TEXT F Eight times within the
past million years, something in the Earth’s climatic equation has changed,
allowing snow in the mountains and the northern latitudes to accumulate from one
season to the next instead of melting away each time. The enormous ice sheets
resulting from this continual buildup lasted tens of thousands of years until
the end of each particular glacial cycle brought a warmer climate. Scientists
speculated that these glacial cycles were ultimately driven by astronomical
factors: slow cyclic changes in the eccentricity of the Earth’s orbit and in the
tilt and orientation of its spin axis. But up until around 30 years ago, the
lack of an independent record of ice age timing made the hypothesis
untestable. Then in the early 1950s Emiliani produced the first
complete record of the waxings and wanings of past glaciations. It came from a
seemingly odd place. The seafloor single-cell marine organisms called
"foraminifera" house themselves in shells made from calcium carbonate. When the
foraminifera die, sink to the bottom, and become part of seafloor sediments, the
carbonate of their shells preserves certain characteristics of the
seawater they inhabited. In particular, the ratio of a heavy isotope of oxygen
(oxygen-18) to ordinary oxygen (oxygen-16) in the carbonate preserves the ratio
of the two oxygens in water molecules. It is now understood that
the ratio of oxygen isotopes in seawater closely reflects the proportion of the
world’s water locked up in glaciers and ice sheets. A kind of meteorological
distillation accounts for the link. Water molecules containing the heavier
isotope tend to condense and fall as precipitation slightly sooner than
molecules containing the lighter isotope. Hence, as water vapor evaporated from
warm oceans moves away from its source, its oxygen-18 returns more quickly to
the oceans than does its oxygen-16. What falls as snow on distant ice sheets and
mountain glaciers is relatively depleted of oxygen-18. As the oxygen-18-poor ice
builds up the oceans become relatively enriched in the isotope. The larger the
ice sheets grow, the higher the proportion of oxygen-I 8 becomes in seawater—and
hence in the sediments. Analyzing cores drilled from seafloor
sediments, Emiliani found that the isotopic ratio rose and fell in rough accord
with the Earth’s astronomical cycles. Since that pioneering observation,
oxygen-isotope measurements have been made on hundreds of cores. A chronology
for the combined record enables scientists to show that the record contains the
very same periodicities as the orbital processes. Over the past 800,000 years,
the global ice volume has peaked every 100,000 years, matching the period of the
orbital eccentricity variation. In addition, "wrinkles" superposed on each
cycle-small-decrease or surge in ice volume have come at intervals of roughly
23,000 and 41, 000 years, in keeping with the precession and tilt frequencies of
the Earth’s spin axis. Which of the following best expresses the main idea of the passage
A.Marine sediments have allowed scientists to amass evidence tending to confirm that astronomical cycles drive the Earth’s glacial cycles. B.The ratio between two different isotopes of oxygen in seawater correlates closely with the size of the Earth’s ice sheets. C.Surprisingly, single-cell marine organisms provide a record of the Earth’s ice ages. D.The Earth’s astronomical cycles have recently been revealed to have an unexpectedly large impact on the Earth’s climate.