春水堂视频

More snow is melting during winter across the West, a concerning trend that could impact everything from ski conditions to fire danger and agriculture, according to a new CU Boulder analysis of 40 years of data, led by Keith Musselman.

Imagine not a white, but a green Arctic, with woody shrubs as far north as the Canadian coast of the Arctic Ocean. This is what the northernmost region of North America looked like about 125,000 years ago, during the last interglacial period, finds new research from CU Boulder led by Sarah Crump. Researchers analyzed plant DNA more than 100,000 years old retrieved from lake sediment in the Arctic and found evidence of a past ecosystem. As the Arctic warms much faster than everywhere else on the planet in response to climate change, the findings, published this week in the Proceedings of the National Academy of Sciences, may not only be a glimpse of the past but a snapshot of our potential future.

During the first half of 2020, global greenhouse gas emissions dropped by about nine percent in the midst of the COVID-19 outbreak. People around the world reported seeing signs that 鈥渘ature was healing鈥� as a result of a steep decline in human activities such as transportation and production. However, a new study from UC Boulder has shown that the positive changes seen in natural ecosystems were not reflected throughout Earth鈥檚 oceans.

The COVID-19 pandemic resulting shutdowns resulted in a 9% drop in the greenhouse gas emissions at the root of climate change. Unfortunately, any silver lining from the pandemic remains murky in the oceans. INSTAAR researchers Nicole Lovenduski delved into the data and found no detectable slowing of ocean acidification due to COVID-19 emissions reductions. Even at emissions reductions four times the rate of those in the first half of 2020, the change would be barely noticeable. Lovenduski shared the results Friday, Dec. 11 at the American Geophysical Union 2020 Fall Meeting. The findings will also be submitted to the journal Geophysical Research Letters.

A long-term trend of ecological improvement is appearing in the mountains west of Boulder. Researchers from CU Boulder have found that, thanks to vehicle emission regulations, Niwot Ridge is slowly recovering from increased acidity caused by vehicle emissions in Colorado鈥檚 Front Range. Their results show that nitric and sulfuric acid levels in the Green Lakes Valley region of Niwot Ridge have generally decreased over the past 30 years, especially since the mid-2000s.

A team of past and present INSTAAR researchers have reconstructed the history of Teton Glacier, Wyoming, by analyzing sediment from alpine lakes. Their work is documented in a new study published this week in Science Advances.

A giant methane cloud caught by satellite in 2014 looming over the U.S. Southwest wasn鈥檛 a persistent hotspot, as first thought when it made national news. Instead, the methane cloud was the nightly build-up of polluted air that trapped emissions of the potent greenhouse gas near the ground, according to a new CIRES- and NOAA-led study with INSTAAR participants.

Current and former INSTAARs Darren Larsen, Sarah Crump, and Aria Blumm analyzed sediment from a glacial lake to learn about glacier fluctuations and climate shifts over the last 10,000 years.

A 9News interview with Bob Brakenridge, author of a new paper suggesting that supernovas have impacted Earth's atmosphere and climate, leaving traces that can be seen in tree rings. Watch a 2-minute video.

Massive explosions of energy happening thousands of light-years from Earth may have left traces in our planet鈥檚 biology and geology, according to new research by CU Boulder geoscientist Robert Brakenridge. The study, published this month in the International Journal of Astrobiology, probes the impacts of supernovas, some of the most violent events in the known universe. To study those possible impacts, Brakenridge searched through the planet鈥檚 tree ring records for the fingerprints of these distant, cosmic explosions. While not conclusive, his findings suggest that relatively close supernovas could theoretically have triggered at least four disruptions to Earth鈥檚 climate over the last 40,000 years.