Insights from Winter 2021-22 using an Acoustic Zooplankton Fish Profiler - Ice in the Coastal Waters of the Nunatsiavut Region of Newfoundland and Labrador, Canada
2021-22年冬季使用聲學(xué)浮游動(dòng)物魚剖面儀的見(jiàn)解--加拿大紐芬蘭與拉布拉多努納特西瓦特地區(qū)沿海水域的冰層情況
Index Terms—sonar, underwater acoustics, instrumentation,ice characteristics, plankton
關(guān)鍵詞:聲納,水下聲學(xué),儀器設(shè)備,冰的特性,浮游生物
摘要——為了支持通過(guò)加拿大沿海地區(qū)由原住民主導(dǎo)的倡議所追求的海洋管理和海洋保護(hù)目標(biāo),需要更好地理解海洋在調(diào)節(jié)氣候和維持復(fù)雜食物網(wǎng)方面的作用。拉布拉多海努納茨亞武特的傳統(tǒng)領(lǐng)海擁有豐富多樣的海洋生態(tài)系統(tǒng),該系統(tǒng)受物理海洋學(xué)和季節(jié)性海冰覆蓋的綜合影響,并由風(fēng)和洋流向南輸送。努納茨亞武特政府開(kāi)展了一項(xiàng)不斷擴(kuò)大的研究項(xiàng)目,以了解和監(jiān)測(cè)這個(gè)復(fù)雜的生物物理系統(tǒng),以支持有效的環(huán)境管理。作為該研究項(xiàng)目的一部分,他們目前正處于對(duì)拉布拉多奈恩附近一個(gè)近海站點(diǎn)的冬季海洋和海冰狀況進(jìn)行監(jiān)測(cè)的第五年。在這個(gè)站點(diǎn)進(jìn)行的測(cè)量包括水溫、鹽度、溶解氧、濁度、洋流以及冰的吃水深度和速度。將這些測(cè)量結(jié)果結(jié)合起來(lái),以了解海洋在調(diào)節(jié)氣候和復(fù)雜食物網(wǎng)中的作用,是支持由原住民主導(dǎo)的研究倡議和加拿大沿海地區(qū)海洋管理的重要一步。
努納茨亞武特政府與ASL環(huán)境科學(xué)公司合作,通過(guò)支持首次部署名為AZFP - ice的新型ASL儀器,進(jìn)一步開(kāi)展該站點(diǎn)的環(huán)境監(jiān)測(cè)。AZFP - ice旨在從其校準(zhǔn)后的(±1 dB)多頻聲學(xué)傳感器收集高時(shí)間和空間分辨率的冰吃水深度測(cè)量數(shù)據(jù)以及同步的生物觀測(cè)數(shù)據(jù)。AZFP - ice是一種經(jīng)過(guò)校準(zhǔn)的科學(xué)單波束回聲測(cè)深儀。AZFP - ice使用中心頻率為417 kHz的窄波束通道來(lái)獲取冰龍骨深度,類似于ASL的冰剖面聲納(IPS)。同步生物觀測(cè)通過(guò)三個(gè)獨(dú)立通道實(shí)現(xiàn),在中心頻率為125 kHz、200 kHz和769 kHz時(shí)收集校準(zhǔn)后的反向散射測(cè)量數(shù)據(jù)。
基于ASL在聲學(xué)浮游動(dòng)物魚類剖面儀(AZFP)聲納系統(tǒng)方面的經(jīng)驗(yàn),AZFP - ice設(shè)計(jì)為每次可自主運(yùn)行長(zhǎng)達(dá)12個(gè)月。AZFP - ice還配備了升級(jí)的電子設(shè)備包,允許在內(nèi)部存儲(chǔ)多達(dá)1 TB的數(shù)據(jù)。其續(xù)航能力和內(nèi)部存儲(chǔ)容量使其具有出色的時(shí)間覆蓋范圍,并且使該儀器非常適合在具有挑戰(zhàn)性的環(huán)境中部署。(異地)工廠校準(zhǔn)允許在絕對(duì)尺度上測(cè)量反向散射,這便于進(jìn)行下游處理,例如漁業(yè)聲學(xué)中常見(jiàn)的所謂“dB差分”方法。
本文介紹了新型AZFP - ice,并展示了其作為環(huán)境監(jiān)測(cè)工具的能力。在AZFP - ice附近放置了一臺(tái)IPS - 5,以便比較觀測(cè)到的冰特征。對(duì)2021年至2022年冬季部署期間收集的數(shù)據(jù)進(jìn)行的初步分析表明,AZFP - ice有助于海冰特征描述。冬季的大部分時(shí)間里,固定冰占主導(dǎo),通過(guò)間距很近的AZFP - ice和IPS - 5對(duì)從解體到冰清除的不同冰段進(jìn)行了比較。
在固定冰期,冰的動(dòng)態(tài)變化較為簡(jiǎn)單,因?yàn)楸鶎?duì)熱力強(qiáng)迫做出響應(yīng)。冬季白晝時(shí)間大幅減少,但與高緯度環(huán)境不同,這個(gè)環(huán)境不會(huì)出現(xiàn)24小時(shí)黑暗。雖然冰可能靜止不動(dòng),但AZFP - ice的其他頻率表明,在白晝減少的這段時(shí)間里,冰下活動(dòng)仍在繼續(xù)。在本文中,我們回顧了這次部署的實(shí)例,展示并討論了AZFP - ice對(duì)冰下生物的聲學(xué)觀測(cè)。結(jié)果表明,AZFP - ice在一臺(tái)儀器中提供了獨(dú)特的測(cè)量組合,為研究人員提供了物理背景(即冰厚度)以及生物數(shù)據(jù)。
Abstract—Improved understanding of the role of the ocean in moderating climate and sustaining complex food webs is required to support ocean stewardship and ocean protection goals being pursued through Indigenous-led initiatives across Canada’s coastlines. The traditional territorial waters of the Nunatsiavut in the Labrador Sea contain a rich and diverse marine ecosystem
regulated by a combination of physical oceanography and the presence of seasonal sea ice cover, transported southward by wind and ocean currents. The Nunatsiavut Government operates a growing research program to understand and monitor this complex biophysical system to support effective environmental management. As part of this research program, they are now in the fifth year of monitoring over-winter ocean and sea ice conditions at an offshore site near Nain, Labrador. Measurements made at this site have included water temperature, salinity, dissolved oxygen, turbidity, currents, and ice drafts and velocities.
