{"id":145906,"date":"2015-03-09T14:18:36","date_gmt":"2015-03-09T13:18:36","guid":{"rendered":"http:\/\/www.madrimasd.org\/blogs\/universo\/?p=145906"},"modified":"2015-03-09T14:18:36","modified_gmt":"2015-03-09T13:18:36","slug":"erosion-fria","status":"publish","type":"post","link":"https:\/\/www.madrimasd.org\/blogs\/universo\/2015\/03\/09\/145906","title":{"rendered":"Erosi\u00f3n Fr\u00eda"},"content":{"rendered":"

\"glaciares-de-las-rias-en-patagonia\"<\/p>\n

Glaciares desembocando en las R\u00edas Patag\u00f3nicas (Chile); Foto. Juan Jos\u00e9 Ib\u00e1\u00f1ez<\/span><\/p>\n

El post de hoy nos habla de <\/span>la erosi\u00f3n fr\u00eda<\/span><\/span><\/strong>, que no de la <\/span>fusi\u00f3n fr\u00eda<\/span><\/a>, tema que escapa a nuestras competencias. Se trata de un breve art\u00edculo publicado <\/span>en Investigaci\u00f3n y Ciencia<\/span><\/a>, partiendo de otro previo aparecido en las p\u00e1ginas de <\/span>Nature<\/span><\/a>.<\/span><\/p>\n

El encabezamiento del t\u00edtulo\u00a0<\/span>en Investigaci\u00f3n y Ciencia<\/span><\/a>, comienza as\u00ed, resumiendo perfectamente el contenido de estos estudios: <\/span>Erosi\u00f3n por enfriamiento. La historia t\u00e9rmica de miles de rocas avala la idea de que el enfriamiento clim\u00e1tico de los \u00faltimos millones de a\u00f1os aceler\u00f3 la erosi\u00f3n de la superficie terrestre<\/em><\/span>.<\/span><\/strong> Con tal motivo se hace uso de <\/span>cron\u00f3metros<\/span><\/a> t\u00e9rmicos o m\u00e1s concretamente de sus <\/span>m\u00e9todos de dataci\u00f3n<\/span><\/a> en geolog\u00eda (<\/span>geotermocronolog\u00eda<\/span><\/a>). Abajo os a\u00f1adimos el inicio de los contenidos en acceso abierto que permite\u00a0Investigaci\u00f3n y Ciencia. Seguidamente incluimos la <\/span>Nota de Prensa de ScienceDaily<\/span><\/a>, para finalizar con una sucinta descripci\u00f3n sobre la <\/span>geotermocronolog\u00eda<\/span><\/a> procedente de Wikipedia. El estudio ha sido realizado en diversas partes del mundo y \u201cparece\u201d bastante serio, aunque personalmente <\/span>dudo que finiquite el debate acerca de si el relieve terrestre obedece<\/strong><\/span> fundamentalmente a la <\/span>orog\u00e9nesis<\/span><\/a> (que incluye formaci\u00f3n de monta\u00f1as) causada por la <\/span>tect\u00f3nica de placas<\/span><\/a>, <\/span>o si por el contrario resulta ser el clima el factor que<\/strong> controla la fisiograf\u00eda del globo terr\u00e1queo.\u00a0<\/span><\/span>Esta forma de\u00a0crear\u00a0<\/strong><\/span>antinomias<\/span><\/a> (contextuales)\u00a0<\/span>\u00a0se me antoja\u00a0fortunada<\/span><\/span><\/strong>. <\/span><\/p>\n

Los autores detectan que <\/span>la producci\u00f3n de sedimentos y la erosi\u00f3n monta\u00f1osa resultan ser mucho mayores bajo climas fr\u00edos que c\u00e1lidos, siendo muy elevada en diversos sistemas monta\u00f1osos del mundo durante los periodos g\u00e9lidos de los \u00faltimos seis millones de a\u00f1o<\/strong><\/span>s<\/span>, en los que la actividad tect\u00f3nica era muy variable en los diferentes enclaves analizados por toda la superficie terrestre. Por tanto <\/span>refuerza la hip\u00f3tesis clim\u00e1tica frente a la tect\u00f3nica, si bien no considero que sea el punto fuerte del mensaje de los autores que, en todo caso, cabr\u00eda matizar<\/strong><\/span>. <\/span>\u00a0<\/span>\u00a0<\/span><\/p>\n

