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Rapid growth of anthropogenic organic nanoparticles greatly alters cloud life cycle in the Amazon rainforest.

Rahul A ZaveriJian WangJiwen FanYuwei ZhangJohn E ShillingAlla ZelenyukFan MeiRob NewsomMikhail PekourJason M TomlinsonJennifer M ComstockManish ShrivastavaEdward FortnerLuiz A T MachadoPaulo ArtaxoScot T Martin
Published in: Science advances (2022)
Aerosol-cloud interactions remain uncertain in assessing climate change. While anthropogenic activities produce copious aerosol nanoparticles smaller than 10 nanometers, they are too small to act as efficient cloud condensation nuclei (CCN). The mechanisms responsible for particle growth to CCN-relevant sizes are poorly understood. Here, we present aircraft observations of rapid growth of anthropogenic nanoparticles downwind of an isolated metropolis in the Amazon rainforest. Model analysis reveals that the sustained particle growth to CCN sizes is predominantly caused by particle-phase diffusion-limited partitioning of semivolatile oxidation products of biogenic hydrocarbons. Cloud-resolving numerical simulations show that the enhanced CCN concentrations in the urban plume substantially alter the formation of shallow convective clouds, suppress precipitation, and enhance the transition to deep convective clouds. The proposed nanoparticle growth mechanism, expressly enabled by the abundantly formed semivolatile organics, suggests an appreciable impact of anthropogenic aerosols on cloud life cycle in previously unpolluted forests of the world.
Keyphrases
  • climate change
  • life cycle
  • water soluble
  • nitric oxide
  • hydrogen peroxide
  • molecular dynamics
  • risk assessment
  • quantum dots
  • loop mediated isothermal amplification