour enormous sums into their research centers and also support affiliated institutions like Postech. The government-run Institute for Basic Science, launched in 2011, collaborates with these players in key fields including biotechnology, AI, semiconductors, physics, robotics and battery research. These investments are already producing results. The IBS has recruited world-class talent such as Kim Ki-moon, an expert in supramolecular chemistry, and Noh Do-young, a leader in advanced X-ray science — both of whom returned from prestigious US laboratories. At KAIST, Cho Kwang-hyun, a systems biology expert trained in the US, is leading cutting-edge research. Foreign talent, while still rare, is also starting to arrive. One standout is Rodney S. Ruoff, an American chemist renowned for his work in carbon materials, who joined IBS to lead nanomaterials research. He praised IBS for offering 'unprecedented freedom' compared to US institutions. Institutions across Korea are making efforts to attract more of this kind of talent. The Daegu Gyeongbuk Institute of Science and Technology, for example, is actively recruiting global doctoral-level researchers in AI as part of a joint initiative with the Ministry of Science and ICT. Its postdoctoral fellowship program offers highly attractive compensation — up to 90 million won ($ 64,700) annually — along with research funding and opportunities for industry collaboration. These moves are designed not only to build domestic expertise but also to internationalize Korea's research environment. Ultimately, all these efforts toward brain gain aim to strengthen Korea's global standing in R&D, which still lags behind its industrial and manufacturing dominance. While Samsung and other Korean brands are global market leaders, their long-term success depends on innovation rooted in foundational science and technology. However, one major domestic challenge remains: attracting young Korean talent to scientific fields. An increasing number of top students are opting for medical school over careers in engineering or science, seeking greater job stability and social prestige. For a country still waiting for its first Nobel Prize in science (it has only won in peace and literature), this trend is troubling. Yet, the momentum behind Korea's brain gain strategy may help reverse this. By showcasing world-class research, international partnerships, and success stories of returnees and foreign scholars, Korea can inspire the next generation of homegrown scientists — and attract the best minds from around the world.
