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Friday, September 2, 2011

Deciphering Enthusiasm




Hanuman“(Hanuman did not see Sita) who was firmly situated on the eternal path of devotion to her husband, had her gaze always fixed on Rama, was always possessed by love for Rama, had entered the glorious mind of her husband, and was always the most exceptional of women.” (Valmiki Ramayana, Sundara Kand, 5.24)
sanātane vartmāni samniviṣṭām |
rāmekśaṇāṃ tāṃ madanābhiviṣṭām |
bharturmanaḥ śrīmadanupraviṣṭām |
strībhyo varābhyaśca sadā viśiṣṭām ||
“Do I have to? I really don’t want to. Can’t I do it later? Can’t we go some other time?” The dependent compelled to act will be reluctant to take up their assigned duties. The chances of enthusiasm being absent increase when force is applied. As such, the success of the mission, and the enjoyment experienced while performing it, will also be notably missing. But nevertheless, these tasks are sometimes very helpful, for Lord Krishna states in the Bhagavad-gita that those things which at first seem like poison but then later on turn into sweet nectar are in the mode of goodness, which is the level of material activity most conducive towards realizing the highest system of knowledge. Some tasks are more difficult than others; thus making it harder for the leader to find able bodied persons willing to take them up. With one combination of individual and task, however, there was no need for a pep talk. Because of the nature of the mission and its targeted beneficiaries, this worker was full of enthusiasm and conviction, so much so that he felt tremendous dejection anytime it seemed like success wouldn’t come. Because of this emotional response he is the most endearing person to those who are trying to find the true light in life, the spiritual sunshine that provides unending comfort.
Mother Yashoda with Lord KrishnaUnwanted tasks are introduced during childhood. The child is a bundle of energy; it can play for hours on end and find ways to stay amused. The child has no worries about where they are in life, how they will pay the monthly bills, or what their future goals should be. The new blood that joins this earth is after preyas, or immediate satisfaction of the senses. It is therefore up to the guardians to instill some discipline, to get the child to follow some regulated behavior so that they can reach a higher end. It is likely that in our childhood our mother and father gave us specific chores that required completion on a regular basis. Taking out the garbage, washing the dishes, and cleaning the room are not jobs accepted with enthusiasm, but they are nevertheless necessary responsibilities because of our parents’ insistence.
Then there are the infamous family trips. Though the child may not know this, their parents are no different than them in terms of how they choose to enjoy. The parents have siblings and friends of a similar age that they enjoy spending time with, though these people may not live very close by. When the weekend arrives after a difficult work week, the parents may just want to get out of the house and see their loved ones and close friends. For the children, such trips aren’t always welcome because the impetus for the visit is rooted in the parents’ interests. It is not surprising therefore for the child to put up opposition. “Why do I have to go? They’re your friends. Why can’t I just stay home by myself?” If the child is not old enough to take care of itself at home or if the parents want to maintain a strong family presence during their visit, they will compel the child to go. Left with no other choice, the child reluctantly follows, all the while refusing to have a good time.
While these difficulties must be endured during childhood, adults have more independence. There is a choice with every action, an up or down vote whether to accept or reject. In the business world the motivation, the driving force influencing the outcome of the mental poll, is the benefit received by the worker. Employees show up to work on time because they expect compensation from the employer. While at work, different tasks are undertaken, some of which are not so pleasant, simply to satisfy the boss, who will in turn pay a salary.
For the employer, the person assigning the tasks, it is beneficial for the employees to have enthusiasm while working. This will make them more invested in the outcome. With every action there is the initial work applied and the corresponding result. The employee’s primary obligation is to apply the work. The results are not always guaranteed, nor can they be predicted. Obviously for the employer the priority system is reversed. The person assigning the task is more interested in seeing the intended result. The actual work undertaken certainly shows effort on the part of the employee, but if there is failure encountered on a regular basis, the work applied isn’t very effective. Without a successful outcome, the employer is essentially wasting money on fruitless work.
The employer loves to see enthusiasm in his workers, because they know this will increase the chances of success, of reaching the intended outcome. The child forced to go to grandma’s house on a Saturday will not be very happy; they will not be a pleasant person to be around. Similarly, a worker just going through the motions will not have anything invested in the outcome. If there is no fear of failure, the chances of not succeeding increase all the more. When there is enthusiasm, however, there is an emotional attachment to the job. The worker desperately wants to see a successful outcome, as it will please both them and the person distributing the task.
