Monday, December 31, 2012

Lake Abaya

                                    Lake Abaya

                                             
  • Lake Abaya (Abaya Hayk in Amharic) is a lake in the Southern Nations, Nationalities, and Peoples Region of Ethiopia. It was named Lake Margherita by the Italian explorerVittorio Bottego, the first European commonly thought to visit the lake, to honor the wife of king Umberto I of Italy, Queen Margherita. This name appears in older publications, and currently is rarely used.
    However, the American explorer Arthur Donaldson Smith records that the local inhabitants, who included an eye witness of the event, told him that the Italian explorerEugene Ruspoli (died 1891) was killed by an elephant near the lake, which happened before Bottego reached Lake Abaya.[1]
    Lake Abaya is located in the Main Ethiopian Rift, east of the Guge Mountains. It is fed on its northern shore by the Bilate which rises on the southern slopes of Mount Gurage, and the Gidabo. The town of Arba Minch lies on its southwestern shore, and the southern shores are part of the Nechisar National Park. Just to the south is Lake Chamo. Lake Abaya is 60 kilometers long and 20 wide,[2] with a surface area of 1162 square kilometers.[3] It has a maximum depth of 13.1 meters and is at an elevation of 1285 meters.[3] There are a number of islands in this lake, the largest being Aruro;[4]others include Gidicho, Welege, Galmaka, and Alkali. The lake is red due to a high load of suspended sediments.[5] Lake Abaya does not always have an outflow, but in some years it overflows into Lake Chamo.
    Savanna, known for its wildlife and birdlife surrounds the lake, which is also fished by local people. According to the Ethiopian Department of Fisheries and Aquaculture, 412tonnes of fish are landed each year, which the department estimates is 69% of its sustainable amount.[6]

Muragala

                      File:Muragala.JPG

Sandakada pahana

                               Sandakada pahana

  • Anuradhapura period

    A sandakada pahana of the Anuradhapura period
    The first sandakada pahanas were created during the latter stage of the ancientAnuradhapura Kingdom. They were only placed at entrances to Buddhist temples during this period.[5]
    The carvings of the semi circular stone slab were the same in every sandakada pahana. A half lotus was carved in the centre, which was enclosed by several concentric bands. The first band from the half lotus is decorated with a procession of swans, followed by a band with an intricate foliage design known as liyavel. The third band has carvings of four animals; elephants, lions, horses, and bulls. These four animals follow each other in a procession symbolizing the four stages in life: growth, energy, power and forbearance. The fourth and outermost band contains a carving of flames.[5]

    [edit]Polonnaruwa period

    The design of the sandakada pahana of the Polonnaruwa period differs largely from that of the Anuradhapura period. The single band that was used to depict the four animals was removed, and processions of the elephant, lion and horse were depicted in separate bands. The most significant change is the removal of the bull from the sandakada pahana.[6] The Anuradhapura tradition of placing sandakada pahanas only at entrances to Buddhist temples also changed, and they are found at the entrances of other buildings belonging to the Polonnaruwa period as well.[5]
    The sandakada pahana at the entrance to the Polonnaruwa Vatadage. Note the absence of the bull and lion.
    An invasion by Rajendra I in 1017 AD brought a large part of the country under the control of the Chola empire.[7][8] The country was under Chola rule until 1055 AD,[9] and the Sri Lankan culture was heavily influenced by South Indian customs and traditions, including theHindu religion.[10] Historians believe that the reason for the removal of the bull from the sandakada pahana was because of its connection with Hinduism. The bull, the vehicle of the god Shiva, is a venerated animal in Hinduism, and therefore was removed from the sandakada pahana since it was a place where people tread upon.[6] The lion has also been omitted from some sandakada pahanas.[11] The best specimen of the sandakada pahanas of the Polonnaruwa period is at the northern entrance of the Polonnaruwa Vatadage.[12]

    [edit]Kandy and Gampola periods

    A sandakada pahana of the Kandy period at the Degaldoruwa temple.
    By the time of the Gampola and KandyKingdoms, the design of the sandakada pahana had changed drastically. The concentric bands were no longer there, and the shape of the once semi circular stone slab had become almost triangular. A lotus was carved in the middle of the stone slab, which was surrounded by an elaborate pattern of liyavel.[13]

    [edit]Symbolism

    Historians believe that the carvings of the sandakada pahana symbolise a religious meaning. The widely accepted interpretation is that of historian Senarath Paranavithana. According to Paranavitana, the sandakada pahana symbolises the cycle of Saṃsāra. Theliyavel symbolise worldly desires (Taṇhā) and the lotus depicts the final achievement ofNirvana.[14] The elephant, bull, lion and horse depict birth, decay, disease and death respectively, while the swans symbolise the distinction between good and bad.

