sexta-feira, 4 de setembro de 2015

Process uses light-harvesting nanoparticles, captures energy from 'hot electrons'

 

 

Rice University researchers have demonstrated an efficient new way to capture the energy from sunlight and convert it into clean, renewable energy by splitting water molecules.

Credit: I. Thomann/Rice University

Rice University researchers have demonstrated an efficient new way to capture the energy from sunlight and convert it into clean, renewable energy by splitting water molecules.

The technology, which is described online in the American Chemical Society journal Nano Letters, relies on a configuration of light-activated gold nanoparticles that harvest sunlight and transfer solar energy to highly excited electrons, which scientists sometimes refer to as "hot electrons."

"Hot electrons have the potential to drive very useful chemical reactions, but they decay very rapidly, and people have struggled to harness their energy," said lead researcher Isabell Thomann, assistant professor of electrical and computer engineering and of chemistry and materials science and nanoengineering at Rice. "For example, most of the energy losses in today's best photovoltaic solar panels are the result of hot electrons that cool within a few trillionths of a second and release their energy as wasted heat."

Capturing these high-energy electrons before they cool could allow solar-energy providers to significantly increase their solar-to-electric power-conversion efficiencies and meet a national goal of reducing the cost of solar electricity.

In the light-activated nanoparticles studied by Thomann and colleagues at Rice's Laboratory for Nanophotonics (LANP), light is captured and converted into plasmons, waves of electrons that flow like a fluid across the metal surface of the nanoparticles. Plasmons are high-energy states that are short-lived, but researchers at Rice and elsewhere have found ways to capture plasmonic energy and convert it into useful heat or light. Plasmonic nanoparticles also offer one of the most promising means of harnessing the power of hot electrons, and LANP researchers have made progress toward that goal in several recent studies.

Thomann and her team, graduate students Hossein Robatjazi, Shah Mohammad Bahauddin and Chloe Doiron, created a system that uses the energy from hot electrons to split molecules of water into oxygen and hydrogen. That's important because oxygen and hydrogen are the feedstocks for fuel cells, electrochemical devices that produce electricity cleanly and efficiently.

To use the hot electrons, Thomann's team first had to find a way to separate them from their corresponding "electron holes," the low-energy states that the hot electrons vacated when they received their plasmonic jolt of energy. One reason hot electrons are so short-lived is that they have a strong tendency to release their newfound energy and revert to their low-energy state. The only way to avoid this is to engineer a system where the hot electrons and electron holes are rapidly separated from one another. The standard way for electrical engineers to do this is to drive the hot electrons over an energy barrier that acts like a one-way valve. Thomann said this approach has inherent inefficiencies, but it is attractive to engineers because it uses well-understood technology called Schottky barriers, a tried-and-true component of electrical engineering.

"Because of the inherent inefficiencies, we wanted to find a new approach to the problem," Thomann said. "We took an unconventional approach: Rather than driving off the hot electrons, we designed a system to carry away the electron holes. In effect, our setup acts like a sieve or a membrane. The holes can pass through, but the hot electrons cannot, so they are left available on the surface of the plasmonic nanoparticles."

The setup features three layers of materials. The bottom layer is a thin sheet of shiny aluminum. This layer is covered with a thin coating of transparent nickel-oxide, and scattered atop this is a collection of plasmonic gold nanoparticles -- puck-shaped disks about 10 to 30 nanometers in diameter.

When sunlight hits the discs, either directly or as a reflection from the aluminum, the discs convert the light energy into hot electrons. The aluminum attracts the resulting electron holes and the nickel oxide allows these to pass while also acting as an impervious barrier to the hot electrons, which stay on gold. By laying the sheet of material flat and covering it with water, the researchers allowed the gold nanoparticles to act as catalysts for water splitting. In the current round of experiments, the researchers measured the photocurrent available for water splitting rather than directly measuring the evolved hydrogen and oxygen gases produced by splitting, but Thomann said the results warrant further study.

"Utilizing hot electron solar water-splitting technologies we measured photocurrent efficiencies that were on par with considerably more complicated structures that also use more expensive components," Thomann said. "We are confident that we can optimize our system to significantly improve upon the results we have already seen."


Story Source:

The above post is reprinted from materials provided by Rice University. Note: Materials may be edited for content and length.