Nadie duda del enorme poder erosivo de las masas de hielo, es decir de la <\/span>erosi\u00f3n glaciar<\/span><\/a>. De confirmarse los resultados obtenidos por los investigadores implicados en el estudio, <\/span>el rebajamiento del relieve ser\u00eda mayor durante los periodos g\u00e9lidos, rebajando las cimas de las altas monta\u00f1as y depositando los sedimentos de suelo, regolitos y rocas a menores altitudes<\/strong><\/span>. Eso s\u00ed, si la <\/span>alteraci\u00f3n f\u00edsica<\/span><\/a> de las rocas resulta ser enorme,\u00a0<\/span>al contrario ocurre con la qu\u00edmica<\/span><\/a>, que <\/span>necesita de ambientes m\u00e1s calentitos y h\u00famedos con vistas a que puedan producirse las los procesos de intemperizaci\u00f3n que transforman las rocas en suelos<\/span><\/span><\/strong>. <\/span>\u00a0<\/span><\/p>\n

En consecuencia, podr\u00eda inferirse que <\/span>una alternancia de periodos fr\u00edos y c\u00e1lidos ser\u00eda un ciclo inmejorable \u00a0con vistas a alterar la superficie terrestre y rebajar sus relieves<\/strong><\/span>. Esto es justamente lo acaecido en los \u00faltimos millones de a\u00f1os y especialmente en el <\/span>Pleistoceno<\/span><\/a>. <\/span>Sin embargo<\/strong><\/span>, que yo sepa, la comunidad cient\u00edfica sigue defendiendo que <\/span>la actividad tect\u00f3nica ha sufrido \u00e9pocas de intensa y baja actividad, en lo que concierne a la elevaci\u00f3n de las monta\u00f1as<\/strong><\/span>, hecho que, hoy por hoy, no puede soslayarse. Por lo tanto<\/span>, este tipo de controversias \u201cblanco-negro\u201d, \u201cmucho-poco, bueno-malo\u201d\u00a0me parecen soberanamente\u00a0in\u00fatiles<\/span><\/span><\/strong>. <\/span><\/p>\n

A pesar de todo creo que la nota de prensa atesora gran inter\u00e9s<\/strong> <\/span>de confirmarse que este tipo de periodos geol\u00f3gicos alternantes (fr\u00edos\/c\u00e1lidos) aceleran la transformaci\u00f3n y rebajamiento del relieve terrestre, estando actualmente inmersos en uno de ellos. Os dejo pues con la informaci\u00f3n aludida con vistas a que los interesados abunden \u201cun poco m\u00e1s\u201d en el tema\u201d.<\/span><\/p>\n

Juan Jos\u00e9 Ib\u00e1\u00f1ez<\/strong><\/span><\/p>\n

<\/p>\n

Erosi\u00f3n por enfriamiento<\/strong><\/span> (T\u00edtulo Original Mundo Cient\u00edfico Agosto 2014)<\/span> Por <\/span>David Lundbek Egholm, <\/span>Investigaci\u00f3n y ciencia<\/span><\/a>, Agosto 2014<\/span><\/p>\n

Resumen Acceso Abierto en Investigaci\u00f3n y Ciencia (Erosi\u00f3n por enfriamiento)<\/span><\/a><\/p>\n

Worldwide acceleration of mountain erosion under a cooling climate<\/span><\/a>. <\/span>Fr\u00e9d\u00e9ric Herman et al. en Nature, vol. 504, p\u00e1gs. 423-426. diciembre de 2013<\/span><\/p>\n

La historia t\u00e9rmica de miles de rocas avala la idea de que el enfriamiento clim\u00e1tico de los \u00faltimos millones de a\u00f1os aceler\u00f3 la erosi\u00f3n de la superficie terrestre<\/span><\/strong>.<\/span><\/p>\n

Seg\u00fan un estudio publicado hace unos meses <\/span>en Nature por Fr\u00e9d\u00e9ric Herman<\/span><\/a>, de la Universidad de Lausana, sobre la <\/span>tasa de erosi\u00f3n de varias cadenas monta\u00f1osas<\/span><\/strong>, <\/span>el enfriamiento global acontecido<\/span><\/strong> a lo largo de los \u00faltimos seis millones de <\/span>a\u00f1os aceler\u00f3 la degradaci\u00f3n de las cordilleras<\/span><\/strong>. Sus resultados reavivan <\/span>un largo debate que vincula clima, topograf\u00eda y tect\u00f3nica de placas<\/span><\/strong>.<\/span><\/p>\n