Yellow rain

                                         Yellow rain

  • Allegations

    The charges stemmed from events in Laos and Vietnam beginning in 1975, when the two governments, which were allied with and supported by the Soviet Union, retaliated against Hmong tribes, peoples who had sided with the United States during the Vietnam War. Refugees described events that they believed to be chemical warfare attacks by low-flying aircraft or helicopters; several of the reports were of a yellow, oily liquid that was dubbed "yellow rain". Those exposed claimed neurological and physical symptoms including seizures, blindness, and bleeding. Similar reports came from the Vietnamese invasion of Cambodia in 1978.[7]
    A 1997 textbook produced by the U.S. Army Medical Department asserted that over ten thousand people were killed in attacks using chemical weapons in Laos, Cambodia and Afghanistan.[2] The descriptions of the attacks were diverse and included air-dropped canisters and sprays, booby traps, artillery shells, rockets and grenades that produced droplets of liquid, dust, powders, smoke or "insect-like" materials of a yellow, red, green, white or brown color.[2]
    Secretary of State Alexander Haig announced in September 1981 that:
    For some time now, the international community has been alarmed by continuing reports that the Soviet Union and its allies have been using lethal chemical weapons in Laos, Kampuchea, and Afghanistan. ... We have now found physical evidence from Southeast Asia which has been analyzed and found to contain abnormally high levels of three potent mycotoxins--poisonous substances not indigenous to the region and which are highly toxic to man and animals.
    The Soviet Union described these accusations as a "big lie" and in turn accused the US government of using chemical weapons during the Vietnam war.[8] The American accusations prompted a United Nations investigation in Pakistan and Thailand. This involved five doctors and scientists who interviewed alleged witnesses and collected samples that were purported to come from Afghanistan and Cambodia. However, the interviews produced conflicting testimony and the analyses of the samples were inconclusive. The UN experts also examined two refugees who claimed to be suffering from the after-effects of a chemical attack, but the refugees were instead diagnosed as having fungal skin infections. The team reported that they were unable to verify that chemical weapons had been used but noted that circumstantial evidence "suggestive of the possible use of some sort of toxic chemical substance in some instances."[9]
    The US mycotoxin analyses were reported in the scientific literature in 1983 and 1984 and reported small amounts of mycotoxins called trichothecenes, ranging from the parts per million to traces in the parts per billion range.[10][11] The lowest possible limit of detection in these mycotoxin analyses is in the parts per billion range.[12] However, several inconsistencies in these reports caused a "prolonged, and at times acrimonious, debate on the validity of the analyses".[13] A 2003 medical review notes that this debate may have been exacerbated since "Although analytical methods were in their infancy during the controversy, they were still sensitive enough to pick up low levels of environmental trichothecene contamination.".[14]