Journal Reference:

  1. Hossein Robatjazi, Shah Mohammad Bahauddin, Chloe Doiron, Isabell Thomann. Direct Plasmon-Driven Photoelectrocatalysis. Nano Letters, 2015; 150806081425003 DOI: 10.1021/acs.nanolett.5b02453

 

The doggy gang

 

The gang

Ricoh ups the resolution of spherical photography with Theta S

 

 

The Theta S launched alongside a new Theta app for Android/iOS

The Theta S launched alongside a new Theta app for Android/iOS (Credit: Paul Ridden/Gizmag)

Image Gallery (12 images)

With faster lenses, larger image sensors and increased resolution, the new Ricoh Theta S, which was launched today at IFA 2015, is a decidedly more grown-up version of the quirky spherical camera. The new model can shoot more detailed spherical photos, and its 360-degree videos are now recorded in Full HD 1920 x 1080 at 30 fps (frames per second).

When the original Theta was launched, it was billed as the first mass production camera for spherical panoramas, and impressed us when we reviewed it. Since then it has gained the ability to record spherical video, and seen competition crop up in the likes of the 360cam, Panono, and Bublcam – though those devices all use a different approach to shooting 360 video or images than Ricoh’s proprietary ultra-small twin-lens folded-optical system.

The new Theta S may look a lot like its predecessor, but it offers a number of improvements on the inside which promise to make a big difference. The key changes come in the form of new faster F2 aperture lenses which take in a 360-degree view, and larger dual 1/2.3-inch (6.17 x 4.55 mm) 12-megapixel CMOS sensors which output a 14-megapixel equivalent.

These updates allow the Theta S to take in more light than earlier models and produce better quality images and video with less noise, even in lower light situations. Previous versions struggled in all but the best lighting conditions. Video can now be recorded in Full HD 1920 x 1080 pixels at 30 fps for up to 25 minutes. In addition to sharing 360-degree content via Ricoh's theta360.com, videos can be viewed on YouTube, and spherical images can be uploaded to Facebook, Twitter and Tumblr.

The Ricoh Theta S will also be able to work alongside the new Google Street View App which was also introduced today by Google Maps. This brings support for the use of spherical cameras like the Ricoh Theta S, which Charles Armstrong, Google Maps Product Manager, said made it easier for users to create and upload spherical photo content to Street View. To make the point he also used one to create a new entry of the assembled journalists at IFA, and uploaded it to his private Street View account.

An updated design sees the Theta S gain a sure-grip black rubber coating, along with a new user interface with face-mounted LED mode indicators to show whether you are shooting stills or videos. A new Theta S app also allows smartphone or tablet users to configure settings, view a real-time preview of what the Theta S is shooting, or view and share content from the camera's 8 GB internal memory. Ricoh says an improved Wi-Fi module allows transfer of data four times faster than the current model.

The Ricoh Theta S will be available from late October priced at US$350.

Product page: Ricoh Theta S

 

http://www.gizmag.com/ricoh-theta-s-spherical-camera-details/39249

 

NSF and USAID announce latest round of awards to address global development challenges

 


Press Release 15-097

group walking through a grass field in Gabon

One PEER project will use geospatial tools to study malarial transmission in birds in Cameroon.
Credit and Larger Version

August 31, 2015

Building sustainable fisheries, monitoring landslide risk, studying the emerging bioeconomy: these are some of the research projects announced today in the newest round of an interagency partnership to foster collaborative global research.

The National Science Foundation (NSF) and U.S. Agency for International Development (USAID) awards will advance the scientific and technical capacity of the U.S. and countries in critical areas of development. The projects are the latest set of Partnerships for Enhanced Engagement in Research (PEER) awards, which pair NSF-funded U.S. scientists with researchers in developing countries, who are funded by USAID.

NSF's 16 PEER awards span eight countries and include research in ocean acidification, malarial transmission, climate adaptation and more.

"By linking NSF-funded scientists and engineers with foreign counterparts, we can leverage U.S. investment while strengthening global research capacity," said Jessica Robin, NSF program director for PEER. "These projects tackle crucial research areas, such as biodiversity conservation and food security, which affect the lives of millions worldwide."

There are 45 total research projects in this year's PEER program, selected from more than 500 proposals and representing a $10 million investment from USAID.

This year's solicitation included a special focus on transboundary water issues in Central Asia, an effort to generate sustainable solutions to critical water issues in the region. Scientists from Uzbekistan, Tajikistan and Kyrgyzstan will partner with Johns Hopkins University researchers to examine water resource management in the Anu Darya river basin, one of the largest in Central Asia. Another team from Kyrgyzstan, Kazakhstan and Tajikistan will work with scientists from University of Idaho on glacier dynamics.

