Increasing Shortwave Penetration Through the Bottom of the Oceanic Mixed Layer in a Warmer Climate

Shortwave penetration (Qpen) through the bottom of the oceanic mixed layer (ML) profoundly affects the thermal structure in the upper ocean and consequently contributes to sea surface temperature (SST) change, which has not been adequately understood under global warming. Here, using ensemble earth...

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Bibliographic Details
Published in:Journal of geophysical research. Oceans 2023-07, Vol.128 (7), p.n/a
Main Authors: Tian, Feng, Zhang, Rong‐Hua
Format: Article
Language:English
Subjects:
21st century
Air-sea flux
Anthropogenic factors
Chlorophyll
Chlorophylls
Climate change
Climate effects
Cooling
Emissions
Fluctuations
Geophysics
Global climate
Global warming
Heat balance
Heat budget
Heat flux
Heat transfer
Heating
Human influences
Man-induced effects
Mixed layer
Mixed layer depth
Ocean mixed layer
Ocean temperature
Ocean warming
Oceans
Optical properties
Radiation
Sea surface
Sea surface temperature
Short wave radiation
Surface cooling
Surface temperature
Thermal structure
Upper ocean
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Summary:Shortwave penetration (Qpen) through the bottom of the oceanic mixed layer (ML) profoundly affects the thermal structure in the upper ocean and consequently contributes to sea surface temperature (SST) change, which has not been adequately understood under global warming. Here, using ensemble earth system model simulations under a high‐emissions scenario (SSP5‐8.5), we investigate the Qpen change and related effects on some oceanic parameters, which are regionally dependent. It is found that globally averaged Qpen typically increased by 2.49 ± 0.83 W m−2 in the second half of the 21st century, which is comparable to an increase in the net surface heat flux (3.01 ± 0.31 W m−2), corresponding to an increase in SST by 3.07 ± 0.83°C. Although there exist substantial intermodel uncertainties in the projected chlorophyll change, the shoaled ML contributes the most of the increase in Qpen in the global ocean, whereas in the tropical ocean, the reduction in the chlorophyll concentration plays an equivalent role with the mixed layer depth in determining Qpen change. The ML heat budget indicates that the enhanced Qpen leads to surface cooling through a decrease in the surface net surface heat flux. However, the cooling is compensated for by a warming effect from ocean dynamical change due to more shortwave penetration into the subsurface layer, leading to a small net effect on the ML heat budget. It is suggested that the impact of Qpen on the global oceanic ML heat balance needs to be adequately recognized. Plain Language Summary Understanding the mechanism for ocean warming induced by anthropogenic effects (e.g., global warming) is important to study global climate change. The accumulated heat into the ocean (heat gain) mainly consists of heat fluxes at the air–sea interface absorbed with the oceanic mixed layer (ML). Additionally, a small part of shortwave radiation (∼20 W m−2) can penetrate out of the bottom of the ML and enters the subsurface ocean, which is referred to as Qpen. As Qpen is instantaneously determined by the ML depth and chlorophyll concentration, it also reflects optical characteristics associated with the redistribution of net surface heat flux and biomass. However, the Qpen change characteristics and its climatic effect under anthropogenic warming have not been quantified yet. Here, we found that the globally averaged Qpen typically increased by 2.49 ± 0.83 W m−2 in the second half of the 21st century. Furthermore, the enhanced Qpen leads to le
ISSN:2169-9275
2169-9291
DOI:10.1029/2022JC019587