La elevada topograf\u00eda de las cadenas monta\u00f1osas responde a la lenta colisi\u00f3n entre placas continentales<\/span><\/strong>, gobernada a su vez por la din\u00e1mica de la <\/span>tect\u00f3nica de placas<\/span><\/a>. Por otro lado, <\/span>la erosi\u00f3n ejercida por r\u00edos, glaciares y deslizamientos contrarresta los procesos de formaci\u00f3n de monta\u00f1as, ya que desmenuza el sustrato rocoso y transporta los sedimentos resultantes hacia regiones de menor altitud<\/span><\/strong>, como las cuencas sedimentarias o los oc\u00e9anos. As\u00ed pues, la estructura de las cadenas monta\u00f1osas obedece a un complejo balance de procesos constructivos y destructivos.<\/span><\/p>\n

Por m\u00e1s que hoy podamos medir los cambios topogr\u00e1ficos recientes mediante el <\/span>Sistema de Posicionamiento Global (GPS),<\/span><\/a> averiguar lo acontecido en el pasado y obtener datos que abarquen las enormes escalas de tiempo asociadas supone una meta muy ambiciosa. Por ello, <\/span>la influencia que ejerce el clima en los procesos erosivos y, por tanto, en la elevaci\u00f3n y la morfolog\u00eda de las cadenas monta\u00f1osas constituye a\u00fan un misterioso<\/span><\/strong> interrogante.<\/span><\/p>\n

Cron\u00f3metros t\u00e9rmicos<\/span><\/strong><\/p>\n

Hace unos seis millones de a\u00f1os, el clima terrestre entr\u00f3 en una pronunciada fase de enfriamiento que provoc\u00f3 glaciaciones tanto en cadenas monta\u00f1osas elevadas como en latitudes altas. <\/span>La historia t\u00e9rmica de miles de rocas avala la idea de que el enfriamiento clim\u00e1tico de los \u00faltimos millones de a\u00f1os aceler\u00f3 la erosi\u00f3n de la superficie terrestre\u2026\u2026\u2026..<\/span><\/p>\n

De acuerdo a Wikipedia<\/span><\/a>.<\/span><\/p>\n

La <\/span>termocronolog\u00eda <\/span><\/strong>es <\/span><\/strong>el estudio de la evoluci\u00f3n t\u00e9rmica de una regi\u00f3n de un planeta. Los termocronologistas utilizan la <\/span>dataci\u00f3n radiom\u00e9trica<\/a> con las temperaturas de cierre que representan la temperatura de los minerales estudiados en un tiempo determinado por los datos registrados para entender la historia t\u00e9rmica de una roca espec\u00edfica, mineral o unidad geol\u00f3gica. Es un subcampo de la <\/span>geolog\u00eda<\/a> y est\u00e1 estrechamente asociada con la geocronolog\u00eda.<\/span><\/p>\n

Un estudio termocronol\u00f3gico t\u00edpico incluye<\/span><\/strong> las fechas de una serie de muestras de rocas de diferentes \u00e1reas de una regi\u00f3n, a menudo procedentes de un transecto vertical a lo largo de un ca\u00f1\u00f3n empinado, acantilado o pendiente. Estas muestras se fechan. Con algunos conocimientos acerca de la estructura t\u00e9rmica del subsuelo<\/strong>, estas fechas se trasladan a los momentos en que ese lugar en particular estaba a temperatura de cierre del mineral. Esto por lo tanto da el rango de extracci\u00f3n de la roca.<\/span><\/p>\n

Algunos sistemas isot\u00f3picos usados com\u00fanmente en termocronolog\u00eda incluyen huellas de fisi\u00f3n en <\/span>circ\u00f3n<\/a> y <\/span>apatita<\/a>, <\/span>dataci\u00f3n potasio-arg\u00f3n<\/a> y dataci\u00f3n arg\u00f3n-arg\u00f3n en apatita, dataci\u00f3n uranio-torio-helio en circ\u00f3n y apatita, y dataci\u00f3n <\/span>4<\/span><\/sup>He\/<\/span>3<\/span><\/sup>He<\/span><\/p>\n

Worldwide acceleration of mountain erosion under a cooling climate<\/span><\/a>. <\/span>Fr\u00e9d\u00e9ric Herman et al. en Nature, vol. 504, p\u00e1gs. 423-426. diciembre de 2013<\/span><\/p>\n