    [edit]Investigation

    C. J. Mirocha at the University of Minnesota conducted a biochemical investigation, looking for the presence of trichothecene mycotoxins, including T-2 toxin, diacetoxyscirpenol (DAS), and deoxynivalenol (DON) (10). This included chemical analyses of blood, urine, and tissue of alleged victims of chemical attacks in February 1982 in Laos and Kampuchea. "The finding of T-2, HT-2, and DAS toxins in blood, urine, and body tissues of alleged victims of chemical warfare in Southeast Asia provides compelling proof of the use of trichothecenes as nonconventional warfare agents....Additional significant findings lie in the trichothecenes found in the leaf samples (T-2, DON, nivalenol) and yellow powder (T-2, DAS)....The most compelling evidence is the presence of T-2 and DAS in the yellow powder. Both toxins are infrequently found in nature and rarely occur together. In our experience, copious producers of T-2 toxin (F. tricinctum) do not produce DAS, and conversely, good producers of DAS (F. roseum 'Gibbosum') do not produce T-2." (10) In 1983, these charges were disputed by Harvard biologist and biological weapons opponent Matthew Meselson and his team, who traveled to Laos and conducted a separate investigation. Meselson's team noted that trichothecene mycotoxins occur naturally in the region and questioned the witness testimony. He suggested an alternate hypothesis that the yellow rain was the harmless fecal matter of honeybees.[3] The Meselson team offered the following as evidence: separate "yellow rain drops" which occurred on the same leaf, and which were "accepted as authentic", consisted largely of pollen; each drop contained a different mix of pollen grains, as one would expect if they came from different bees, and the grains showed properties characteristic of pollen digested by bees (the protein inside the pollen grain was gone, while the outer indigestible shell remained).[15] Further, the pollen mix came from plant species typical of the area where a drop was collected.[16][17]
    Bee droppings that resemble "yellow rain".
    The US government responded to these findings by arguing that the pollen was added deliberately, in order to make a substance that could be easily inhaled and "ensure the retention of toxins in the human body".[6] Meselson responded to this idea by stating that it was rather far-fetched to imagine that somebody would produce a chemical weapon by "gathering pollen predigested by honeybees."[17] Meselson's work was described in an independent medical review as providing "compelling evidence that yellow rain might have a benign natural explanation".[14]
    Analyses of putative "yellow rain" samples by the British, French and Swedish governments confirmed the presence of pollen and failed to find any trace of mycotoxins.[6][18] Toxicology studies questioned the reliability of reports stating that mycotoxins had been detected in alleged victims up to two months after exposure, since these compounds are unstable in the body and are cleared from the blood in just a few hours.[13] Surveys also showed that both mycotoxin-producing fungi and mycotoxin contamination were common in Southeast Asia, casting doubt on the assertion that detecting these compounds was an unusual occurrence.[19][20] For example, a Canadian military laboratory found mycotoxins in the blood of five people from the area who had never been exposed to yellow rain, out of 270 tested, but none in the blood of ten alleged victims,[17][21] and a 1988 paper reported that illnesses from mycotoxin exposure may pose a serious threat to public health inMalaysia.[22] It is now recognized that mycotoxin contamination of foods such as wheat and maize is a common problem, particularly in temperate regions of the world.[20][23] As noted in a 2003 medical review, "The government research highlighted, if nothing else, that natural mycotoxicoses were an important health hazard in Southeast Asia."[14]
    in 1987 the New York Times reported that later freedom of information requests showed that field investigations in 1983-85 by US government teams had produced no evidence to substantiate the initial allegations and instead cast doubt on the reliability of the initial reports, however The Times noted that these critical reports were not released to the public.[24] A 1989 analysis of the initial reports gathered from Hmong refugees that was published in the Journal of the American Medical Association noted "marked inconsistencies that greatly compromised the validity of the testimony" and criticized the methods used in interviews by the US Army medical team that gathered this information. These issues included the US Army team only interviewing those people who claimed to have knowledge of attacks with chemical weapons and the investigators asking leading questions during interviews. The authors noted that individuals' stories changed over time, were inconsistent with other accounts, and that the people who claimed to have been eyewitnesses when first interviewed later stated that they had been relaying the accounts of others.[25]

    [edit]Disputed conclusions

    Currently, two main viewpoints exist on the yellow rain controversy. One viewpoint sees these allegations as supported by insufficient evidence, or as having been completely refuted. For instance, a 1992 review published in Politics and the Life Sciences described the idea of yellow rain as a biological agent as conclusively disproved and called for an assessment by the US government of the mistakes made in this episode, stating that "the present approach of sweeping the matter under the rug and hoping people will forget about it could be counterproductive."[21] Similarly, a 1997 review of the history of biological warfare published in the Journal of the American Medical Association stated that the yellow rain allegations are "widely regarded as erroneous",[5] a 2001 review in the Annual Reviews in Microbiology described them as "unsubstantiated for many reasons",[26] and a 2003 article in Annual review of phytopathologydescribed them as "largely discredited".[4] A 2003 review of the history of biological warfare described these allegations as one of many cases where states have produced propaganda containing false or unsubstantiated accusations of the use of biological weapons by their enemies.[27]
    In contrast, as of 1997 the US Army maintains that some experts believe that "trichothecenes were used as biological weapons in Southeast Asia and Afghanistan" although they write that "it has not been possible for the United States to prove unequivocally that trichothecene mycotoxins were used as biological weapons." They argued that presence of pollen in yellow rain samples is best explained by the idea that "during biological warfare attacks, dispersed trichothecenes landed in pollen-containing areas."[2](Essentially the same position is taken in a subsequent volume in the same series of US Army textbooks published in 2007.[28]) Similarly, the US Defense Threat Reduction Agency argues that the controversy has not been resolved and state that a CIA report indicated the Soviet Union did possess weapons based on T-2 mycotoxin, although they state that "no trace of a trichothecene-containing weapon was ever found in the areas affected by yellow rain" and conclude that the use of such weapons "may never be unequivocally proved."[29] A 2007 review published in Politics and the Life Sciences concluded that the balance of evidence strongly supported the hypothesis that some type of chemical or biological weapon was used in Southeast Asia in the late 1970s and early 1980s, but noted that they found no definitive proof of this hypothesis and that the evidence could not "identify the specific agents used, the intent, or the root source or sources of the attacks."[30]