For the employer, gauging the level of enthusiasm in the field of candidates is often difficult. In the beginning, the qualities belonging to each candidate will be reviewed. “Okay, this person has done such and such in the past. It looks like they are dependable and take orders very well. This other person looks like they can work independently and handle difficult situations. This other person has every skill necessary for the job.” When all the relevant factors have been taken into consideration, a final judgment is made.
A high enthusiasm level will naturally put a prospective candidate into a better position, but how do we judge this? Surely a candidate can verbally express how desperate they are to undertake the task in question. “Please give me the job. I’m ready. I’m up for the task. I won’t let you down.” If these statements are to be accepted, the employer must invest some faith in the worker, as they will have to assume that the candidate is being honest about how they feel. A way to get more assurance, however, is to get references, i.e. talk to people who know the worker and can vouch for their enthusiasm and ability to carry out specific tasks.
Sita DeviWith Shri Hanuman, the Vanara warrior asked to find a missing princess, all of the necessary qualifications were there. Sita Devi, the wife ofLord Rama, had gone missing while she was residing in the forest of Dandaka. Her husband was the strongest bow warrior of the time, but when He was temporarily lured away from the couple’s cottage, a fiendish character swept in and forcibly took Sita with him. No one was really sure where she had gone, or if she was even still alive. Sita was fixed in a vow of dedication to her husband, so she could never survive long without being in His company. Indeed, it would be learned later on that she only kept her vital breath within her body by keeping her thoughts fixed on her husband, His qualities, and the time they previously spent together.
Since outwardly there was not even a hint as to where Sita had been taken, Rama thought it wise to enlist the help of others. Who better than the Vanaras of Kishkindha, who were monkey-like creatures beaming with enthusiasm for pleasing Rama? A monkey is especially known for being hyper and capable of jumping from tree to tree without exhaustion. These monkeys were more human-like, as these events took place in an ancient time. The Darwinists believe that man descended from monkeys, but the Vedas correctly reveal that dull matter is incapable of causing shifts in species. Without a spiritual injection, no form of body, which is nothing more than a machine, can do anything. Without a driver an automobile just remains stationary. Even in advanced airplanes that can fly themselves, there must be the human influence of a programmed computer or remote pilot available.
Vanaras fighting for RamaSpecies are crafted according to specific combinations of the material elements of earth, water, fire, ether and air, along with mind, intelligence and ego. No life form is capable of creating a new permanent species on its own; as nature has full control over the human being. Just as we can’t stop the sun from rising and setting, we can’t suddenly generate a new race of human beings having three hands or some other advanced feature set. While the bodies themselves don’t evolve, the souls that reside within them can travel from one form to another. This is known as transmigration, or reincarnation. In the Treta Yuga, the second time period of creation, conditions on earth were so pure that even the monkey race had advanced characteristics. When the presence of the mode of goodness is strong, the abilities of a species are enhanced. The Vanaras, who were forest dwellers more than anything else, were predominantly monkey-like, but they nevertheless had the ability to think rationally at times and converse with human beings.
The leader of the Vanaras in Kishkindha was Sugriva, and he had a massive army of monkeys at his disposal. To find Sita, however, required great effort, courage, resourcefulness, intelligence and humility. This last quality would come in handy because the worker would have to follow specific instructions and not alter the objectives of the mission. Whoever would find Sita would certainly be praised for their accomplishment, but if their ego got too large, if they suddenly felt they were superior to others, they might violate the orders given. Rama wanted Sita to be found, but He was going to rescue her Himself. Shri Rama was of the princely order, so it was His duty to protect the innocent. If He had to rely on others to rescue His wife, His and His family’s stature would immediately be deprecated.
Lord RamaThough Sugriva dispatched thousands of monkeys to scour the earth in a frantic search, he knew that only Hanuman had any real chance of succeeding. Hanuman was Sugriva’s trusted aide, and he had many times prior proven the worthiness of his high position. Seeing his qualities personally and trusting Sugriva’s words, Rama had full confidence in Hanuman’s ability to succeed in the task. Indeed, the Vanara would go on to perform amazing feats, such as leaping across a massive ocean and defeating several powerful forces obstructing his path.
