By Abbas Nazil
The longstanding debate over the origins of Earth’s water has resurfaced with new findings from comet 67P/Churyumov-Gerasimenko.
The recent research challenges earlier conclusions and offers fresh insight into the role comets may have played in delivering water to our planet.
The breakthrough came after a team led by NASA planetary scientist Kathleen Mandt reanalyzed data from the European Space Agency’s Rosetta mission, which studied comet 67P in 2014.
The mission originally found a deuterium-to-hydrogen (D/H) ratio in the comet’s water that was three times higher than that of Earth’s oceans—a figure that seemed to discount comets as a significant water source for Earth.
However, Mandt’s team, using advanced statistical tools and more than 16,000 measurements collected throughout Rosetta’s mission, discovered that earlier readings were skewed by dust interference.
The D/H ratio fluctuated across different parts of the comet’s coma—a cloud of gas and dust surrounding the nucleus—and closely correlated with dust density.
This suggested that dust grains in the coma were carrying deuterium-enriched water, thereby distorting the measurements and not accurately reflecting the comet’s bulk water composition.
As comets near the Sun, their surfaces heat up, causing the release of gas and dust. Water molecules containing deuterium preferentially adhere to dust grains.
These grains, once released into the coma, emit enriched water that temporarily alters the D/H ratio in localized areas.
Mandt’s research showed that as these dust grains lose their deuterium-enriched water further out in the coma, a more accurate picture of the comet’s intrinsic water composition emerges.
These findings have broader implications beyond comet 67P. Laboratory studies support the idea that dust can adsorb deuterium-rich water (HDO), and this phenomenon may be widespread across the solar system.
The research adds a critical layer of complexity to isotopic measurements and highlights the importance of considering dust effects in future cometary missions.
The study also ties into the broader question of solar system formation. Variations in temperature and density in the early protosolar nebula led to differences in isotopic ratios across comets, asteroids, and planetary bodies.
While volcanic activity on early Earth likely contributed to its water inventory, a significant portion may have arrived during a heavy bombardment period about four billion years ago involving both asteroids and comets.
Despite earlier assumptions that asteroids were the main contributors, Jupiter-family comets (JFCs), such as 67P, are again under scrutiny. Other comets, like C/2014 Q2 Lovejoy, have shown variable D/H ratios, indicating isotopic diversity even within single comets.
This variability complicates the picture but also reinforces the need for refined analysis.
Ultimately, Mandt’s findings breathe new life into the theory that comets—despite initial doubts—could still be key players in Earth’s hydrological history.
As new missions continue to probe these icy remnants of the early solar system, scientists edge closer to understanding how Earth became a watery world—and what that means for the potential habitability of planets beyond.