Imprint of Galactic dynamics on Earth's climate

The Earth’s climate changes naturally on all timescales. At the short end of the spectrum—hours or days—it is affected by sudden events such as volcanic eruptions, which raise the atmospheric temperature directly, and also indirectly, by the addition of greenhouse gases such as water vapour and carbon dioxide. Over years, centuries, and millennia, climate is influenced by changes in ocean currents that, ultimately, are controlled by the geography of ocean basins. On scales of thousands to hundreds of thousands of years, the Earth’s orbit around the Sun is the crucial influence, producing glaciations and interglacials, such as the one in which we live. Longer still, tectonic forces operate over millions of years to produce mountain ranges like the Himalayas and continental rifts such as that in East Africa, which profoundly affect atmospheric circulation, creating deserts and monsoons. Over tens to hundreds of millions of years, plate movements gradually rearrange the continents, creating new oceans and destroying old ones, making and breaking land and sea connections, assembling and disassembling supercontinents, resulting in fundamental changes in heat transport by ocean currents. Finally, over the very long term—billions of years—climate reflects slow changes in solar luminosity as the planet heads towards a fiery Armageddon. All but two of these controls are direct or indirect consequences of plate tectonics.

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From “Inconvenient Truth” to Effective Governance

10.1093/oso/9780198805373.003.0008 ◽

2018 ◽

Author(s):

Richard Passarelli ◽

David Michel ◽

William Durch

Keyword(s):

Climate Change ◽

Global Climate ◽

Climate System ◽

Global Public Good ◽

Environmental Groups ◽

Quarter Century ◽

Effective Governance ◽

Political Response ◽

Earth’S Climate ◽

National Governments

The Earth’s climate system is a global public good. Maintaining it is a collective action problem. This chapter looks at a quarter-century of efforts to understand and respond to the challenges posed by global climate change and why the collective political response, until very recently, has seemed to lag so far behind our scientific knowledge of the problem. The chapter tracks the efforts of the main global, intergovernmental process for negotiating both useful and politically acceptable responses to climate change, the UN Framework Convention on Climate Change, but also highlights efforts by scientific and environmental groups and, more recently, networks of sub-national governments—especially cities—and of businesses to redefine interests so as to meet the dangers of climate system disruption.

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Collection of Environmental Variables and Bacterial Community Compositions in Marian Cove, Antarctica, during Summer 2018

Data ◽

10.3390/data6030027 ◽

2021 ◽

Vol 6 (3) ◽

pp. 27

Author(s):

Hyo-Ryeon Kim ◽

Jae-Hyun Lim ◽

Ju-Hyoung Kim ◽

Il-Nam Kim

Keyword(s):

Bacterial Community ◽

Community Composition ◽

Marine Bacteria ◽

Environmental Variables ◽

Environmental Changes ◽

Bacterial Community Composition ◽

Composition Data ◽

Decomposition Of Organic Matter ◽

Class Level ◽

Earth’S Climate

Marine bacteria, which are known as key drivers for marine biogeochemical cycles and Earth’s climate system, are mainly responsible for the decomposition of organic matter and production of climate-relevant gases (i.e., CO₂, N₂O, and CH₄). However, research is still required to fully understand the correlation between environmental variables and bacteria community composition. Marine bacteria living in the Marian Cove, where the inflow of freshwater has been rapidly increasing due to substantial glacial retreat, must be undergoing significant environmental changes. During the summer of 2018, we conducted a hydrographic survey to collect environmental variables and bacterial community composition data at three different layers (i.e., the seawater surface, middle, and bottom layers) from 15 stations. Of all the bacterial data, 17 different phylum level bacteria and 21 different class level bacteria were found and Proteobacteria occupy 50.3% at phylum level following Bacteroidetes. Gammaproteobacteria and Alphaproteobacteria, which belong to Proteobacteria, are the highest proportion at the class level. Gammaproteobacteria showed the highest relative abundance in all three seawater layers. The collection of environmental variables and bacterial composition data contributes to improving our understanding of the significant relationships between marine Antarctic regions and marine bacteria that lives in the Antarctic.