Hanuman’s enthusiasm didn’t need to be proven, as he was always devoted to Rama. Though he barely knew the prince of the Raghu dynasty or His younger brother Lakshmana, Hanuman could decipher their divine natures. Thus when he was told to find Sita, Hanuman took the mission as his life and soul. As if there were any doubt on the matter, when on the precipice of finding the divine princess, Hanuman would once again show us his terrific enthusiasm, his undying love for Rama and his eagerness to please Him.
HanumanSita Devi had been taken to the island of Lanka, which was inhabited by Rakshasas headed by their leader Ravana. These creatures were similar to ghoulish monsters, almost like ogres. They were attached to sinful behavior and thus lived mostly in the mode of darkness. Hanuman reached the shores of Lanka and then entered the city in a guise difficult to spot. Since he had mastery over every yogic siddhi, or mystical perfection, Hanuman could change the size of his stature at will. Taking on a form having the dimensions of a cat, Hanuman scurried through the city and searched different places looking for Sita. But he could not find her. Instead, he found many beautiful women, all dedicated to their ogre-like husbands. The women were looking very nice, but Hanuman could not be distracted.
Normally, seeing such opulence and beauty would bring some pleasure to the mind. After all, the entire aim of sightseeing is to gaze at amazing wonders, things that are not seen in ordinary life. Living in the forest his whole life, Hanuman was not accustomed to the wonderful opulence found in Lanka. But from the above referenced passage from the Ramayana, we see that he was still dejected even after having gone on a most wonderful visual tour. Since he was searching for Sita, it’s safe to assume that Hanuman noted every inch of space within Lanka. Therefore he was well acquainted with the city and its inhabitants; yet he was still unhappy.
HanumanTo give us an indication of why Hanuman was not pleased, some of Sita Devi’s foremost qualities are listed. These stand in stark contrast to the qualities possessed by any normal person, let alone the queens in Lanka. Sita was eternally chaste, as Ravana had tried to win her over many times, but she flat out refused. Sita Devi is actually the goddess of fortune and her husband the Supreme Lord Narayana. Their time on earth was like the showing of a play, with the actors playing their roles perfectly. If Sita and Rama weren’t divine figures, the Ramayana would be no more important than any ordinary poem. Hanuman’s stature and endearing nature are further enhanced by the fact that he was ever devoted to the Supreme Lord and His wife. Hanuman doesn’t dedicate his life and soul to just ordinary people who have no relation to God.
It is also said that Sita always kept her eyes fixed on Rama. Even when not in the company of her husband, she simply kept her mind’s eye fixed on the Lord, whom yogis, mental speculators and ascetics undergo trials and tribulations to understand. God is always there for those who love Him, and amongst such lovers none can be more dedicated than Sita. These facts were well known to Hanuman, as it is also mentioned in the above passage that Sita was the very mind of her husband and that she was the most exalted woman. God is atmarama; He is in need of nothing. The general tendency for the illusioned soul is to try to see God or find Him in different places. Yet the devotees are so wonderful that the Lord always sees them. Sita Devi, through her devotion and divine qualities, etched a permanent mark in the mind of her husband. Hanuman was fully enthralled just by thinking of Sita’s qualities and her strong devotion. She was the only person he wanted to meet. Even if he saw the most beautiful women and greatest level of opulence, he would still not be deterred in his mission.
Hanuman’s dejection over not having found Sita shows that his enthusiasm for serving Rama was unmatched. While the eagerness to serve can be measured by the behavior shown at the beginning of a task, it can be more accurately ascertained later on down the line. If there is temporary failure or things don’t go as planned, the reaction of the worker provides the best indication of their interest in the mission. Hanuman showed eagerness at the beginning of the task, and he also had references to his qualities given by Sugriva. Yet when he felt such strong dejection after having not found Sita in Lanka, Hanuman showed that he took the mission as seriously as Rama did.
Hanuman thinking of Sita and RamaSita and Rama are Hanuman’s very life and soul, and his enthusiasm towards pleasing them is unmatched. Because of this eagerness, he would eventually succeed. Hanuman only wants to think of God and sing His glories. Through accepting difficult missions assigned to him, Hanuman further glorifies the Supreme Lord by showing the benefits ofdevotional service. While Sita and Rama are worshipable for their divine qualities, wonderful nature and kind-heartedness, their glories are further increased by the brilliance of their most enthusiastic servant, Shri Hanuman. Whoever is fortunate enough to remember Hanuman for who he is and honor and respect his level of dedication will never be out of favor with God. To them will come the rarest, most unique and most valuable gift of all: divine love.

