Elsevier

Atmospheric Research

Volume 240, August 2020, 104946
Atmospheric Research

Evaluation of land-atmosphere processes of the Polar WRF in the summertime Arctic tundra

https://doi.org/10.1016/j.atmosres.2020.104946Get rights and content
Under a Creative Commons license
open access

Highlights

  • Arctic tundra is exposed to warmer conditions with a warming global climate.

  • Polar WRF has bias in simulating climate near the surface on clear summer days.

  • Polar WRF reproduces the observations accurately with the observed soil moisture.

  • Regional climate simulation improves with proper numerical design over the Arctic.

Abstract

Arctic tundra is undergoing a rapid transition due to global warming and will be exposed to snow-free conditions for longer periods under projected climate scenarios. Regional climate modeling is useful for understanding and predicting climate change in the Arctic tundra, however, the lack of in-situ observations of surface energy fluxes and the planetary boundary layer (PBL) structure hinders accurate predictions of local and regional climate around the Arctic. In this study, we investigate the performance of the Polar-optimized version of the Weather Research and Forecasting model (PWRF) in the Arctic tundra on clear days in summer. Based on simultaneous observations of surface fluxes and the PBL structure in Cambridge Bay, Nunavut, Canada, our validation shows that the PWRF simulates a drier environment, leading to a larger Bowen ratio and a warmer atmosphere compared to observations. Further sensitivity analyses indicate that the model biases are mainly from the uncertainties in physical parameters such as surface albedo and emissivity, the solar constant, and the model top height, rather than structural flaws in the model physics. Importantly, the PWRF reproduces the observations more accurately when the observed soil moisture is fed into the simulation. This indicates that there must be improvements in simulations of the land-atmosphere interaction at the Arctic tundra, not only in the accuracy of the initial soil moisture conditions but also in soil hydraulic properties and drainage processes. The mixing diagram analysis also shows that the entrainment process between the PBL and the overlying atmosphere needs to be improved for better weather and climate simulation. Our findings shed light on modeling studies in the Arctic region by disentangling the model error sources from uncertainties by parameters and physics package options.

Keywords

Polar WRF
Arctic tundra
Land-atmosphere interaction
Surface energy balance
Soil moisture
Planetary boundary layer

Cited by (0)

1

Current affiliation: Korea Atomic Energy Research Institute, Daejeon, Republic of Korea.

2

Current affiliation: Max Planck Institute for Meteorology, Hamburg, Germany.