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Collaborative Research: Investigating Thermal Structure, Dynamics, and Dehydration in the Tropical Tropopause Layer with Fiber Optic Temperature Profiling from Strateole-2 Balloons

合作研究：利用 Strateole-2 气球的光纤温度剖面研究热带对流层顶层的热结构、动力学和脱水

基本信息

批准号：
1642277
负责人：
Lars Kalnajs
金额：
$ 86.83万
依托单位：
University of Colorado at Boulder
依托单位国家：
美国
项目类别：
Continuing Grant
财政年份：
2017
资助国家：
美国
起止时间：
2017-02-01 至 2024-01-31
项目状态：
已结题

来源：
https://www.nsf.gov/awardsearch/showAward?AWD_ID=1642277&HistoricalAwards=false
关键词：
Collaborative Research Investigating Thermal Structure

项目摘要

The tropical tropopause layer (TTL) is transition zone between the troposphere (the domain of clouds, precipitation, and weather systems) and the stratosphere (the cold and dry region above it which contains the ozone layer). The TTL extends from about 14 to 18.5km over the tropics and is above the tops of all but the tallest convective clouds. It often contains thin cirrus clouds which, though difficult to see, play an outsized role in trapping outgoing radiation and thus warming the troposphere. It is sometimes called the "gateway to the stratosphere" because most of the water vapor in the stratosphere, and many other stratospheric constituents, enter the stratosphere by moving upward through the TTL. The stratosphere is extremely dry compared to the troposphere, but stratospheric water vapor is of interest because it has an important greenhouse effect and can lead to the formation of polar stratospheric clouds which play a role in ozone hole formation.Work under this project seeks to improve understanding of the TTL by developing and deploying a temperature profiler as part of a long-duration ballooning campaign. The profiler, with the acronym FLOATS (Fiber-optic Laser Operated Atmospheric Temperature Sensor), measures temperature along a fiber optic cable 2km long which is suspended below a balloon gondola. FLOATS works by injecting laser light into a fiber optic cable and sensing Raman backscattered light. It can measure temperature with 0.3K precision and a vertical resolution of 3m, generating a profile every two to five minutes. A proof-of-concept prototype was developed under an EAGER award, AGS-1419932. FLOATS is deployed as part of the Strateole-2 field campaign organized by the Centre National d'Etudes Spatiales (CNES), the French Space Agency, and the Laboratoire de Meteorologie Dynamic (LMD) of the University of Paris-Saclay. Strateole-2 is a five-year campaign, with a small validation deployment in 2018 and full science deployments in 2020-2021 and 2022-2023. Balloons are launched from the Seychelles (about 5S in the Indian Ocean), with the expectation that each balloon will circle the earth for up to 90 days and observe the TTL between 20S and 15N. This award supports US participation in the validation campaign and the first full science deployment, along with post-campaign analysis. It is one of three awards made to US PIs for participation in Strateole-2, the full set being AGS-1643022, AGS-1642277/1642246, and AGS-1642650/1653644.The FLOATS measurements are used to address three scientific objectives, all of which use temperature variations along the fiber optic cable to examine the behavior of gravity waves (wave motions in the air in which buoyancy provides the restoring force). The first is the depression of the cold point tropopause (CPT) temperature by vertically propagating gravity waves, which is a key factor in determining how much water vapor enters the stratosphere through the TTL. If condensation or sublimation occurs when relative humidity reaches 100%, then the amount of water vapor entering the stratosphere should not exceed the amount corresponding to 100% relative humidity at the CPT temperature. Earlier work by one of the PIs and others suggests that wave-induced CPT temperature depression could be significant, and an increase in wave activity could be responsible for a substantial portion of the decrease in CPT temperature and stratospheric water vapor believed to have occurred in the first decade of the 21st century. The second science objective is to understand the role of gravity waves in producing cirrus clouds in the TTL. The problem is complementary to stratospheric dehydration produced by temperature depression, as water vapor prevented from entering the stratosphere by colder temperatures instead freezes out to form cirrus ice particles.The third objective is to measure the vertical momentum flux associated with the waves. These waves are critical for the stratospheric quasi-biennial oscillation (QBO), which can influence the skill of long-range weather forecasts. Momentum flux would be estimated by combining FLOATS measurements (which give wave amplitude, vertical wavelength, and phase speed) with additional measurement taken on the balloon gondola including wave-induced directional displacement inferred from GPS positioning.The work has scientific broader impacts due to the value of the observations for addressing a variety of questions regarding TTL processes and the stratospheric QBO. In particular, wave momentum flux data is of value for developing gravity wave parameterizations for use in improving numerical models used for weather forecasting. FLOATS observations will be made available to the research community from servers at the Laboratory for Atmospheric and Space Physics at the University of Colorado Boulder, so that they can be freely examined by the research community. In addition, the project constitutes a demonstration of a novel technology for meteorological observations which could have a wide array of scientific applications. Beyond these considerations, the project supports a postdoctoral research associate, thereby developing the future scientific workforce in this research area.

