Wednesday, April 1, 2026

What's Up: April 2026 Skywatching Tips from NASA - NASA Jet Propulsion Laboratory

 

Mercury shines extra bright, the Lyrid meteor shower peaks, and a comet soars into view

Mercury shines at its brightest for the year, the Lyrid meteor shower peaks, and a bright new comet makes an appearance in April’s night sky.

Skywatching Highlights

  • April 3: Mercury at greatest elongation
  • April 17: Best chance to see Comet C/2025 R3
  • April 21 to 22: Lyrid meteor shower peak
  • April 27: Comet C/2025 R3 makes closest approach to Earth

Transcript

Mercury shines extra bright, the Lyrid meteor shower peaks, and a comet soars into view. That's What's Up this April. 

On April 3rd, Mercury will be at its most visible all year. On this date, the planet will be at its greatest elongation, or its furthest distance from the Sun, as we see it from Earth, making it easier to see the often hard-to spot-planet. 

To find Mercury, look east before the Sun begins to rise. The planet will be very low on the horizon, just above Mars. 

The Lyrid meteor shower peaks April 21st to 22nd. This meteor shower comes from debris left behind by Comet Thatcher. 

When this debris hits and then burns up in our atmosphere, we see the "shooting stars" of a meteor shower. 

To experience the peak of the April Lyrids, look to the east starting at around 10 p.m. on April 21st and through the night into April 22nd. The meteor shower takes place nearby the star Vega, the fifth brightest star in the night sky, which can be found in the constellation Lyra, the Harp. 

April 17th might be your best chance to see the Comet C/2025 R3, which some think could be the brightest comet of the year. This comet will make its closest approach to Earth on April 27th, coming within 44 million miles of our planet. 

Experts estimate that the comet will likely reach magnitude eight, which means you would need access to a telescope or binoculars to see it. The comet will be visible in the eastern sky in the constellations Pegasus and above Pisces. You'll be able to spot the comet in the predawn hours from mid-April through the end of April in the Northern Hemisphere, and in the evenings in early May for viewers in the Southern Hemisphere. 

Here are the phases of the Moon for April. You can stay up to date on all of NASA's missions exploring the solar system and beyond, at science.nasa.gov. I'm Chelsea Gohd from NASA's Jet Propulsion Laboratory and that's What's Up for this month.

Source: What's Up: April 2026 Skywatching Tips from NASA - NASA Science

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Alkaline steel and cement wastewater could capture 30 million tons of CO₂ annually

Abstract. Credit: Environmental Science & Technology Letters (2026). DOI: 10.1021/acs.estlett.6c00081

Alkaline industrial wastewaters from steel or cement production are ideally suited to bind and sequester carbon dioxide (CO) chemically, safely, and for the long term. This is the result of a study conducted by the Helmholtz-Zentrum Hereon. Until now, this wastewater has been disposed of into rivers without using its CO2-sequestration capacity. In the future, it could neutralize millions of tons of CO—offering an attractive and implementable option to mitigate climate change. The study was recently published in the journal Environment, Science & Technology Letters.

Despite the Paris Climate Agreement and all energy-saving measures, global CO emissions continue to rise. Current climate protection efforts, such as expanding solar and wind energy, have so far not been sufficient to stop or even reverse this trend. For several years, climate experts have therefore been urging the removal of CO from the atmosphere and its long-term sequestration.

A key focus is on a method that mimics a natural process that has controlled atmospheric CO levels for billions of years: rock weathering, which chemically binds CO2 into so-called carbonates—commonly known, for example, as baking soda. The carbonates enter the environment through the weathering of limestone-rich rocks. Rain washes them into rivers and the ocean, where they react with CO. In this way, the greenhouse gas CO2 remains chemically bound for long periods and is removed from the atmosphere. Hereon researchers have now succeeded in developing an industrial-scale process based on this principle that could bind and sequester many millions of tons of carbon dioxide per year.

Reaction of carbonic acid

"Our process is essentially based on a reaction that many people will remember from chemistry class—the neutralization of a base by an acid," explains Prof Helmuth Thomas, head of the Hereon Institute for Carbon Cycles.

A textbook example is the reaction of sodium hydroxide with hydrochloric acid, producing table salt. CO behaves in a similar way. CO from the air reacts with water to form carbonic acid. When this carbonic acid reacts with a base—an alkaline liquid—bicarbonate is formed, which binds the CO in water for the long term. The idea behind the project is not to use carbonates derived from rock for the reaction with carbonic acid, but rather alkaline industrial wastewater.

"These alkaline wastewaters are produced in large quantities—for example in cement or steel production," says Thomas. Until now, they have been mixed with sulfuric or hydrochloric acid to neutralize the base before being released into rivers. In other words: the wastewater's potential to bind CO has remained completely untapped and appears wasted.

But what if, instead of sulfuric acid, the alkaline wastewater were neutralized with CO—or carbonic acid—in the future? This method would allow vast quantities of the greenhouse gas to be chemically bound as bicarbonate at an industrial scale. The open question was how much carbon dioxide could actually be bound using this process. Answering it required Thomas's chemical expertise, who calculated the precise CO turnover for such systems.

The result was clear: neutralizing CO in this way is worthwhile—especially because the energy consumption of the facilities is low. Environmental and regulatory constraints, in particular with respect to the pH conditions, are met via automatic adaptation of the released waters to the original conditions of the receiving river.

Global potential

Experts have been discussing chemical CO binding with carbonates for some time. One idea has been to transport rock flour from mountains to the sea via trains and trucks, load it onto ships, and disperse it into the ocean. But the logistical effort would be enormous. Moreover, no one knows how efficiently or quickly the carbonates from the rock flour would react with CO in the water—or whether they would simply sink before the reaction occurs. This is not an issue in an industrial facility: the entire reaction takes place onsite, and the mass balance can be calculated precisely.

"What's great is that the necessary technology is already available," says Thomas. It could begin immediately—unlike many other concepts for reducing atmospheric CO. The potential is enormous: if all alkaline industrial wastewater worldwide were used for this process, around 30 million tons of CO could be bound per year. 

Provided by Helmholtz Association of German Research Centres 

by Torsten Fischer, Helmholtz Association of German Research Centres

edited by Gaby Clark, reviewed by Robert Egan 

Source: Alkaline steel and cement wastewater could capture 30 million tons of CO₂ annually   

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