"Shiva moon" - Prem Joshua

Environmental Pollution





Environmental Pollution


Table of Contents
1. Pollution (definition)
2. Water Pollution
3. Thermal Pollution
4. Land Pollution
5. Pestiside Pollution
6. Radiation Pollution
7. Noise Pollution
8. Air Pollution





Pollution - Environmental pollution is any discharge of material or energy into water, land, or air that causes or may cause acute (short-term) or chronic (long-term) detriment to the Earth's ecological balance or that lowers the quality of life. Pollutants may cause primary damage, with direct identifiable impact on the environment, or secondary damage in the form of minor perturbations in the delicate balance of the biological food web that are detectable only over long time periods.

Until relatively recently in humanity's history, where pollution has existed, it has been primarily a local problem. The industrialization of society, the introduction of motorized vehicles, and the explosion of the human population, however, have caused an exponential growth in the production of goods and services. Coupled with this growth has been a tremendous increase in waste by-products. The indiscriminate discharge of untreated industrial and domestic wastes into waterways, the spewing of thousands of tons of particulates and airborne gases into the atmosphere, the "throwaway" attitude toward solid wastes, and the use of newly developed chemicals without considering potential consequences have resulted in major environmental disasters, including the formation of smog in the Los Angeles area since the late 1940s and the pollution of large areas of the Mediterranean Sea. Technology has begun to solve some pollution problems (see pollution control), and public awareness of the extent of pollution will eventually force governments to undertake more effective environmental planning and adopt more effective antipollution measures.


Different Types of Pollution

 WATER POLLUTION

Water pollution is the introduction into fresh or ocean waters of chemical, physical, or biological material that degrades the quality of the water and affects the organisms living in it. This process ranges from simple addition of dissolved or suspended solids to discharge of the most insidious and persistent toxic pollutants (such as pesticides, heavy metals, and nondegradable, bioaccumulative, chemical compounds).

    Conventional
    Conventional or classical pollutants are generally associated with the direct input of (mainly human) waste products. Rapid urbanization and rapid population increase have produced sewage problems because treatment facilities have not kept pace with need. Untreated and partially treated sewage from municipal wastewater systems and septic tanks in unsewered areas contribute significant quantities of nutrients, suspended solids, dissolved solids, oil, metals (arsenic, mercury, chromium, lead, iron, and manganese), and biodegradable organic carbon to the water environment.

Conventional pollutants may cause a myriad of water pollution problems. Excess suspended solids block out energy from the Sun and thus affect the carbon dioxide-oxygen conversion process, which is vital to the maintenance of the biological food chain. Also, high concentrations of suspended solids silt up rivers and navigational channels, necessitating frequent dredging. Excess dissolved solids make the water undesirable for drinking and for crop irrigation.