Summary en Nature del trabajo previo de 2013<\/strong><\/span><\/p>\n

Climate influences the erosion<\/span><\/strong> processes acting at the Earth\u2019s surface. However, the effect of cooling during the <\/span>Late Cenozoic era, including the onset of Pliocene\u2013Pleistocene Northern Hemisphere glaciation<\/span><\/strong> (about two to three million years ago), on global erosion rates remains unclear. <\/span>The uncertainty arises mainly from a lack of consensus on the use of the sedimentary record as a proxy for erosion and the difficulty of isolating the respective contributions of tectonics and climate to erosion<\/span><\/strong>. Here we compile 18,000 bedrock <\/span>thermochronometric ages<\/span><\/a> from around the world and use a formal inversion procedure to <\/span>estimate temporal and spatial variations in erosion rates<\/span><\/strong>. This <\/span>allows for the quantification of erosion for the source areas that ultimately produce the sediment record on a timescale of millions of years<\/span><\/strong>. We find that <\/span>mountain erosion rates have increased since about six million years ago and most rapidly since two million years ago<\/span><\/strong>. The increase of erosion rates is observed <\/span>at all latitudes, but is most pronounced in glaciated mountain<\/span><\/strong> ranges, indicating that glacial processes played an important part. <\/span>Because mountains represent a considerable fraction of the global production of sediments, our results imply an increase in sediment flux at a global scale that coincides closely with enhanced cooling during the Pliocene and Pleistocene epochs.<\/span><\/strong><\/p>\n

Nota de Prensa de ScienceDaily<\/span><\/a><\/strong><\/p>\n

Mountain erosion accelerates under a cooling climate<\/span><\/p>\n

Date: December 18, 2013; <\/span>Source: Universitaet T\u00fcbingen<\/span><\/p>\n

Summary: <\/span><\/strong>The Earth\u2019s continental topography reflects the balance between tectonics, climate, and their interaction through erosion. However, understanding the <\/span>impact of individual factors on Earth\u2019s topography remains elusive<\/span><\/strong>. Scientists have now investigated the effect of global cooling and glaciation on topogrpahy over the last two to three million years. Their data show that mountain erosion rates have increased since circa 6 million years and most rapidly in the last 2 million years. Moreover, alpine glaciers play a significant role in the increase of erosion rates under a cool climate.<\/span><\/p>\n

Illustration: The speed of erosion of the Earth. Legend: blue indicates erosion of less than 0.01 mm p.a.; red indicates erosion of more than 7 mm p.a.<\/span><\/p>\n

Credit: Image courtesy of Schweizerischer Nationalfonds zur Foerderung der wissenschaftlichen Forschung<\/span><\/p>\n

Earth’s continental topography reflects the balance between tectonics, climate, and their interaction through erosion. However, understanding the impact of individual factors on Earth’s topography remains elusive. Professor Todd Ehlers of the University of T\u00fcbingen Geoscience Department, in cooperation with international colleagues, has studied the coupling of climate and erosion on a global scale<\/strong>. The scientists investigated the effect of global cooling and glaciation on topogrpahy over the last two to three million years. To quantify erosion, they compiled bedrock thermochronometric data from around the world<\/strong>. Their data show that mountain erosion rates have increased since circa 6 million years and most rapidly in the last 2 million years<\/strong>. Moreover, alpine glaciers play a significant role in the increase of erosion rates under a cool climate. The results are published in the current edition of Nature.<\/span><\/p>\n

The scientists have compiled data from 18,000 rock samples to globally estimate temporal and spatial variations in erosion rates. During mountain erosion rocks travel from about 10 kilometers depth in the crust to the Earth’s surface. During this process, the rocks cool from great depths to the surface. <\/span>Thermochronology <\/span><\/strong>exploits that small quantities of radioactive uranium contained in the rock decay in a time-dependent process. Below a given so-called closure temperature rocks accumulate the products of radioactive decay. In quantifying decay products, scientists are able to calculate the travel time of a rock from a determined depth to the surface and the time elapsed for cooling. Finally, these data can be converted into an erosion rate using sophisticated computer models.<\/span><\/p>\n

The study’s broad approach that uses a global distribution of samples reduces the influence of individual regional tectonic events on the overall study results. The overall global picture that emerged was a strong correlation of erosion rates with the global climate change over the last several million years.<\/span><\/p>\n

\u00abOn a global scale erosion rates span four orders of magnitude in the last eight million years from one hundreth millimeter up to ten millimeters a year,\u00bb Todd Ehlers says. Six million years ago, increase of erosion rates was expressed at all latitudes, but was most pronounced in glaciated mountain ranges, indicating that glaciers played a significant role.<\/span><\/p>\n

