For over a century, scientists have confronted a perplexing inconsistency in astronomical observations. The rotational behavior of galaxies suggests the presence of a substantial amount of unseen mass, commonly referred to as dark matter. However, its exact nature remains elusive, making its detection a formidable challenge.

To refine our understanding of dark matter, researchers are now integrating sophisticated models with high-precision observational data. A team led by Associate Professor Wen Yin at Tokyo Metropolitan University recently employed an innovative spectrographic method to study light from the galaxies Leo V and Tucana II. Their work, conducted using the 6.5-meter Magellan Clay Telescope in Chile, concentrated on the infrared spectrum-a promising region for detecting dark matter signatures.

The team focused on a theoretical dark matter candidate known as the axionlike particle (ALP), which is hypothesized to decay and emit light. Current models suggest that the near-infrared spectrum is particularly conducive to detecting such decays. However, this portion of the electromagnetic spectrum is cluttered with various sources of interference, including zodiacal light-caused by sunlight scattering off interstellar dust-and emissions from Earth's atmosphere.

To overcome these challenges, the researchers previously proposed a technique leveraging the differing wavelength distributions of background radiation and light from dark matter decay. Unlike broad-spectrum background noise, light from decay events is concentrated in a narrow range, making it more identifiable. Infrared spectrographs such as NIRSpec aboard the James Webb Space Telescope and WINERED on the Magellan Clay Telescope provide the precision necessary to implement this method, effectively transforming these instruments into dark matter detectors.

The study's high-precision measurements, enabled by the WINERED spectrograph, allowed the team to systematically account for all detected near-infrared light with significant statistical accuracy. The absence of any observed decay events was then used to establish an upper limit on their frequency and a corresponding lower limit on the lifetime of ALP particles. Their analysis indicates that the minimum lifetime of these particles is between 10^25 and 10^26 seconds-roughly ten to a hundred million times the age of the universe.

This breakthrough represents the most stringent limit yet placed on the longevity of dark matter. Furthermore, the research highlights the synergy between infrared cosmology and particle physics in unraveling the universe's fundamental mysteries. While the current findings remain consistent with theoretical expectations, the team has also identified potential anomalies-slight excesses in detected signals-that hint at the possibility of future dark matter detection with additional data and further refinement of analytical techniques. The quest to uncover the missing component of the cosmos continues.

Research Report:First Result for Dark Matter Search by WINERED

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