    [edit]Later events

    An episode of mass pollen release from bees in 2002 in Sangrampur, India, prompted unfounded fears of a chemical weapons attack, although this was in fact due to a mass migration of giant Asian honeybees. This event revived memories of what New Scientistdescribed as "cold war paranoia", and the article noted that the Wall Street Journal had covered these 1980s yellow rain allegations in particular detail.[31] Indeed, the Wall Street Journal continues to assert that the Soviet Union used yellow rain as a chemical weapon in the 1980s and in 2003 accused Matthew Meselson of "excusing away evidence of Soviet violations."[32]
    In the build-up to the 2003 invasion of Iraq the Wall Street Journal alleged that Saddam Hussein possessed a chemical weapon called "yellow rain".[33] The Iraqis appear to have investigated trichothecene mycotoxins in 1990, but only purified a total of 20 ml of the agent from fungal cultures and did not manage to scale up the purification or produce any weapons containing these compounds.[34] Although these toxins are not generally regarded as practical tactical weapons,[35] the T-2 toxin might be a usable weapon since it can be absorbed through the skin, although it would be very difficult to manufacture it in any reasonable quantity.[36]
    Henry Wilde, a retired US Foreign Service Officer, has drawn parallels between the use of yellow rain allegations by the US government against the Soviet Union and the later exaggerated allegations on the topic of Iraq and weapons of mass destruction.[37] Wilde considers it likely that states may again "use rumors and false or planted intelligence of such weapons use for propaganda purposes." and calls for the establishment of a more rigorous inspection process to deal with such claims.[37] Similar concerns were expressed in a 2006 review published by the World Organisation for Animal Health, which compared the American yellow rain accusations to other cold-war accusations from the Soviet Union and Cuba, as well as to more recent mistaken intelligence on Iraqi weapons capabilities, concluding that such unjustified accusations have encouraged the development of biological weapons and increased the risk that they might be used, as they have discredited arms-control efforts

Saturday, December 29, 2012

Red rain

                                       Red rain

                                            
  • Occurrence

    Kottayam district in Kerala, which experienced the most intense red rainfall
    The colored rain of Kerala began falling on July 25, 2001, in the districts of Kottayam and Idukki in the southern part of the state. Yellow, green, and black rain was also reported.[2][3][4] Many more occurrences of the red rain were reported over the following ten days, and then with diminishing frequency until late September.[3] According to locals, the first colored rain was preceded by a loud thunderclap and flash of light, and followed by groves of trees shedding shriveled grey "burnt" leaves. Shriveled leaves and the disappearance and sudden formation of wells were also reported around the same time in the area.[13][14][15]It typically fell over small areas, no more than a few square kilometers in size, and was sometimes so localized that normal rain could be falling just a few meters away from the red rain. Red rainfalls typically lasted less than 20 minutes.[3] Each milliliter of rain water contained about 9 million red particles, and eachliter of rainwater contained approximately 100 milligrams of solids. Extrapolating these figures to the total amount of red rain estimated to have fallen, it was estimated that 50,000 kilograms (110,000 lb) of red particles had fallen on Kerala.[3]

    [edit]Description of the particles

    Photomicrograph of particles from red rain sample
    Particles under a scanning electron microscope
    A single spore viewed with atransmission electron microscope, purportedly showing a detached inner capsule.
    The brownish-red solid separated from the red rain consisted of about 90% round red particles and the balance consisted of debris.[5] The particles insuspension in the rain water were responsible for the color of the rain, which at times was strongly colored red. A small percentage of particles were white or had light yellow, bluish gray and green tints.[3] The particles were typically 4 to 10 µmacross and spherical or oval. Electron microscope images showed the particles as having a depressed center, suggestive of biological cells. At still higher magnification some particles showed internal structures.[3]