Furthermore, <\/span>erosion rates accelerated more in the last two million years with the most substantial changes at latitudes greater than 30\u00b0, for example in the European Alps, Patagonia, Alaska, the South Island of New Zealand and The Coast Mountains of British Columbia. These areas are highly variable in their tectonic activity, but they have in common that they have all been glaciated in the past few million years<\/span><\/strong>. Mountain erosion rates since about six million years ago were increased once more by nearly a factor of two for the Pleistocene compared to the Pliocene. \u00abThis change with increased activity of glaciers and higher sediment flux shows a clear temporal correspondence with further Late Cenozoic cooling,\u00bb Todd Ehlers comments. These results have important implications in general for improving our understanding of the coupling between climate and erosion.<\/span><\/p>\n

\u00a0<\/span>Story Source<\/span><\/strong>: The above story is based on materials provided by Universitaet T\u00fcbingen. Note: Materials may be edited for content and length.<\/span><\/p>\n

\u00a0<\/span>Journal Reference: <\/span><\/strong>Fr\u00e9d\u00e9ric Herman, Diane Seward, Pierre G. Valla, Andrew Carter, Barry Kohn, Sean D. Willett, Todd A. Ehlers. Worldwide acceleration of mountain erosion under a cooling climate. Nature, 2013; 504 (7480): 423 DOI: 10.1038\/nature12877<\/span><\/p>\n","protected":false},"excerpt":{"rendered":"

Glaciares desembocando en las R\u00edas Patag\u00f3nicas (Chile); Foto. Juan Jos\u00e9 Ib\u00e1\u00f1ez El post de hoy nos habla de la erosi\u00f3n fr\u00eda, que no de la fusi\u00f3n fr\u00eda, tema que escapa a nuestras competencias. Se trata de un breve art\u00edculo publicado en Investigaci\u00f3n y Ciencia, partiendo de otro previo aparecido en las p\u00e1ginas de Nature. El encabezamiento del t\u00edtulo\u00a0en Investigaci\u00f3n y Ciencia, comienza as\u00ed, resumiendo perfectamente el contenido de estos estudios: Erosi\u00f3n por enfriamiento. La historia t\u00e9rmica de miles de rocas avala la idea de que el enfriamiento clim\u00e1tico de los \u00faltimos millones de a\u00f1os aceler\u00f3 la erosi\u00f3n de la superficie\u2026<\/p>\n","protected":false},"author":26,"featured_media":0,"comment_status":"open","ping_status":"open","sticky":false,"template":"","format":"standard","meta":{"ngg_post_thumbnail":0},"categories":[603,607,585],"tags":[14204,28051,28056,28053,28052,28055],"blocksy_meta":{"styles_descriptor":{"styles":{"desktop":"","tablet":"","mobile":""},"google_fonts":[],"version":4}},"aioseo_notices":[],"_links":{"self":[{"href":"https:\/\/www.madrimasd.org\/blogs\/universo\/wp-json\/wp\/v2\/posts\/145906"}],"collection":[{"href":"https:\/\/www.madrimasd.org\/blogs\/universo\/wp-json\/wp\/v2\/posts"}],"about":[{"href":"https:\/\/www.madrimasd.org\/blogs\/universo\/wp-json\/wp\/v2\/types\/post"}],"author":[{"embeddable":true,"href":"https:\/\/www.madrimasd.org\/blogs\/universo\/wp-json\/wp\/v2\/users\/26"}],"replies":[{"embeddable":true,"href":"https:\/\/www.madrimasd.org\/blogs\/universo\/wp-json\/wp\/v2\/comments?post=145906"}],"version-history":[{"count":7,"href":"https:\/\/www.madrimasd.org\/blogs\/universo\/wp-json\/wp\/v2\/posts\/145906\/revisions"}],"predecessor-version":[{"id":146802,"href":"https:\/\/www.madrimasd.org\/blogs\/universo\/wp-json\/wp\/v2\/posts\/145906\/revisions\/146802"}],"wp:attachment":[{"href":"https:\/\/www.madrimasd.org\/blogs\/universo\/wp-json\/wp\/v2\/media?parent=145906"}],"wp:term":[{"taxonomy":"category","embeddable":true,"href":"https:\/\/www.madrimasd.org\/blogs\/universo\/wp-json\/wp\/v2\/categories?post=145906"},{"taxonomy":"post_tag","embeddable":true,"href":"https:\/\/www.madrimasd.org\/blogs\/universo\/wp-json\/wp\/v2\/tags?post=145906"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}