Although essential to the aquatic habitat, nutrients such as nitrogen and phosphorus may also cause overfertilization and accelerate the natural aging process (eutrophication) of lakes. This acceleration in turn produces an overgrowth of aquatic vegetation, massive algal blooms, and an overall shift in the biologic community--from low productivity with many diverse species to high productivity with large numbers of a few species of a less desirable nature. Bacterial action oxidizes biodegradable organic carbon and consumes dissolved oxygen in the water. In extreme cases where the organic-carbon loading is high, oxygen consumption may lead to an oxygen depression: (less than 2 mg/l compared with 5 to 7 mg/l for a healthy stream) is sufficient to cause a fish kill and seriously to disrupt the growth of associated organisms that require oxygen to survive.

Nonconventional
The nonconventional pollutants include dissolved and particulate forms of metals, both toxic and nontoxic, and degradable and persistent organic carbon compounds discharged into water as a by-product of industry or as an integral part of marketable products. More than 13,000 oil spills of varying magnitude occur in the United States each year. Thousands of environmentally untested chemicals are routinely discharged into waterways; an estimated 400 to 500 new compounds are marketed each year. In addition, coal strip mining releases acid wastes that despoil the surrounding waterways. Nonconventional pollutants vary from biologically inert materials such as clay and iron residues to the most toxic and insidious materials such as halogenated hydrocarbons (DDT, kepone, mirex, and polychlorinated biphenyls--PCB). The latter group may produce damage ranging from acute biological effects (complete sterilization of stretches of waterways) to chronic sublethal effects that may go undetected for years. The chronic low-level pollutants are proving to be the most difficult to correct and abate because of their ubiquitous nature and chemical stability.

THERMAL POLLUTION
Thermal pollution is the discharge of waste heat via energy dissipation into cooling water and subsequently into nearby waterways. The major sources of thermal pollution are fossil-fuel and nuclear electric-power generating facilities and, to a lesser degree, cooling operations associated with industrial manufacturing, such as steel foundries, other primary-metal manufacturers, and chemical and petrochemical producers.
The discharge temperatures from electric-power plants generally range from 5 to 11 C degrees (9 to 20 F degrees) above ambient water temperatures. An estimated 90% of all water consumption, excluding agricultural uses, is for cooling or energy dissipation.
 The discharge of heated water into a waterway often causes ecologic imbalance, sometimes resulting in major fish kills near the discharge source. The increased temperature accelerates chemical-biological processes and decreases the ability of the water to hold dissolved oxygen. Thermal changes affect the aquatic system by limiting or changing the type of fish and aquatic biota able to grow or reproduce in the waters. Thus rapid and dramatic changes in biologic communities often occur in the vicinity of heated discharges.

LAND POLLUTION
Land pollution is the degradation of the Earth's land surface through misuse of the soil by poor agricultural practices, mineral exploitation, industrial waste dumping, and indiscriminate disposal of urban wastes.
    Soil Misuse
    Soil erosion--a result of poor agricultural practices--removes rich humus topsoil developed over many years through vegetative decay and microbial degradation and thus strips the land of valuable nutrients for crop growth. Strip mining for minerals and coal lays waste thousands of acres of land each year, denuding the Earth and subjecting the mined area to widespread erosion problems. The increases in urbanization due to population pressure presents additional soil-erosion problems; sediment loads in nearby streams may increase as much as 500 to 1,000 times over that recorded in nearby undeveloped stretches of stream. Soil erosion not only despoils the Earth for farming and other uses, but also increases the suspended-solids load of the waterway. This increase interferes with the ecological habitat and poses silting problems in navigation channels, inhibiting the commercial use of these waters.

Solid Waste
In the United States in 1988 municipal wastes alone--that is, the solid wastes sent by households, business, and municipalities to local landfills and other waste-disposal facilities--equaled 163 million metric tons (1980 million U.S. tons), or 18 k (40lb) per person, according to figures released by the Environmental Protection Agency. Additional solid wastes accumulate from mining, industrial production, and agriculture. Although municipal wastes are the most obvious, the accumulations of other types of wastes are the most obvious, the accumulations of other types of waste are far greater, in many instances are more difficult to dispose of, and present greater environmental hazards.