PEER is a collaboration between USAID and eight federal science agencies, including NSF, NASA, the National Institute of Food and Agriculture, the National Institutes of Health, the Smithsonian Institution, the United States Department of Agriculture’s Agricultural Research Service, the United States Forest Service, and the United States Geological Service. The program is administered by the National Academy of Sciences.

PEER has supported more than 150 projects in over 40 countries since its start in 2011. The next call for PEER pre-proposals will open in October 2015.

-NSF-

Media Contacts
Jessica Arriens, NSF, (703) 292-2243, jarriens@nsf.gov

Program Contacts
Jessica H. Robin, NSF, (703) 292-8706, jrobin@nsf.gov

The National Science Foundation (NSF) is an independent federal agency that supports fundamental research and education across all fields of science and engineering. In fiscal year (FY) 2015, its budget is $7.3 billion. NSF funds reach all 50 states through grants to nearly 2,000 colleges, universities and other institutions. Each year, NSF receives about 48,000 competitive proposals for funding, and makes about 11,000 new funding awards. NSF also awards about $626 million in professional and service contracts yearly.

Useful NSF Web Sites:
NSF Home Page: http://www.nsf.gov
NSF News: http://www.nsf.gov/news/
For the News Media: http://www.nsf.gov/news/newsroom.jsp
Science and Engineering Statistics: http://www.nsf.gov/statistics/
Awards Searches: http://www.nsf.gov/awardsearch/

 

http://www.nsf.gov/news/news_summ.jsp?cntn_id=136076&WT.mc_id=USNSF_51&WT.mc_ev=click

 

The genetic causes, ethnic origins and history of red hair

 

 

What causes red hair ?

Red hair is a recessive genetic trait caused by a series of mutations in the melanocortin 1 receptor (MC1R), a gene located on chromosome 16. As a recessive trait it must be inherited from both parents to cause the hair to become red. Consequently there are far more people carrying the mutation for red hair than people actually having red hair. In Scotland, approximately 13% of the population are redheads, although 40% carry at least one mutation.

There are many kinds of red hair, some fairer, or mixed with blond ('strawberry blond'), some darker, like auburn hair, which is brown hair with a reddish tint. This is because some people only carry one or a few of the several possible MC1R mutations. The lightness of the hair ultimately depends on other mutations regulating the general pigmentation of both the skin and hair.

Red Hair Facts

  • Skin and hair pigmentation is caused by two different kinds of melanin: eumelanin and pheomelanin. The most common is eumelanin, a brown-black polymer responsible for dark hair and skin, and the tanning of light skin. Pheomelanin has a pink to red hue and is present in lips, nipples, and genitals. The mutations in the MC1R gene imparts the hair and skin more pheomelanin than eumelanin, causing both red hair and freckles.
  • Redheads have very fair skin, almost always lighter than non-redheads. This is an advantage in northern latitudes and very rainy countries, where sunlight is sparse, as lighter skin improves the absorption of sunlight, which is vital for the production of vitamin D by the body. The drawback is that it confers redheads a higher risk for both sunburns and skin cancer.
  • Studies have demonstrated that people with red hair are more sensitive to thermal pain and also require greater amounts of anesthetic than people with other hair colours. The reason is that redheads have a mutation in a hormone receptor that can apparently respond to at least two different hormones: the melanocyte-stimulating hormone (for pigmentation) and endorphins (the pain relieving hormone).
  • Folk wisdom has long described redheads as hot-tempered and short-tempered.
  • If you did an autosomal DNA test (e.g. with 23andMe), you can check if you carry some of the MC1R mutations.

 

Red hair, a Celto-Germanic trait ?

Red hair has long been associated with Celtic people. Both the ancient Greeks and Romans described the Celts as redheads. The Romans extended the description to Germanic people, at least those they most frequently encountered in southern and western Germany. It still holds true today.

Although red hair is an almost exclusively northern and central European phenomenon, isolated cases have also been found in the Middle East, Central Asia (notably among the Tajiks), as well as in some of the Tarim mummies from Xinjiang, in north-western China. The Udmurts, an Uralic tribe living in the northern Volga basin of Russia, between Kazan and Perm, are the only non-Western Europeans to have a high incidence of red hair (over 10%). So what do all these people have in common ? Surely the Udmurts and Tajiks aren't Celts, nor Germans. Yet, as we will see, all these people share a common ancestry that can be traced back to a single Y-chromosomal haplogroup: R1b.