    [edit]Chemical composition

    Several groups of researchers analyzed the chemical elements in the solid particles and different techniques gave similar results. The particles were composed mostly of carbon andoxygen with lesser amounts of hydrogennitrogensiliconchlorine and metals.
    The samples of water were brought to the Centre for Earth Science Studies (CESS) in India, where they separated the suspended particles by filtration. The pH (acidity) of the water was found to be around 7 (neutral). The electrical conductivity of the rainwater showed the absence of any dissolved salts. Sediment (red particles plus debris) was collected and analyzed by the CESS using a combination of ion-coupled plasma mass spectrometry, atomic absorption spectrometry and wet chemical methods. The major elements found are listed below.[5] The CESS analysis also showed significant amounts of heavy metals in the raindust, including nickel (43 ppm), manganese (59 ppm), titanium (321 ppm), chromium(67ppm) and copper (55 ppm).
    CESS analysis: Major elements present in the dried sediment
    ElementAlKMgCaNaFeSiCP
    Weight %1.000.261.482.520.490.617.5051.000.08
    Louis and Kumar used energy dispersive X-ray spectroscopy analysis of the red solid and showed that the particles were composed of mostly carbon and oxygen, with trace amounts of silicon and iron[3] (see table below).
    Elemental composition of red particles by EDXRF analysis
    ElementWeight %Atomic %Standards
    C49.5357.83CaCO3
    O45.4239.82Quartz
    Na0.690.42Albite
    Al0.410.21Al2O3
    Si2.851.42Quartz
    Cl0.120.05KCl
    Fe0.970.24Fe
    CHN analyzer showed content of 43.03% carbon, 4.43% hydrogen, and 1.84% nitrogen.[3]
    J. Thomas Brenna in the Division of Nutritional Sciences at Cornell University conducted carbon and nitrogen isotope analyses using a scanning electron microscope with X-ray microanalysis, an elemental analyzer, and an isotope ratio (IR) mass spectrometer. The red particles collapsed when dried, which suggested that they were filled with fluid. The amino acids in the particles were analyzed and seven were identified (in order of concentration): phenylalanineglutamic acid/glutamineserineaspartic acidthreonine, and arginine. He concluded that the results were consistent with a marine origin or a terrestrial plant that uses a C4 photosynthetic pathway.[16]

    [edit]Official report

    Initially, the Centre for Earth Science Studies (CESS) stated that the likely cause of the red rain was an exploding meteor, which had dispersed about 1,000 kg (one ton) of material. A few days later, following a basic light microscopy evaluation, the CESS retracted this as they noticed the particles resembled spores,[17] and because debris from a meteor would not have continued to fall from the stratosphere onto the same area while unaffected by wind. A sample was, therefore, handed over to the Tropical Botanical Garden and Research Institute (TBGRI) for microbiological studies, where the spores were allowed to grow in a medium suitable for growth of algae and fungi. The inoculated Petri dishes and conical flasks were incubated for three to seven days and the culture was observed under a microscope.
    In November 2001, commissioned by the Government of India's Department of Science & Technology, the Center for Earth Science Studies (CESS) and the Tropical Botanical Garden and Research Institute (TBGRI) issued a joint report which concluded that:[5][17]
    The color was found to be due to the presence of a large amount of spores of alichen-forming alga belonging to the genus Trentepohlia. Field verification showed that the region had plenty of such lichens. Samples of lichen taken fromChanganacherry area, when cultured in an algal growth medium, also showed the presence of the same species of algae. Both samples (from rainwater and from trees) produced the same kind of algae, indicating that the spores seen in the rainwater most probably came from local sources.
    The site was again visited on August 16, 2001 and it was found that almost all the trees, rocks and even lamp posts in the region were covered with Trentepohlia lichen, and estimated that the extent of lichen in the region is sufficient to generate the quantity of spores seen in the rainwater.[5] Although red or orange, Trentepohlia is a Chlorophyte green alga which can grow abundantly on tree bark or damp soil and rocks, but is also the photosynthetic symbiont or photobiont of many lichens, including some of those abundant on the trees in Changanacherry area.[5] The strong orange colour of the algae, which masks the green of the chlorophyll, is caused by the presence of large quantities of orangecarotenoid pigments. A lichen is not a single organism, but the result of a partnership (symbiosis) between a fungus and an alga or cyanobacterium.
    The report also stated that there was no meteoric, volcanic or desert dust origin present in the rainwater and that its color was not due to any dissolved gases or pollutants.[5] The report concluded that heavy rains in Kerala -in the weeks preceding the red rains- could have caused the widespread growth of lichens, which had given rise to a large quantity of spores into the atmosphere. However, for these lichen to release their spores simultaneously, it is necessary for them to enter their reproductive phase at about the same time. The CESS report noted that while this may be a possibility, it is quite improbable.[5] Also, they could find no satisfactory explanation for the apparently extraordinary dispersal, nor for the apparent uptake of the spores into clouds. CESS scientists noted that "While the cause of the color in the rainfall has been identified, finding the answers to these questions is a challenge."[17] Attempting to explain the unusual spore proliferation and dispersal, researcher Ian Goddard proposed several local atmospheric models.