A whole world's wake-up call

The past few weeks in the world of space have been pretty hectic. Most especially because of the fantastic new views of Pluto we've been receiving, courtesy of the New Horizons flyby (which I wrote about in my last postcard). We've also been hearing about the "frozen primordial soup" of organic compounds detected by the European Space Agency's Philae lander on comet 67P/Churyumov–Gerasimenko, as detailed in a new special issue of Science. Some of these compounds may be important for the prebiotic synthesis of amino acids, sugars, and nucleobases, i.e., the very ingredients of life. 

The surface of comet 67P/Churyumov–Gerasimenko, as imaged from 9 metres away. Credit: ESA

But there are two other recent news items I want to focus on in this postcard. First, the new photograph of the Earth captured by NASA's new Deep Space Climate Observatory (DSCOVR) satellite. And second, the recent discovery of an exoplanet that is being billed as Earth's 'twin'.

On 6 July 2015, the Earth Polychromatic Imaging Camera (EPIC) instrument on DSCOVR returned its first view of the entire sunlit Earth. Safe in its gravitationally stable location one million miles away—at a so-called Lagrange point—the satellite was able to obtain this kind of full-Earth portrait for the first time since the famous 'Blue marble' photograph was snapped by the Apollo 17 astronauts whilst on their way to the Moon in 1972. I've mentioned that older, stunning photo in a previous postcard, but as the most reproduced image in history, I think that it is more than worth showing again.

The famous and historic 'Blue marble', taken during the Apollo 17 mission in 1972. Credit: NASA

It might come as a surprise that it has taken more than 40 years to recapture Earth in a similar view. The pictures you've seen of Earth's full disc in the meantime have either been this Apollo 17 photograph, or composite images (i.e., several smaller images that have been stitched together). It is difficult to obtain these images because many variables come into play. The camera must be between the Earth and the Sun, and far enough away to capture the whole planet in its field of view. Although weather satellites—in geosynchronous orbits—get similar views, they cannot normally see an entire hemisphere without shadow.

The Earth, from one million miles, as seen by the Deep Space Climate Observatory on 6 July 2015. Credit: NASA

The data from EPIC will primarily be used to measure changes to the ozone and aerosol levels in Earth's atmosphere, as well as cloud height, vegetation properties, and ultraviolet reflectivity characteristics. But these new, beautiful, images of a whole Earth remind us how powerful it is to see our entire home in one go. As pointed out by John Grunsfeld, associate administrator of NASA's Science Mission Directorate, "these new views of Earth give us an important perspective of the true global nature of our spaceship Earth."

Indeed, I'm reminded of an excellent book I read several years ago by Robert Poole. In Earthrise: How Man First Saw The Earth, Poole tells the story of how images of Earth—such as the Blue marble and the equally famous Apollo 'Earthrise'—taken during the dawn of the space age, played a huge role in the birth of the now-popular environmental and conservation movements.

'Earthrise' photograph taken by astronaut Bill Anders during the Apollo 8 mission, on 24 December 1968. Credit: NASA

It is another aspect of these images of our blue Earth, however, that strikes me most. It is the human capacity for intelligence and creativity that enables space exploration and capturing of Earth-selfies from afar. Yet we do not see evidence of our presence in these pictures. In many ways, we are invisible to the universe. It is not life that makes Earth special. It is the blue oceans, the green forests, and the white wispy clouds in our lovely oxygen-rich atmosphere that make our world habitable. So for this postcard to our hypothetical alien planetary geologists, I want to send a snapshot of our whole world. Let them see the Earth and all its systems intertwined.

The uniqueness of Earth, however, might be under threat if a new discovery from the Kepler space telescope is anything to go by. On 23 July 2014, scientists working on the Kepler mission announced that they have found the most Earth-like extrasolar planet yet. The new planet—known as Kepler-452b—is located about 1,400 light years away, and is a similar size to Earth. In addition, Kepler-452b orbits a Sun-like star at a distance that is similar to that of Earth around the Sun. The planet is being hailed as "the first possibly rocky, habitable planet around a solar-type star". And it will thus, likely, become the focus of an intense search for extraterrestrial life. Perhaps we'll even find those alien planetary geologists there waiting for us.

Artist's concept of Kepler-452b in orbit around its parent star. Credit: NASA Ames/JPL-Caltech/T.Pyle

At a time when humanity seems to be as fractured as ever, perhaps we need a wake-up call like these ones from NASA. We need to be reminded every once in a while that we are all one family, stuck together here on our little spaceship Earth. We should do our utmost to look after it—and each other.

Wake up and taste the water

Comets have made the news a number of times in recent months. These interplanetary travellers, which were once thought to herald doom, are now known to be among the most primitive objects in the solar system. And of course, comets periodically make visits from the far reaches of the solar system (regions known as the Oort Cloud and the Kuiper belt) to our more local neighbourhood.

Back in December, Comet ISON—the 'comet of the century'—made a much-watched and disappointing suicide plunge into the Sun. And just this week, the European Space Agency successfully 'woke up' its Rosetta spacecraft from its two-and-a-half-year hibernation.

Currently more than 400 million miles away from home, Rosetta is journeying towards the comet 67P/Churyumov-Gerasimenko. Once it arrives, it will first orbit, and then land on the comet's surface. Together, the orbiter and lander portions of the spacecraft are equipped with over 20 scientific instruments that will make important characterizations of the comet. Scientists working on the mission hope to find out if comets such as this, which contain complex organic molecules, may have played a role in seeding life on Earth.

Artist's impression of the European Space Agency's Rosetta spacecraft orbiting the comet 67P/Churyumov-Gerasimenko. Credit: ESA, C.Carreau / ATG medialab

There has also been a long-lived debate over whether or not comets contributed significantly to the delivery, early in its history, of Earth's vast water inventory.

Because water is such a vital ingredient for the sustenance of life here on Earth, we target our search for extraterrestrial life on places where water exists. Water therefore seems like a pretty obvious choice for an Earth-material to send as one of our interplanetary postcards. But how might an alien scientist be able to tell our Earth-water apart from any other foreign H₂O? We all know that water can vary drastically in its colour, salinity, taste, etc. So is there a characteristic signature of our water that portrays its Earthly provenance?

Earth: A water world. Credit: NASA

Lucky for us, chemistry has an answer. Hydrogen (H), like all elements is defined by the number of protons it contains. 'Normal' hydrogen contains just one proton in its nucleus. However, it is possible for a stable hydrogen atom to contain one or two neutrons in addition to the lone proton. The hydrogen isotope that has one proton and one neutron is known as deuterium (D). Heavy water is enriched in molecules that contain deuterium in place of the normal hydrogen.

Planetary scientists have shown that D/H ratios in water vary throughout the solar system. Measurements for a number of Oort Cloud comets reveal that they have D/H ratios which are more than twice the value for Earth's oceans, and are thus unlikely to have been the source of water on our planet.

Range of deuterium/hydrogen (D/H) ratios in solar system objects.
Credit: A. E. Saal et al. 2013, Science

Paul Hartogh and colleagues, however, showed in 2011 that a Jupiter-family comet (103P / Hartley 2), which probably originated from the Kuiper belt, has a D/H ratio that is much more consistent with that of Earth. This means that at least some of Earth's water may have been delivered by comets. Although in more recent work, Conel Alexander et al. argue that CI chondrites (the class of meteorite whose composition most closely resembles that of the Sun) were the principal source of terrestrial water.

And so the great water debate continues.  But no matter how, and from where, the water got here; get here it did. And we wouldn't be alive without it.