 

Where is red hair more common ?

It is hard to calculate the exact percentage of the population having red hair as it depends on how wide a definition one adopts. For example, should men with just partial red beards, but no red hair on the top of their heads be included or not ? Should strawberry blond be counted as red, blond, or both ? Regardless of the definition, the frequency of red hair is highest in Ireland (10 to 30%) and Scotland (10 to 25%), followed by Wales (10 to 15%), Cornwall and western England, Brittany, the Franco-Belgian border, then western Switzerland, Jutland and southwest Norway. The southern and eastern boundaries, beyond which red hair only occurs in less than 1% of the population, are northern Spain, central Italy, Austria, western Bohemia, western Poland, Baltic countries and Finland.

Overall, the distribution of red hair matches remarkably well the ancient Celtic and Germanic worlds. It is undeniable too that the highest frequencies are always observed in Celtic areas, especially in those that remained Celtic-speaking to this day or until recently. The question that inevitably comes to many people's minds is: did red hair originate with the Celtic or the Germanic people ?

Southwest Norway may well be the clue to the origin of red hair. It has been discovered recently, thanks to genetic genealogy, that the higher incidence of both dark hair and red hair (as opposed to blond) in southwest Norway coincided with a higher percentage of the paternal lineage known as haplogroup R1b-L21, including its subclade R1b-M222, typical of northwestern Ireland and Scotland (the so-called lineage of Niall of the Nine Hostages). It is now almost certain that native Irish and Scottish Celts were taken (probably as slaves) to southwest Norway by the Vikings, and that they increased the frequency of red hair there.

Map of red hair frequency in Europe

Distribution of haplogroup red hair in Europe

Map of Y-haplogroup R1b in Europe

Distribution of haplogroup R1b in Europe

The 45th parallel, a natural boundary for red hair ?

What is immediately apparent to genetic genealogists is that the map of red hair correlates with the frequency of haplogroup R1b in northern and western Europe. It doesn't really correlate with the percentage of R1b in southern Europe, for the simple reason that red hair is more visible among people carrying various other genes involved in light skin and hair pigmentation. Mediterranean people have considerably darker pigmentations (higher eumelanin), especially as far as hair is considered, giving the red hair alleles little opportunity to express themselves. The reddish tinge is always concealed by black hair, and rarely visible in dark brown hair. Rufosity being recessive, it can easily stay hidden if the alleles are too dispersed in the gene pool, and that the chances of both parents carrying an allele becomes too low. Furthermore, natural selection also progressively pruned red hair from the Mediterranean populations, because the higher amount of sunlight and strong UV rays in the region was more likely to cause potentially fatal melanoma in fair-skinned redheads.

At equal latitude, the frequency of red hair correlates amazingly well with the percentage of R1b lineages. The 45th parallel north, running through central France, northern Italy and Croatia, appears to be a major natural boundary for red hair frequencies. Under the 45th parallel, the UV rays become so strong that it is no longer an advantage to have red hair and very fair skin. Under the 41th parallel, redheads become extremely rare, even in high R1b areas.

The 45th parallel is also the traditional boundary between northern European cultures, where cuisine is butter-based, and southern European cultures, preferring olive oil for cooking. In France, the 45th parallel is the also limit between the northern Oïl dialects of French and the southern Occitan language. In northern Italy, it is the 46th parallel that separates German speakers (in South Tyrol) from Italian speakers. The natural boundary probably has a lot to do with the sun and climate in general, since the 45th parallel is exactly halfway between the Equator and the North Pole.

Even as far back as Neolithic times, the 45th parallel roughly divided the Mediterranean Cardium Pottery culture from the Central European Linear Pottery culture. It is entirely possible, and even likely, that the European north-south divide, not just for culture and agriculture, but also for phenotypes and skin pigmentation, go back to Neolithic times, when the southern expansion of agriculture was carried out mostly by the migration of farmers from the Near East to Iberia, following the Mediterranean coastlines, while the northern Danubian diffusion of farming was achieved by native Mesolithic Europeans who acquired Neolithic techniques by contact with farmers from Thessaly and Albania (Sesklo culture), and only blending to a small extent.

Slavic, Baltic and Finnish people are predominantly descended from haplogroup R1a, N1c1 and I1. Their limited R1b ancestry means that the MC1R mutation is much rarer in these populations. This is why, despite their light skin and hair pigmentation and living at the same latitude as Northwest Europeans, almost none of them have red hair, apart from a few Poles or Czechs with partial German ancestry.