Combining these measurements to understand the ocean’s role in moderating climate and complex food webs is an important step in support of Indigenous-led research initiatives and ocean stewardship across Canada’s coastlines.
The Nunatsiavut Government has collaborated with ASL Environmental Sciences to further develop environmental mon- itoring at this site by supporting the first-ever deployment of the new ASL instrument known as the AZFP-ice. The AZFP-ice is designed to collect high temporal and spatial resolution measurements of ice draft and simultaneous biological obser-vations from its calibrated (±1 dB) multifrequency acoustical sensors. The AZFP-ice is a calibrated, scientific, singlebeam echosounder. The AZFP-ice uses a narrow beam 417 kHz center frequency channel to obtain ice keel depth, similar to ASL’s Ice Profiling Sonar (IPS). Simultaneous biological observations are realized using three separate channels, collecting calibrated backscatter measurements at 125 kHz, 200 kHz, and 769 kHz center frequencies.
Building on ASL’s experience with the Acoustic Zooplankton Fish Profiler (AZFP) sonar system, the AZFP-ice is designed to operate autonomously for up to 12 months at a time. The AZFP-ice also features an upgraded electronics package that allows up to 1 TB of data to be stored internally. Its endurance and its internal memory capacity allow for excellent temporal coverage and make the instrument well-suited for deployment in challenging environments. The (ex situ) factory calibration allows backscatter to be measured on an absolute scale, which facilitates downstream processing such as the so-called ‘dB differencing’ approach that is common in fisheries acoustics.
This paper introduces the new AZFP-ice and showcases its capabilities as a tool for environmental monitoring. An IPS-5 was located near the AZFP-ice, allowing for a comparison of the observed ice characteristics. Preliminary analysis of the data collected during an over-winter deployment from 2021 to 2022 indicates that the AZFP-ice facilitates sea-ice characterization.
Much of the over-winter period is dominated by landfast ice, and segments of ice from break-up to ice clearing are compared from the closely spaced AZFP-ice and IPS-5.During the period of landfast ice, the ice dynamics are simple as the ice responds to the thermodynamic forcing. Daylight hours are greatly reduced in the winter, but this environment does not experience 24-hour darkness, unlike high-latitude environments. While the ice may be motionless, the other AZFP-ice frequencies indicate that below the ice activity continues during this period of reduced daylight. In this paper, the AZFP-ice’s acoustical observations of the under-ice biology are presented and discussed as we review examples from this deployment. The AZFP-ice is shown to provide a unique combination of measurements in a single instrument, offering researchers a physical context (i.e. ice thickness) alongside biological data.
