Ambient Sound at Challenger Deep, Mariana Trench

Dziak, Robert P.; Haxel, J. H.; Matsumoto, H.; Lau, Tai-Kwan; Heimlich, Sara L.; Nieukirk, Sharon L.; Mellinger, David K.; Osse, J.; Meinig, Christian; Delich, N.; Stalin, Scott

doi:10.5670/oceanog.2017.240

Cited by 16 publications

(12 citation statements)

References 25 publications

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“…Furthermore, we noticed the low‐frequency soundscape off Minamitorishima Island was quieter than that at Challenger Deep, Mariana Trench. The acoustic data reported by Dziak et al (2017) demonstrated a hadal environment influenced by numerous seismic activities, persistent shipping traffic, and the passing of a Category 4 typhoon, a pattern not found in the recordings collected off Minamitorishima Island. Due to the remote location of Minamitorishima Island and lower shipping activities around it, the discrepancy between the two acoustic data sets could imply the influence of anthropogenic and geophysical activities on deep‐sea soundscapes.…”

Section: Discussionmentioning

confidence: 88%

“…Despite comprising over 75% of the world's biosphere (Angel 1997), the deep sea remains the last frontier on Earth—but it is far from untouched by humankind. From plastic debris to shipping noise, our activities have cast vivid shadows to the deep, evident even at the bottom of the Mariana Trench (Dziak et al 2017; Chiba et al 2018). Recently, surging interests in mining the deep for minerals to feed the ever‐growing global needs have stepped our potential influence up to a new level (Van Dover et al 2018; Smith et al 2020).…”

Section: Figmentioning

confidence: 99%

“…To monitor changes in soundscapes, it is important to establish baselines of environmental sounds before the impacts occur. To date, relatively few soundscape baseline characterizations have been carried out at the deep seafloor (Dziak et al 2017), but the fact that mining activities can severely impact the local soundscape has been evident in oil and gas extraction—through both exploratory air guns and actual drilling (Hildebrand 2009; Kyhn et al 2014; Wiggins et al 2016).…”

Section: Figmentioning

confidence: 99%

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Baseline soundscapes of deep‐sea habitats reveal heterogeneity among ecosystems and sensitivity to anthropogenic impacts

Chen

Lin

Watanabe

et al. 2021

Limnology & Oceanography

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Underwater soundscapes, though invisible, are crucial in shaping the biodiversity of marine ecosystems by acting as habitat‐specific settlement cues for larvae. The deep sea has received little attention in soundscape research, but it is being targeted for mineral extraction to feed the ever‐growing needs of our society. Anthropogenic impacts on soundscapes influence the resilience of key shallow‐water habitats, and the same likely applies to the deep. Japan is a forerunner in deep‐sea mining, but virtually no deep soundscape baselines exist for Japanese waters. Here, we report baseline soundscapes from four deep‐sea locations in Japan, including the Suiyo Seamount hydrothermal vent, the abyssal plain around the Minamitorishima Island home to manganese nodule fields and muds rich in rare‐earth elements, twilight depths off Sanriku, as well as a typical bathyal system in Suruga Bay. Long‐duration audio recordings were visualized and factorized by an unsupervised machine learning model, revealing differing characteristics among the habitats. Two locations near the coast are highly influenced by shipping noise. The Suiyo vent is characterized by low‐frequency sounds from venting, and the abyssal Minamitorishima is quiet with a flat spectral shape. Noise from observation platforms is likely sufficient to alter soundscape characteristics, especially in offshore locations, suggesting offshore mining‐targeted areas are susceptible to impacts from anthropogenic noise. We argue that the monitoring of soundscapes is an indispensable component for assessing potential mining impacts on deep‐sea ecosystems. Our results establish reference points for future soundscape monitoring and assessment in Japanese waters as well as similar ecosystems globally.

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Section: Discussionmentioning

confidence: 88%

Section: Figmentioning

confidence: 99%

Section: Figmentioning

confidence: 99%

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Baseline soundscapes of deep‐sea habitats reveal heterogeneity among ecosystems and sensitivity to anthropogenic impacts