 

Where did red hair first arise ?

It has been suggested that red hair could have originated in Paleolithic Europe, especially since Neanderthal also had red hair. The only Neanderthal specimen tested so far (from Croatia) did not carry the same MC1R mutation responsible for red hair in modern humans (the mutation in question in known as Arg307Gly). But since Neanderthals evolved alongside Homo Sapiens for 600,000 years, and had numerous subspecies across all Europe, the Middle East and Central Asia, it cannot be ruled out that one particular subspecies of Neanderthal passed on the MC1R mutation to Homo Sapiens. It is however unlikely that this happened in Europe, because red hair is conspicuously absent from, or very low in parts of Europe with the highest percentages of haplogroup I (e.g. Finland, Bosnia, Sardinia) and R1a (Eastern Europe), the only two lineage associated with Mesolithic and Paleolithic Europeans. We must therefore look for the source of red hair, elsewhere. unsurpisingly, the answer lies with the R1b people - thought to have recolonised Central and Western Europe during the Bronze Age.

The origins of haplogroup R1b are complex, and shrouded in controversy to this day. The present author favours the theory of a Middle Eastern origin (a point upon which very few population geneticists disagree) followed by a migration to the North Caucasus and Pontic Steppe, serving as a starting point for a Bronze-age invasion of the Balkans, then Central and Western Europe. This theory also happens to be the only one that explains the presence of red hair among the Udmurts, Central Asians and Tarim mummies.

 

A possible Neanderthal link ?

Haplogroup R1b probably split from R1a during the Upper Paleolithic, roughly 25,000 years ago. The most likely location was Central Asia, around what is now the Caspian Sea, which only became a sea after the last Ice Age ended and the ice caps over western Russia melted. After the formation of the Caspian Sea, these nomadic hunter-gatherers, ended up on the greener and richer Caucaso-Anatolian side of the Caspian, where they may have domesticated local animals, such as cows, pigs, goats and sheep.

If the mutation for red hair was inherited from Neanderthal, it would have been from a Central Asian Neanderthal, perhaps from modern Uzbekistan, or an East Anatolian/Mesopotamian one. The mutation probably passed on to some other (extinct ?) lineages for a few millennia, before being inherited by the R1b tribe. Otherwise, it could also have arisen independently among R1b people as late as the Neolithic period (but no later).

 

Red hair and the Indo-European migrations

Developing pottery, or more probably acquiring the skills from Middle Eastern neighbours (notably haplogroup G2a), part of the R1b tribe (and a small minority of G2a3b1) migrated across the Caucasus to take advantage of the vast expanses of grassland for their herds. This is where the Proto-Indo-European culture would have emerged, and spread to the native R1a tribes of the Eurasian steppe, with whom the R1b people blendeded to a moderate level (the reason why there is always a minority of R1b and G2a among predominantly R1a populations today, anywhere from Eastern Europe to Siberia and India).

The domestication of the horse in the Volga-Ural region circa 4000-3500 BCE, combined with the emergence of Bronze Age technology in the North Caucasus around 3300 BCE, would lead to the spectacular expansion of R1b and R1a lineages, an adventure that would lead these Proto-Indo-European speakers to the Atlantic fringe of Europe to the west, to Siberia and North America to the east, and all the way from Egypt to India to the south. From 3500 BCE, the vast majority of the R1b migrated westward along the Black Sea coast, to the metal-rich Balkans, where they mixed with the local inhabitants of Chalcolithic "Old Europe". A small number of R1b accompanied R1a to Siberia and Central Asia, which is why red hair very occasionally turns up in R1a-dominant populations of those areas (who usually still have a minority of R1b among their lineages, although some tribes may have lost them due to the founder effect).

The archeological record indicates that this sustained series of invasions was extremely violent and led to the complete destruction of the until then flourishing civilizations of the Balkans and Carpathians (whose descendants survive as the I2a1b and E1b1b1a lineages). The R1b invaders took local women as wives and concubines, creating a new mixed ethnicity. The language evolved in consequence, adopting loanwords from the languages of Old Europe. This new ethnic and linguistic entity could be referred to as the Proto-Italo-Celto-Germanic people.