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Analysis of the possibility and molecular mechanism of carbon dioxide consumption in the Diels-Alder processes

Pure and Applied Chemistry ◽

10.1515/pac-2020-1009 ◽

2021 ◽

Vol 0 (0) ◽

Author(s):

Karolina Kula ◽

Agnieszka Kącka-Zych ◽

Agnieszka Łapczuk-Krygier ◽

Radomir Jasiński

Keyword(s):

Carbon Dioxide ◽

Molecular Mechanism ◽

Lewis Acids ◽

Chemical Reactivity ◽

Carbon Dioxide Concentration ◽

Diels Alder ◽

Wide Range ◽

Bet Analysis ◽

Earth’S Climate ◽

Step Mechanism

Abstract The large and significant increase in carbon dioxide concentration in the Earth’s atmosphere is a serious problem for humanity. The amount of CO2 is increasing steadily which causes a harmful greenhouse effect that damages the Earth’s climate. Therefore, one of the current trends in modern chemistry and chemical technology are issues related to its utilization. This work includes the analysis of the possibility of chemical consumption of CO2 in Diels-Alder processes under non-catalytic and catalytic conditions after prior activation of the C=O bond. In addition to the obvious benefits associated with CO2 utilization, such processes open up the possibility of universal synthesis of a wide range of internal carboxylates. These studies have been performed in the framework of Molecular Electron Density Theory as a modern view of the chemical reactivity. It has been found, that explored DA reactions catalyzed by Lewis acids with the boron core, proceeds via unique stepwise mechanism with the zwitterionic intermediate. Bonding Evolution Theory (BET) analysis of the molecular mechanism associated with the DA reaction between cyclopentadiene and carbon dioxide indicates that it takes place thorough a two-stage one-step mechanism, which is initialized by formation of C–C single bond. In turn, the DA reaction between cyclopentadiene and carbon dioxide catalysed by BH3 extends in the environment of DCM, indicates that it takes place through a two-step mechanism. First path of catalysed DA reaction is characterized by 10 different phases, while the second by eight topologically different phases.

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Snowfall-albedo feedbacks could have led to deglaciation of snowball Earth starting from mid-latitudes

Communications Earth & Environment ◽

10.1038/s43247-021-00160-4 ◽

2021 ◽

Vol 2 (1) ◽

Author(s):

Philipp de Vrese ◽

Tobias Stacke ◽

Jeremy Caves Rugenstein ◽

Jason Goodman ◽

Victor Brovkin

Keyword(s):

Carbon Dioxide ◽

Atmospheric Carbon Dioxide ◽

Climate Models ◽

Hydrological Cycle ◽

High Surface ◽

Dust Deposition ◽

Carbon Dioxide Concentrations ◽

Maximum Temperatures ◽

Carbon Dioxide Levels ◽

Earth’S Climate

AbstractSimple and complex climate models suggest a hard snowball – a completely ice-covered planet – is one of the steady-states of Earth’s climate. However, a seemingly insurmountable challenge to the hard-snowball hypothesis lies in the difficulty in explaining how the planet could have exited the glaciated state within a realistic range of atmospheric carbon dioxide concentrations. Here, we use simulations with the Earth system model MPI-ESM to demonstrate that terminal deglaciation could have been triggered by high dust deposition fluxes. In these simulations, deglaciation is not initiated in the tropics, where a strong hydrological cycle constantly regenerates fresh snow at the surface, which limits the dust accumulation and snow aging, resulting in a high surface albedo. Instead, comparatively low precipitation rates in the mid-latitudes in combination with high maximum temperatures facilitate lower albedos and snow dynamics that – for extreme dust fluxes – trigger deglaciation even at present-day carbon dioxide levels.

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Atlantic Niño/Niña Prediction Skills in NMME Models

Atmosphere ◽

10.3390/atmos12070803 ◽

2021 ◽

Vol 12 (7) ◽

pp. 803

Author(s):

Ran Wang ◽

Lin Chen ◽

Tim Li ◽

Jing-Jia Luo

Keyword(s):

Sea Surface ◽

Prediction Skill ◽

Boreal Summer ◽

Boreal Winter ◽

Equatorial Atlantic ◽

Multimodel Ensemble ◽

Spring Predictability Barrier ◽

Anomaly Correlation Coefficient ◽

Earth’S Climate ◽

Atlantic Niño

The Atlantic Niño/Niña, one of the dominant interannual variability in the equatorial Atlantic, exerts prominent influence on the Earth’s climate, but its prediction skill shown previously was unsatisfactory and limited to two to three months. By diagnosing the recently released North American Multimodel Ensemble (NMME) models, we find that the Atlantic Niño/Niña prediction skills are improved, with the multi-model ensemble (MME) reaching five months. The prediction skills are season-dependent. Specifically, they show a marked dip in boreal spring, suggesting that the Atlantic Niño/Niña prediction suffers a “spring predictability barrier” like ENSO. The prediction skill is higher for Atlantic Niña than for Atlantic Niño, and better in the developing phase than in the decaying phase. The amplitude bias of the Atlantic Niño/Niña is primarily attributed to the amplitude bias in the annual cycle of the equatorial sea surface temperature (SST). The anomaly correlation coefficient scores of the Atlantic Niño/Niña, to a large extent, depend on the prediction skill of the Niño3.4 index in the preceding boreal winter, implying that the precedent ENSO may greatly affect the development of Atlantic Niño/Niña in the following boreal summer.

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