Chen

Lin

Watanabe

et al. 2021

Limnology & Oceanography

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“…The published results are representative of the unpublished results, most of which come from cruise reports. The methods used to measure such extreme ocean depths, besides traditional sounding with a weighted rope or cable, have included explosives and stopwatches (Carruthers and Lawford, 1952;Gaskell et al, 1953), single-beam sonar (Hanson et al, 1959;Mantyla and Reid, 1978;Taira et al, 2004Taira et al, , 2005Nakanishi and Hashimoto, 2011), multibeam sonar (Hydrographic Department and Japan Marine Safety Agency, 1984;Fujioka et al, 2002;Nakanishi and Hashimoto, 2011;Gardner et al, 2014;van Haren et al, 2017), side-scan sonar (Fryer et al, 2003), and pressure sensors (Piccard and Dietz, 1967;Todo et al, 2005;Bowen et al, 2009; 2012 James Cameron dive; Dziak et al, 2017;Fitzherbert, 2019). Gardner et al (2014) and Stewart and Jamieson (2019) both provide a review of previous investigations of the deepest part of the ocean.…”

Section: Introductionmentioning

confidence: 99%

“…obtained from Matthew's tables of sound speed (Matthews, 1939;Carruthers and Lawford, 1952;Mantyla and Reid, 1978;Zheng, 2015), comprising a compilation of historical measurements of water column chemistry by latitude and longitude. In modern times, direct measurements of the sound speed profile over the Challenger Deep have been made with conductivity, temperature, depth (CTD) sensors mounted on either deep submersibles or free-falling vehicles (Piccard and Dietz, 1967;Bowen et al, 2009;Taira et al, 2004;Barclay et al, 2017;Dziak et al, 2017;van Haren et al, 2017) and with expendable bathythermographs (XBTs; Fujioka et al, 2002;Gardner et al, 2014). Ideally, for depth estimation, such determinations of the sound speed profile should be concurrent with the acquisition of the time-of-flight data; otherwise, significant errors can arise in the acoustic estimate of the ocean depth (Beaudoin et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

Implosion in the Challenger Deep: Echo Sounding with the Shock Wave

Loranger¹,

Barclay²,

Buckingham³

2021

Oceanog

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Since HMS Challenger made the first sounding in the Mariana Trench in 1875, scientists and explorers have been seeking to establish the exact location and depth of the deepest part of the ocean. The scientific consensus is that the deepest depth is situated in the Challenger Deep, an abyss in the Mariana Trench with depths greater than 10,000 m. Since1952, when HMS Challenger II, following its namesake, returned to the Mariana Trench, 20 estimates (including the one from this study) of the depth of the Challenger Deep have been made. The location and depth estimates are as diverse as the methods used to obtain them; they range from early measurements with explosives and stop watches, to single- and multi-beam sonars, to submersibles, both crewed and remotely operated. In December 2014, we participated in an expedition to the Challenger Deep onboard Schmidt Ocean Institute’s R/V Falkor and deployed two free-falling, passive-acoustic instrument platforms, each with a glass-sphere pressure housing containing system electronics. At a nominal depth of 9,000 m, one of these housings imploded, creating a highly energetic shock wave that, as recorded by the other instrument, reflected multiple times from the sea surface and seafloor. From the arrival times of these multi-path pulses at the surviving instrument, in conjunction with a concurrent measurement of the sound speed profile in the water column, we obtained a highly constrained acoustic estimate of the Challenger Deep: 10,983 ± 6 m.

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Acoustic twilight: A year‐long seafloor monitoring unveils phenological patterns in the abyssal soundscape

Lin,

Kawagucci

2023

Limnol Oceanogr Letters

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Despite the perpetual darkness of the deep sea, contrasting the sunlit epipelagic waters, many deep‐sea organisms exhibit rhythmic activities. To discern environmental cues that may serve as entrainment signals for deep‐sea organisms, this study investigated the soundscape of the abyssal plain south of Minamitorishima Island. Our analysis revealed clear diel and seasonal patterns, primarily driven by evening fish choruses and marine mammal vocalizations. These evening choruses, discernible above the background noise, likely serve as a circadian time cue for organisms capable of perceiving them within the aphotic depths. In addition, the frequent detection of whistles and echolocation clicks suggests this region functions as a foraging ground for marine mammals. These acoustic cues might guide organisms with auditory capabilities toward habitats rich in sinking food debris and whale falls. By elucidating the ecological processes shaping abyssal soundscape dynamics, these findings open new directions for further exploration in deep‐sea chronobiology.

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Ambient Sound at Challenger Deep, Mariana Trench

Cited by 16 publications

References 25 publications

Baseline soundscapes of deep‐sea habitats reveal heterogeneity among ecosystems and sensitivity to anthropogenic impacts

Baseline soundscapes of deep‐sea habitats reveal heterogeneity among ecosystems and sensitivity to anthropogenic impacts

Implosion in the Challenger Deep: Echo Sounding with the Shock Wave

Acoustic twilight: A year‐long seafloor monitoring unveils phenological patterns in the abyssal soundscape

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