The most common and convenient method of disposing of municipal solid wastes is in the sanitary landfill. The open dump, once a common eyesore in towns across the United States, attracted populations of rodents and other pests and often emitted hideous odors; it is now illegal. Sanitary landfills provide better aesthetic control and should be odor-free. Often, however, industrial wastes of unknown content are commingled with domestic wastes. Groundwater infiltration and contamination of water supplies with toxic chemicals have recently led to more active control of landfills and industrial waste disposal. Careful management of sanitary landfills, such as providing for leachate and runoff treatment as well as daily coverage with topsoil, has alleviated most of the problems of open dumping. In many areas, however, space for landfills is running out and alternatives must be found.

Recycling of materials is practical to some extent for much municipal and some industrial wastes, and a small but growing proportion of solid wastes is being recycled. When wastes are commingled, however, recovery becomes difficult and expensive. New processes of sorting ferrous and nonferrous metals, paper, glass, and plastics have been developed, and many communities with recycling programs now require refuse separation. Crucial issues in recycling are devising better processing methods, inventing new products for the recycled materials, and finding new markets for them.

Incineration is another method for disposing of solid wastes. Advanced incinerators use solid wastes as fuel, burning quantities of refuse and utilizing the resultant heat to make steam for electricity generation. Wastes must be burned at very high temperatures, and incinerator exhausts must be equipped with sophisticated scrubbers and other devices for removing dioxins and other toxic pollutants. Problems remain, however: incinerator ash contains high ratios of heavy metals, becoming a hazardous waste in itself, and high-efficiency incinerators may discourage the use of recycling and other waste-reduction methods.

Composting is increasingly used to treat some agricultural wastes, as well as such municipal wastes as leaves and brush. Composting systems can produce usable soil conditioners, or humus, within a few months (see compost).

PESTICIDE POLLUTION
Pesticides are organic and inorganic chemicals originally invented and first used effectively to better the human environment by controlling undesirable life forms such as bacteria, pests, and foraging insects. Their effectiveness, however, has caused considerable pollution. The persistent, or hard, pesticides, which are relatively inert and nondegradable by chemical or biologic activity, are also bioaccumulative; that is, they are retained within the body of the consuming organism and are concentrated with each ensuing level of the biologic food chain. For example, DDT provides an excellent example of cumulative pesticide effects. (Although DDT use has been banned in the United States since 1972, it is still a popular pesticide in much of the rest of the world.) DDT may be applied to an area so that the levels in the surrounding environment are less than one part per billion. As bacteria or other microscopic organisms ingest and retain the pesticide, the concentration may increase several hundred- to a thousandfold. Concentration continues as these organisms are ingested by higher forms of life--algae, fish, shellfish, birds, or humans. The resultant concentration in the higher life forms may reach levels of thousands to millions of parts per billion.
Many pesticides are nondiscriminatory; that is, they are not specific for a particular plant or organism. A dramatic example of this effect is DDE (a product of the breakdown of DDT), which effectively inhibits the ability of birds to provide sufficient calcium deposits for their eggs, producing fragile shells and a high percentage of nested eggs that break prematurely. Another reported side effect of pesticides is their effect on the nervous system of animals and fish; they can cause instability, disorientation, and, in some cases, death. These examples are generally a result of relatively high body residuals producing acute (short-term) readily recordable results.
The long-term (chronic) effects of persistent pesticides are virtually unknown, but many scientists believe they are as much an environmental hazard as are the acute effects. Nonpersistent (readily degradable) pesticides or substitutes, insect sterilization techniques, hormone homologues that check or interfere with maturation stages, and introduction of animals that prey on the pests present a potentially brighter picture for pest control with significantly reduced environmental consequences.

