ACTIVATE: Mission
Principal Investigator (PI): | Armin Sorooshian, U. of Arizona (UA) |
Deputy PI: | Xubin Zeng, UA |
Project Scientist: | Johnathan Hair, NASA LaRC |
Partnering Institutions: | UA, NASA LaRC, NASA GISS, SSAI, NIA, PNNL, U of Miami, NOAA ESRL |
Mission Overview and Platforms: ACTIVATE will deploy two complementary aircraft over the western North Atlantic Ocean – the NASA LaRC HU-25 Falcon and B-200 King Air. The HU-25 acquires in situ measurements below, in, and above clouds. The B-200 flies above clouds to remotely measure aerosols and clouds using the High Spectral Resolution Lidar-2 (HSRL‑2), the Research Scanning Polarimeter (RSP), and deploys dropsondes to measure the atmospheric state. Since both aircraft and the majority of in situ and remote sensing instruments are based at LaRC adjacent to the western Atlantic study region, ACTIVATE will acquire a statistically robust dataset through an extensive series of flights (~50 joint airplane missions per year) in each of three years (~600 hours and ~150 flights over three years for each airplane). We will sample a wide range of aerosol and cloud conditions by planning February–June flights.
Mission Schedule
How will it work?
- Location
- The western North Atlantic Ocean is selected for ACTIVATE for three reasons:
- it includes a wide range of MBL cloud types, from stratiform to cumulus clouds;
- it is affected by pollution transport;
- its close proximity to LaRC increases both flight time and flight plan flexibility.
- The western North Atlantic Ocean is selected for ACTIVATE for three reasons:
- Aircraft Coordination
- The ACTIVATE suite of instruments is divided between two aircraft; the low-flying HU-25 (with a minimum altitude of 0.15 km) and the higher-flying B-200.
- Based on consultation with LaRC pilots, these two aircraft will be flown at altitudes that are ideally matched in terms of ground speeds and flight endurance to provide close spatially and temporally coordinated flights.
- The ACTIVATE suite of instruments is divided between two aircraft; the low-flying HU-25 (with a minimum altitude of 0.15 km) and the higher-flying B-200.
- Schedule
- Briefly, the schedule includes two campaigns (February–March and May–June) in each of three years during 2020–2022 (total of six), thereby sampling part of the annual cycle (late winter to early summer) in cloud and aerosol properties.
- We plan for 150 joint flights with two coordinated aircraft, which is the maximum that can be conducted under the budgetary and logistical constraints. These flights would provide an order of magnitude more ‘cloud events’ than previous airborne projects (see §3.1) and hence will offer unprecedented statistics to build robust aerosol-cloud interactive model parameterizations. This can best be achieved between February-March and May-June over three years by executing 100 flight hours during 25 flights for each aircraft in each of the six campaigns (for a combined aircraft total of 1200 hours and 300 flights over the project lifetime). After each upload, 1–2 test flights (2 hrs) are planned for each platform consistent with previous projects. Each campaign year consists of a single instrument upload and download period. Given that multiple flights can be conducted on the same day, the 25 joint flights for each campaign over a two month duration results in a reasonable pace of operations to target specific cloud scenes. A month long hiatus, also used for schedule reserve, between the two campaigns allows for an early period of preliminary data analysis and instrument and aircraft maintenance. By leveraging recent, similar implementation approaches with proven instruments and experienced teams, ACTIVATE is well-positioned to execute a comprehensive, yet low-risk, series of campaigns.
- Briefly, the schedule includes two campaigns (February–March and May–June) in each of three years during 2020–2022 (total of six), thereby sampling part of the annual cycle (late winter to early summer) in cloud and aerosol properties.