热带对流层顶层（TTL）是对流层（云，降水和天气系统的领域）和平流层（其上包含臭氧层的寒冷干燥区域）之间的过渡区。 TTL在热带上空延伸约14至18.5公里，除了最高的对流云之外，它位于所有对流云的顶部。它通常包含薄卷云，虽然很难看到，但在捕获向外辐射，从而使对流层变暖方面发挥了巨大作用。它有时也被称为“通往平流层的大门”，因为平流层中的大部分水蒸气和许多其他平流层成分都是通过TTL向上移动进入平流层的。与对流层相比，平流层极为干燥，但平流层水蒸气令人感兴趣，因为它具有重要的温室效应，并可导致形成极地平流层云，而平流层云在臭氧洞的形成中发挥作用，本项目下的工作旨在通过开发和部署温度剖面仪作为长期气球飞行活动的一部分，提高对TTL的认识。该探测器的首字母缩写为FLOATS（光纤激光操作大气温度传感器），测量沿着2公里长的光纤电缆的温度，该电缆悬挂在气球吊舱下面。 FLOATS的工作原理是将激光注入光纤电缆并检测拉曼反向散射光。它可以以0.3K的精度和3米的垂直分辨率测量温度，每两到五分钟生成一个剖面。概念验证原型是在EAGER奖AGS-1419932下开发的。 FLOATS是由法国国家空间研究中心（CNES）、法国航天局和巴黎萨克雷大学气象动态实验室（LMD）组织的Strategole-2野外活动的一部分。 “彗星-2”是一项为期五年的活动，2018年将进行小规模验证部署，2020-2021年和2022-2023年将进行全面科学部署。气球从塞舌尔群岛（印度洋约5S）发射，预计每个气球将环绕地球长达90天，并观察20 S和15 N之间的TTL。该奖项支持美国参与验证活动和第一次全面的科学部署，沿着活动后分析。它是授予美国PI的三个奖项之一，用于参与AGS-2，全套是AGS-1643022，AGS-1642277/1642246和AGS-1642650/1653644。FLOATS测量用于解决三个科学目标，所有这些都使用沿着光纤电缆的温度变化来检查重力波（空气中的波动，其中浮力提供恢复力）的行为。首先是垂直传播的重力波降低冷点对流层顶（CPT）温度，这是决定有多少水蒸气通过TTL进入平流层的关键因素。如果当相对湿度达到100%时发生冷凝或升华，则进入平流层的水蒸气量不应超过CPT温度下100%相对湿度对应的量。其中一位PI和其他人的早期工作表明，波浪引起的CPT温度降低可能是显著的，波浪活动的增加可能是CPT温度和平流层水汽下降的主要原因，据信这是在21世纪世纪的第一个十年发生的。第二个科学目标是了解重力波在TTL中产生卷云的作用。这个问题与温度下降造成的平流层脱水是相辅相成的，因为较低的温度阻止水蒸气进入平流层，而不是冻结形成卷云冰粒。第三个目标是测量与波相关的垂直动量通量。这些波是平流层准两年振荡（QBO）的关键，它可以影响长期天气预报的技能。动量通量将估计结合FLOATS测量（其中给出波的振幅，垂直波长，和相速度）与额外的测量气球吊舱，包括从GPS定位推断的波诱导方向位移。这项工作具有更广泛的科学影响，由于价值的意见，为解决各种有关TTL过程和平流层QBO的问题。特别是，波动量通量数据是有价值的开发重力波参数化，用于改进用于天气预报的数值模型。 FLOATS观测数据将通过科罗拉多大学博尔德分校大气和空间物理实验室的服务器提供给研究界，以便研究界可以自由地对其进行检查。此外，该项目还展示了一种新型气象观测技术，该技术可能具有广泛的科学应用。除了这些考虑因素，该项目还支持博士后研究助理，从而发展该研究领域未来的科学劳动力。