RADIATION POLLUTION
Radiation pollution is any form of ionizing or nonionizing radiation that results from human activities. The most well-known radiation results from the detonation of nuclear devices and the controlled release of energy by nuclear-power generating plants (see nuclear energy). Other sources of radiation include spent-fuel reprocessing plants, by-products of mining operations, and experimental research laboratories. Increased exposure to medical X rays and to radiation emissions from microwave ovens and other household appliances, although of considerably less magnitude, all constitute sources of environmental radiation.
Public concern over the release of radiation into the environment greatly increased following the disclosure of possible harmful effects to the public from nuclear weapons testing, the accident (1979) at the Three Mile Island nuclear-power generating plant near Harrisburg, Pa., and the catastrophic 1986 explosion at Chernobyl, a Soviet nuclear power plant. In the late 1980s, revelations of major pollution problems at U.S. nuclear weapons reactors raised apprehensions even higher.
The environmental effects of exposure to high-level ionizing radiation have been extensively documented through postwar studies on individuals who were exposed to nuclear radiation in Japan. Some forms of cancer show up immediately, but latent maladies of radiation poisoning have been recorded from 10 to 30 years after exposure. The effects of exposure to low-level radiation are not yet known. A major concern about this type of exposure is the potential for genetic damage.
Radioactive nuclear wastes cannot be treated by conventional chemical methods and must be stored in heavily shielded containers in areas remote from biological habitats. The safest of storage sites currently used are impervious deep caves or abandoned salt mines. Most radioactive wastes, however, have half-lives of hundreds to thousands of years, and to date no storage method has been found that is absolutely infallible.
NOISE POLLUTION
Noise pollution has a relatively recent origin. It is a composite of sounds generated by human activities ranging from blasting stereo systems to the roar of supersonic transport jets. Although the frequency (pitch) of noise may be of major importance, most noise sources are measured in terms of intensity, or strength of the sound field. The standard unit, one decibel (dB), is the amount of sound that is just audible to the average human. The decibel scale is somewhat misleading because it is logarithmic rather than linear; for example, a noise source measuring 70 dB is 10 times as loud as a source measuring 60 dB and 100 times as loud as a source reading 50 dB. Noise may be generally associated with industrial society, where heavy machinery, motor vehicles, and aircraft have become everyday items. Noise pollution is more intense in the work environment than in the general environment, although ambient noise increased an average of one dB per year during the 1980s. The average background noise in a typical home today is between 40 and 50 decibels. Some examples of high-level sources in the environment are heavy trucks (90 dB at 15 m/50 ft), freight trains (75 dB at 15 m/50 ft), and air conditioning (60 dB at 6 m/20 ft).
The most readily measurable physiological effect of noise pollution is damage to hearing, which may be either temporary or permanent and may cause disruption of normal activities or just general annoyance. The effect is variable, depending upon individual susceptibility, duration of exposure, nature of noise (loudness), and time distribution of exposure (such as steady or intermittent). On the average an individual will experience a threshold shift (a shift in an individual's upper limit of sound detectability) when exposed to noise levels of 75 to 80 dB for several hours. This shift will last only several hours once the source of noise pollution is removed. A second physiologically important level is the threshold of pain, at which even short-term exposure will cause physical pain (130 to 140 dB). Any noise sustained at this level will cause a permanent threshold shift or permanent partial hearing loss. At the uppermost level of noise (greater than 150 dB), even a single short-term blast may cause traumatic hearing loss and physical damage inside the ear.
Although little hard information is available on the psychological side effects of increased noise levels, many researchers attribute increased irritability, lower productivity, decreased tolerance levels, increased incidence of ulcers, migraine headaches, fatigue, and allergic responses to continued exposures to high-level noises in the workplace and the general environment.
AIR POLLUTION
Air pollution is the accumulation in the atmosphere of substances that, in sufficient concentrations, endanger human health or produce other measured effects on living matter and other materials. Among the major sources of pollution are power and heat generation, the burning of solid wastes, industrial processes, and, especially, transportation. The six major types of pollutants are carbon monoxide, hydrocarbons, nitrogen oxides, particulates, sulfur dioxide, and photochemical oxidants.
    Local and Regional
    Smog has seriously affected more persons than any other type of air pollution. It can be loosely defined as a multisource, widespread air pollution that occurs in the air of cities. Smog, a contraction of the words smoke and fog, has been caused throughout recorded history by water condensing on smoke particles, usually from burning coal. The infamous London fogs--about 4,000 deaths were attributed to the severe fog of 1952--were smog of this type. Another type, ice fog, occurs only at high latitudes and extremely low temperatures and is a combination of smoke particles and ice crystals.
As a coal economy has gradually been replaced by a petroleum economy, photochemical smog has become predominant in many cities. Its unpleasant properties result from the irradiation by sunlight of hydrocarbons (primarily unburned gasoline emitted by automobiles and other combustion sources) and other pollutants in the air. Irradiation produces a long series of photochemical reactions (see photochemistry). The products of the reactions include organic particles, ozone, aldehydes, ketones, peroxyacetyl nitrate, and organic acids and other oxidants. Sulfur dioxide, which is always present to some extent, oxidizes and hydrates to form sulfuric acid and becomes part of the particulate matter. Furthermore, automobiles are polluters even in the absence of photochemical reactions. They are responsible for much of the particulate material in the air; they also emit carbon monoxide, one of the most toxic constituents of smog.

