J. H. Butler scite author profile

Earth's climate is warming as a result of anthropogenic emissions of greenhouse gases, particularly carbon dioxide (CO(2)) from fossil fuel combustion. Anthropogenic emissions of non-CO(2) greenhouse gases, such as methane, nitrous oxide and ozone-depleting substances (largely from sources other than fossil fuels), also contribute significantly to warming. Some non-CO(2) greenhouse gases have much shorter lifetimes than CO(2), so reducing their emissions offers an additional opportunity to lessen future climate change. Although it is clear that sustainably reducing the warming influence of greenhouse gases will be possible only with substantial cuts in emissions of CO(2), reducing non-CO(2) greenhouse gas emissions would be a relatively quick way of contributing to this goal.

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Global distribution of N₂O and the ΔN₂O‐AOU yield in the subsurface ocean

Nevison

Butler²,

Elkins³

2003

Global Biogeochemical Cycles

237

345

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Oceanic distributions and emissions of short‐lived halocarbons

Butler

King

Lobert

et al. 2007

Global Biogeochemical Cycles

205

270

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[1] Using data from seven cruises over a 10-year span, we report marine boundary layer mixing ratios (i.e., dry mole fractions as pmol mol À1 or ppt), degrees of surface seawater saturation, and air-sea fluxes of three short-lived halocarbons that are significant in tropospheric and potentially stratospheric chemistry. CHBr 3 , CH 2 Br 2 , and CH 3 I were all highly supersaturated almost everywhere, all the time. Highest saturations of the two polybrominated gases were observed in coastal waters and areas of upwelling, such as those near the equator and along ocean fronts. CH 3 I distributions reflected the different chemistry and cycling of this gas in both the water and the atmosphere. Seasonal variations in fluxes were apparent where cruises overlapped and were consistent among oceans. Undersaturations of these gases were noted at some locations in the Southern Ocean, owing to mixing of surface and subsurface waters, not necessarily biological or chemical sinks. The Pacific Ocean appears to be a much stronger source of CHBr 3 to the marine boundary layer than the Atlantic. The high supersaturations, fluxes, and marine boundary layer mixing ratios in the tropics are consistent with the suggestion that tropical convection could deliver some portion of these gases and their breakdown products to the upper troposphere and lower stratosphere.

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Atmospheric gas concentrations over the past century measured in air from firn at the South Pole

Battle

Bender

Sowers

et al. 1996

Nature

303

268

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A record of atmospheric halocarbons during the twentieth century from polar firn air

Butler

Battle

Bender

et al. 1999

Nature

239

211

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J. H. Butler

Non-CO2 greenhouse gases and climate change

Global distribution of N₂O and the ΔN₂O‐AOU yield in the subsurface ocean

Oceanic distributions and emissions of short‐lived halocarbons

Atmospheric gas concentrations over the past century measured in air from firn at the South Pole

A record of atmospheric halocarbons during the twentieth century from polar firn air

Contact Info

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Resources

About

J. H. Butler

Non-CO2 greenhouse gases and climate change

Global distribution of N2O and the ΔN2O‐AOU yield in the subsurface ocean

Oceanic distributions and emissions of short‐lived halocarbons

Atmospheric gas concentrations over the past century measured in air from firn at the South Pole

A record of atmospheric halocarbons during the twentieth century from polar firn air

Contact Info

Product

Resources

About

Global distribution of N₂O and the ΔN₂O‐AOU yield in the subsurface ocean