Polski

The Japanese team uses laser technology for ice core sampling to accurately study climate change

996
2023-09-23 10:20:57
Zobacz tłumaczenie

Recently, a research team from the Astronomical Glaciology Laboratory under the RIKEN Nishina Center (RNC) of the Japanese Institute of Physics and Chemistry announced that they have developed a new laser based sampling system for studying the composition of glacier ice cores.


The above image shows the discrete holes sampled 150mm from the shallow ice core of the Fuji Ice Dome in Japan (Southeast Antarctica)
(Image source: RIKEN)


The depth resolution of the new system is 3 millimeters, three times lower than the currently available resolution, which means it can detect temperature changes that occurred in a shorter period of time in the past.

The new laser melting sampler (LMS) is expected to help reconstruct continuous annual temperature changes thousands to hundreds of thousands of years ago, which will help scientists understand past and present climate change. This study was published in the Journal of Glaciology on September 19, 2023.

Draw a climate history map
Tree rings can tell us the age of trees, and the color and width of the rings reveal information about the local climate in those years. The annual growth of glaciers can also tell us this information, but it often takes much longer. The team of scientists led by Yuko Motizuki also hopes that they can study past climate change by analyzing cylindrical ice cores extracted from glaciers.

By regularly sampling along the core, researchers can reconstruct a continuous temperature distribution. However, for samples collected from depths, this is impossible because the annual accumulation there is usually compressed to sub centimeters.

Currently, scientists typically use two standard ice core sampling methods. One method yields a depth accuracy of approximately 10 millimeters, which means that data accumulated for years less than 10 millimeters will be lost, and any significant climate change event will be missed. Another method has good depth accuracy, but it destroys some of the samples required for analyzing water content, which is the main method used by scientists to calculate past temperatures.

The new laser melting sampler overcomes these two problems: it has high depth accuracy and does not damage the key oxygen and hydrogen isotopes found in water, which are necessary for inferring past temperatures.

From: Ofweek





Powiązane rekomendacje
  • Inertia Enterprises focuses on the commercialization of fusion energy

    Inertia Enterprises, a private fusion power start-up, based in San Francisco, CA., has announced the formation of the company, co-founded by fusion energy pioneer Dr. Andrea “Annie” Kritcher, fusion power plant designer Prof. Mike Dunne, and successful tech entrepreneur, Jeff Lawson.Underpinned by this team of experts spanning science, engineering, technology and business, Inertia stated that it i...

    08-29
    Zobacz tłumaczenie
  • Researchers use a new frequency comb to capture photon high-speed processes

    From detecting COVID in respiration to monitoring greenhouse gas concentrations, laser technology called frequency combs can recognize specific molecules as simple as carbon dioxide to as complex as monoclonal antibodies, with unparalleled accuracy and sensitivity. Although frequency combs have incredible capabilities, their ability to capture high-speed processes such as hypersonic propulsion or ...

    2023-11-02
    Zobacz tłumaczenie
  • IPG launches dual beam fiber laser for additive manufacturing applications

    Recently, American fiber laser giant IPG Photonics announced the launch of a new laser series specifically designed for the additive manufacturing field.The highlight of this series of lasers lies in its integration of IPG's unique dual beam technology, which can independently regulate and simultaneously emit core and ring beams, setting a new benchmark in accuracy, efficiency, and reliability.Ba...

    2024-11-25
    Zobacz tłumaczenie
  • Laser Uranium Enrichment Company (GLE) accelerates development

    Paducah, located in western Kentucky, may become the location of the world's first commercial facility to adopt this technology.Since 2016, Global Laser Enrichment Company (GLE) has partnered with the US Department of Energy to use its unique molecular process to concentrate 200000 tons of depleted uranium "tails" stored at the former Padiuka gas diffusion plant in western Kentucky.After years of ...

    2024-06-22
    Zobacz tłumaczenie
  • Researchers have developed a QCL DFB continuous laser for gas detection

    Alpes Laser was founded in 1998 in Nazhatel, Switzerland and was the first company to bring quantum cascade lasers to the market. It released its first continuous laser in 2001 and its first high gain laser in 2009, thus maintaining this priority position.In 2004, the first commercial laser was introduced.Principle: In a single mode laser, the grating is etched into the active region to force the ...

    2023-08-16
    Zobacz tłumaczenie