EFFECT OF DEEP-SEA SEDIMENTARY CALCITE PRESERVATION ON ATMOSPHERIC CO2 CONCENTRATION

被引：438

作者：

ARCHER, D

MAIERREIMER, E

机构：

[1] COLUMBIA UNIV, PALISADES, NY 10964 USA

[2] MAX PLANCK INST METEOROL, W-2000 HAMBURG 54, GERMANY

来源：

NATURE | 1994年 / 367卷 / 6460期

关键词：

D O I：

10.1038/367260a0

中图分类号：

O [数理科学和化学]; P [天文学、地球科学]; Q [生物科学]; N [自然科学总论];

学科分类号：

07 ; 0710 ; 09 ;

摘要：

DURING the last glaciation, the atmospheric carbon dioxide concentration was about 30% less than the Holocene pre-industrial value1. Although this change is thought to originate in oceanic processes2, the mechanism is still unclear. On timescales of thousands of years, the pH of the ocean (and hence the atmospheric CO2 concentration) is determined by a steady-state balance between the supply rate of calcium carbonate to the ocean from terrestrial weathering, and the alteration and removal of carbonate by burial in sediments2-4 . Degradation of organic carbon in sediments promotes the dissolution of calcium carbonate in sedimentary pore water5,6, so that a change in the relative rates at which organic carbon and calcium carbonate are deposited on the sea floor should drive a compensating change in ocean pH. Here we use a model that combines ocean circulation, carbon cycling and other sedimentary processes to explore the relationship between deep-sea-sediment chemistry and atmospheric CO2 concentration. When we include organic-carbon-driven dissolution in our model, a 40% decrease in the calcite deposition rate is enough to decrease the atmospheric CO2 Concentration to the glacial value.

引用

页码：260 / 263

页数：4

共 36 条

[1] MODELING THE CALCITE LYSOCLINE [J].

ARCHER, D .

JOURNAL OF GEOPHYSICAL RESEARCH-OCEANS, 1991, 96 (C9) :17037-17050

[2] DISSOLUTION OF CALCITE IN DEEP-SEA SEDIMENTS - PH AND O-2 MICROELECTRODE RESULTS [J].

ARCHER, D ;

EMERSON, S ;

REIMERS, C .

GEOCHIMICA ET COSMOCHIMICA ACTA, 1989, 53 (11) :2831-2845

[3]

Bacastow R, 1990, CLIM DYNAM, V4, P95, DOI [10.1007/BF00208905, DOI 10.1007/BF00208905]

[4] VOSTOK ICE CORE PROVIDES 160,000-YEAR RECORD OF ATMOSPHERIC CO2 [J].

BARNOLA, JM ;

RAYNAUD, D ;

KOROTKEVICH, YS ;

LORIUS, C .

NATURE, 1987, 329 (6138) :408-414

[5] DISTRIBUTION OF CARBONATE IN SURFACE SEDIMENTS OF PACIFIC OCEAN [J].

BERGER, WH ;

ADELSECK, CG ;

MAYER, LA .

JOURNAL OF GEOPHYSICAL RESEARCH-OCEANS AND ATMOSPHERES, 1976, 81 (15) :2617-2627

[6] INCREASE OF CARBON-DIOXIDE IN THE ATMOSPHERE DURING DEGLACIATION - THE CORAL-REEF HYPOTHESIS [J].

BERGER, WH .

NATURWISSENSCHAFTEN, 1982, 69 (02) :87-88

[7]

BERGER WH, 1984, CLIMATE PROCESSES CL, P337

[8] DISTRIBUTION OF CALCIUM-CARBONATE IN SURFACE SEDIMENTS OF ATLANTIC OCEAN [J].

BISCAYE, PE ;

KOLLA, V ;

TUREKIAN, KK .

JOURNAL OF GEOPHYSICAL RESEARCH-OCEANS AND ATMOSPHERES, 1976, 81 (15) :2595-2603

[9] VERTICAL OCEANIC NUTRIENT FRACTIONATION AND GLACIAL INTERGLACIAL CO2 CYCLES [J].

BOYLE, EA .

NATURE, 1988, 331 (6151) :55-56

[10] THE ROLE OF CaCO3 COMPENSATION THE GLACIAL TO INTERGLACIAL ATMOSPHERIC CO2 CHANGE [J].

Broecker, Wallace ;

Peng, Tsung-Hung .

GLOBAL BIOGEOCHEMICAL CYCLES, 1987, 1 (01) :15-29

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