* Astronomy

Long-term climate records are a key to understanding how Earth's climate changed in the past and how it may change in the future. Direct measurements of light energy emitted by the sun, taken by satellites and other modern scientific techniques, suggest variations in the sun's activity influence Earth's long-term climate. However, there were no measured climate records of this type until the relatively recent scientific past.
Scientists have traditionally relied upon indirect data gathering methods to study climate in the Earth's past, such as drilling ice cores in Greenland and Antarctica. Such samples of accumulated snow and ice drilled from deep within ice sheets or glaciers contain trapped air bubbles whose composition can provide a picture of past climate conditions. Now, however, a group of NASA and university scientists has found a convincing link between long-term solar and climate variability in a unique and unexpected source: directly measured ancient water level records of the Nile, Earth's longest river.
Alexander Ruzmaikin and Joan Feynman of NASA's Jet Propulsion Laboratory, Pasadena, Calif., together with Dr. Yuk Yung of the California Institute of Technology, Pasadena, Calif., have analysed Egyptian records of annual Nile water levels collected between 622 and 1470 A.D. at Rawdah Island in Cairo. These records were then compared to another well-documented human record from the same time period: observations of the number of auroras reported per decade in the Northern Hemisphere. Auroras are bright glows in the night sky that happen when mass is rapidly ejected from the sun's corona, or following solar flares. They are an excellent means of tracking variations in the sun's activity.
Feynman said that while ancient Nile and auroral records are generally "spotty," that was not the case for the particular 850-year period they studied.

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The Late Maunder Minimum (1675-1704 AD) is a multi-decadal period during which sunspots almost entirely disappeared. This lack of solar activity on its surface is generally associated with reduced irradiance. Because of unusually cold conditions, particularly in Western Europe during winter, the Maunder Minimum has often been used as synonymous for the Little Ice Age with the sun being the primary driver of overall conditions. Interestingly, the climate conditions during the Maunder Minimum did not remain cold over the entire period but exhibited a number of very cold, pulse-like episodes of a few years length. While these pulses could be expressions of internal climate variability superposed on a cold baseline, other forcing factors should be considered as well.

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Title: Largest explosive eruption in historical times in the Andes at Huaynaputina Volcano, A.D. 1600, southern Peru
Authors: Jean-Claude Thouret, Jasmine Davila, and Jean-Philippe Eissen

The largest explosive eruption (volcanic explosivity index of 6) in historical times in the Andes took place in A.D. 1600 at Huaynaputina volcano in southern Peru. According to chronicles, the eruption began on February 19 with a Plinian phase and lasted until March 6. Repeated tephra falls, pyroclastic flows, and surges devastated an area 70X40 km² west of the vent and affected all of southern Peru, and earthquakes shook the city of Arequipa 75 km away. Eight deposits, totalling 10.2-13.1 km³ in bulk volume, are attributed to this eruption: (1) a widespread, approximately 8.1 km³ pumice-fall deposit; (2) channelled ignimbrites (1.6-2 km³ ) with (3) ground-surge and ash-cloud-surge deposits; (4) widespread co-ignimbrite ash layers; (5) base-surge deposits; (6) unconfined ash-flow deposits; (7) crystal-rich deposits; and (8) late ash-fall and surge deposits. Disruption of a hydrothermal system and hydromagmatic interactions are thought to have fuelled the large-volume explosive eruption. Although the event triggered no caldera collapse, ring fractures that cut the vent area point to the onset of a funnel-type caldera collapse.

Latitude:, 16.608°S, . Longitude:, 70.85°W

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1600 eruption of Huaynaputina volcano
1783 eruption of Laki volcano
1815 eruption of Tambora volcano

There is no agreed beginning year to the Little Ice Age, although there are a frequently referenced series of events preceding the known climatic minima. Starting in the 13th century, pack ice began advancing southwards in the North Atlantic, as did glaciers in Greenland. The three years of torrential rains beginning in 1315 ushered in an era of unpredictable weather in Northern Europe which did not lift until the 19th century. There is anecdotal evidence of expanding glaciers almost worldwide. In contrast a climate reconstruction based on glacial length shows no great variation from 1600 to 1850, though it shows strong retreat thereafter.

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 Carbon dioxide, a greenhouse gas that has become a bane of modern society, may have saved Earth from freezing over early in the planet's history, according to the first detailed laboratory analysis of the world's oldest sedimentary rocks.
Scientists have theorized for years that high concentrations of greenhouse gases could have helped Earth avoid global freezing in its youth by allowing the atmosphere to retain more heat than it lost. Now a team from the University of Chicago and the University of Colorado at Boulder that analysed ancient rocks from the eastern shore of Hudson Bay in northern Quebec, Canada, have discovered the first direct field evidence supporting this theory.
The study shows carbon dioxide in Earth's atmosphere could have sustained surface temperatures above freezing before 3.75 billion years ago according to the researchers, led by University of Chicago Assistant Professor Nicolas Dauphas. Co-authors on the study, which appeared online Jan. 16 in the journal Earth and Planetary Science Letters, included Assistant Professor Stephen Mojzsis and doctoral student Nicole Cates of CU-Boulder's geological sciences department and Vincent Busigny, now of the Institut de Physique du Globe in Paris.

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A glassy stick made by lightning striking Libyan sands has now been used to date the lightning and detect the ancient climate.
It turns out that the root-like glass "fulgurite" structure made of melted and welded sand from the Libyan Desert contains miniscule bubbles of trapped gases from the time it was made. These gases, carbon dioxide (CO2), carbon monoxide (CO) and nitric oxide (NO) harbour hints of the type of plants that were zapped along with the sandy ground some 15,000 years ago.
Careful analysis of those gases and the weights of the carbon atoms in them reveal the plants were probably the sort which used what’s called C4 photosynthesis — best for plants living in hot, arid climates. This, in turn, implies that the semi-arid Sahel region of today reached much further north during the Pleistocene (1.8 million to 10,000 years ago).
In other words, the Libyan Desert was once a lot less arid than it is today.

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