sun – Progress in Research

Stonehenge continues to attract the attention of scholars and researchers more than four millenia after its construction. Giulio Magli, professor at the Politecnico di Milano, and Juan Antonio Belmonte, professor at Instituto de Astrofísica de Canarias and Universidad de La Laguna in Tenerife, have published on Antiquity, authoritative journal of Archaeology, an innovative study which helps explain the monument original function: the theory that Stonehenge was used as a solar calendar is wrong. Its structure instead accounts for a symbolic interest of the builders to the solar cycle, most probably related to the connections between afterlife and winter solstice in Neolithic societies.

Archaeoastronomy, which often uses satellite images to study the orientation of archaelogical sites, has a key role in this interpretation, since Stonehenge exhibits an astronomical alignment to the sun which refers both to the summer solstice sunrise and to the winter solstice sunset.

In the paper, Magli and Belmonte refute the theory that the monument was used as a giant calendrical device, based on 365 days per year divided in 12 months, with the addition of a leap year every four. This calendar is identical to the Alexandrian one, introduced more than two millennia later, at the end of the first century BC as a combination of the Julian calendar and the Egyptian civil calendar. The authors show that this theory is based on a series of forced interpretations of the astronomical connections of the monument, as well as on debatable numerology and on unsupported analogies.

First of all, Magli and Belmonte refer to astronomy: they show that the slow movement of the sun at the horizon in the days close to solstices makes it impossible to control the correct working of the alleged calendar, as the device (remember: composed by huge stones) should be able to distinguish positions as accurate as a few arc minutes, that is, less than 1/10 of one degree.

Second, numerology. Attributing meanings to “numbers” in a monument is always a risky procedure. For example, in this case, a “key number” of the alleged calendar, 12, is not recognizable anywhere.

Finally, cultural paragons. A first elaboration of the 365 plus 1 day calendar is documented in Egypt only two millennia later than Stonehenge (and entered in use further centuries later). Besides, a transfer and elaboration of notions with Egypt occurred around 2600 BC has no archaeological basis.

A new study published in the prestigious journal Nature Communications explains how DNA is protected from mutations caused by ultraviolet light via its constituent elements, nucleosides. The results, obtained by using extremely short pulses of light, may lead to important applications in nanotechnology and pharmacology, such as fighting skin tumours.

The study was conducted by a team of researchers at the Institute for Photonics and Nanotechnology under the National Research Council (CNR-IFN), the Politecnico di Milano, the Università di Bologna, the Università della Tuscia, and Heinrich Heine Universität Düsseldorf.

Studying how nucleosides interact with light on very short timescales is essential for understanding the complex physical processes that lead to DNA photodamage,
Rocío Borrego-Varillas, first author, researcher at the CNR-IFN and the Politecnico di Milano.

Lasers enable incredibly short pulses of light to be generated with a duration of a few millionths or billionths of a second. They also allow us to observe very quick phenomena, such as the fundamental processes that occur when light interacts with living organisms, for example, in vision or photosynthesis.

DNA, the molecule that encodes the information necessary for building proteins, efficiently absorbs the UV component of sunlight, a property common to many biomolecules. Due to the high energy of UV radiation, its absorption may trigger a chain of chemical reactions, with the resulting corruption of information encoded in the sequence of bases (photodamage) and serious consequences (such as skin tumours). Fortunately, in most cases, DNA molecules are able to efficiently dissipate the energy contained in UV light due to a photoprotective process that inhibits damage.

In nucleosides, these processes are particularly efficient due to the speed with which the absorbed energy is dissipated, but it is precisely this speed which makes their study so difficult, something which has long been debated by scientists; hence the idea to use ultra short pulses of light to trigger these processes and follow all the phases in their evolution. The technique was applied to the study of two nucleosides: uridine and methyluridine. By observing molecular processes on such short timescales, the researchers have been able to understand for the first time the mechanism through which nucelosides dissipate the energy deposited by UV light.

The difficulty with studying such fast molecular processes is similar to taking a picture of a car moving at full speed. To prevent the picture from looking fuzzy, a short exposure time is chosen. If we want to capture images of a molecular process that lasts less than a millionth of a second, we need very short flashes of UV light.

Tag: sun

A study reveals one of the mysteries of Stonehenge

Lasers allow discovering how DNA protects itself from sunlight