After nearly a millennium in the Danubian basin (as far west as Bavaria), they would continue their westward expansion (from 2500 BCE) to Western Europe. In fact, the westward expansion was most likely carried out exclusively by the westernmost faction of R1b, who had settled north of the Alps, around Austria and Bavaria, and developed the Unetice culture. Many R1b lineages stayed behind in the Balkans, where they progressively blended with the natives, then with later immigrants to the region (notably J2, under the Greek, Roman, Byzantine and Ottoman rules) over the next millennia - mostly losing their red hair due to the high incidence of very dark hair in the region today. According to ancient Greek writers, red hair was common among the Thracians, who lived around modern Bulgaria, an region where rufosity has almost completely disappeared today. Red hair alleles may have survived in the local gene pool though, but cannot be expressed due to the lack of other genes for light hair pigmentation.

The red-haired Proto-Italic, Proto-Celtic and Proto-Germanic split in three branches during the progressive expansion of the successive Bronze-age Unetice, Tumulus and Urnfield cultures from Central Europe. The Proto-Germanic branch, originating as the R1b-U106 subclade, is thought to have migrated from present-day Austria to the Low Countries and north-western Germany. They would continue their expansion (probably from 1200 BCE) to Denmark, southern Sweden and southern Norway, where, after blending with the local I1 and R1a people, the ancient Germanic culture emerged.

Nowadays, the frequency of red hair among Germanic people is highest in the Netherlands, Belgium, north-western Germany and Jutland, i.e. where the percentage of R1b is the highest, and presumably the first region to be settled by R1b, before blending with the blond-haired R1a and I1 people from Scandinavia and re-expanding south to Germany during the Iron Age, with a considerably lower percentage of R1b and red-hair alleles. Red-haired is therefore most associated with the continental West Germanic peoples, and least with Scandinavians and Germanic tribes that originated in Sweden, like the Goths and the Vandals. This also explains why the Anglo-Saxon settlements on southern England have a higher frequency of redheads than the Scandinavian settlements of northeast England.

The Italic branch crossed the Alps around 1300 BCE and settled across most of the peninsula, but especially in Central Italy (Umbrians, Latins, Oscans). They probably belonged predominantly to the R1b-U152 subclade. It is likely that the original Italics had just as much red hair as the Celts and Germans, but lost them progressively as they intermarried with their dark-haired neighbours, like the Etruscans. The subsequent Gaulish Celtic settlements in northern Italy increased the rufosity in areas that had priorly been non-Indo-European (Ligurian, Etruscan, Rhaetic) and therefore dark-haired. Nowadays red hair is about as common in northern and in central Italy.

The Celtic branch is the largest and most complex. The area that was Celtic-speaking in Classical times encompassed regions belonging to several distinct subclades of R1b-S116 (the Proto-Italo-Celtic haplogroup). The earliest migration of R1b to Western Europe must have happened with the diffusion of the Bronze Age to France, Belgium, Britain and Ireland around 2100 BCE - a migration best associated with the R1b-L21 subclade. A second migration took place around 1800 BCE to Southwest France and Iberia, and is associated with R1b-Z196. These two branches are usually considered as Celtic, but was probably more distinct than the later continental Celtic were from Italic languages, due to its earlier split. The Northwest Celtic branch could have been ancestral to Goidelic languages (Gaelic), and the south-western one to Celtiberian. Both belong to the Q-Celtic group, as opposed to the P-Celtic group, to which Gaulish and Brythonic belong and which is associated with the expansion of the Hallstatt and La Tène cultures and R1b-U152 (the same subclade as the Italic branch). Nowadays, red hair is found in all three Celtic branches, although it is most common in the R1b-L21 branch. The reason is simply that it is the northernmost branch (red hair being more useful at higher latitudes) and that the Celtic populations of Britain and Ireland have retained the purest Proto-Celtic ancestry (extremely high percentage of R1b).

Red hair was also found among the tartan-wearing Chärchän man, one of the Tarim mummies dating from 1000 BCE, who according to the author were an offshoot of Central European Celts responsible for the presence of R1b among modern Uyghurs. The earlier, non-tartan-wearing Tarim mummies from 2000 BCE, which were DNA tested and identified as members of haplogroup R1a, did not have red hair, just like modern R1a-dominant populations.

http://www.eupedia.com/genetics/origins_of_red_hair.shtml

Carregador de celular grátis

 

 

Não compres carregadores de celular. Se perdeste o teu, vai a um hotel e diz que o perdeste lá.  Carregadores são alguns  dos objetos mais esquecidos em hotéis,  por isso têm sempre um caixote cheio deles.

 

Snap 2015-09-04 at 05.05.00