All types of smog decrease visibility and, with the possible exception of ice fog, are irritating to the respiratory system. Statistical studies indicate that smog is a contributor to malignancies of many types. Photochemical smog produces eye irritation and lacrimation and causes severe damage to many types of vegetation, including important crops. Acute effects include an increased mortality rate, especially among persons suffering from respiratory and coronary ailments. Air pollution also has a deleterious effect on works of art (see art conservation and restoration).

Air pollution on a regional scale is in part the result of local air pollution--including that produced by individual sources, such as automobiles--that has spread out to encompass areas of many thousands of square kilometers. Meteorological conditions and landforms can greatly influence air-pollution concentrations at any given place, especially locally and regionally. For example, cities located in bowls or valleys over which atmospheric inversions form and act as imperfect lids are especially likely to suffer from incidences of severe smog. Oxides of sulfur and nitrogen, carried long distances by the atmosphere and then precipitated in solution as acid rain, can cause serious damage to vegetation, waterways, and buildings.

Global
Humans also pollute the atmosphere on a global scale, although until the early 1970s little attention was paid to the possible deleterious effects of such pollution. Measurements in Hawaii suggest that the concentration of carbon dioxide in the atmosphere is increasing at a rate of about 0.2% every year. The effect of this increase may be to alter the Earth's climate by increasing the average global temperature. Certain pollutants decrease the concentration of ozone occurring naturally in the stratosphere, which in turn increases the amount of ultraviolet radiation reaching the Earth's surface. Such radiation may damage vegetation and increase the incidence of skin cancer. Examples of stratospheric contaminants include nitrogen oxides emitted by supersonic aircraft and chlorofluorocarbons used as refrigerants and aerosol-can propellants. The chlorofluorocarbons reach the stratosphere by upward mixing from the lower parts of the atmosphere (see ozone layer). It is believed that these chemicals are responsible for the noticeable loss of ozone over the polar regions that has occurred in the 1980s.

Special thanks to the ©1998 Environmental Protection Agency for allowing us to post this on our web site.

Petroleum





Petroleum is a naturally occurring liquid oil normally found in deposits beneath the surface of the earth. It is a type of oil composed of rock minerals, making it different from other kinds of oils that come from plants and animals (such as vegetable oil, animal fat, or essential oils). The word petroleum comes from the Latin words petra (rock) and oleum (oil), and so literally means rock oil. Despite this, petroleum is an organic compound, formed from the remains of microorganisms living millions of years ago. It is one of the three main fossil fuels, along with coal and natural gas.

Petroleum Economy

Petroleum, like all fossil fuels, primarily consists of a complex mixture of molecules called hydrocarbons (molecules containing both hydrogen and carbon). When it comes out of the ground, it is known as crude oil, and it may have various gases, solids, and trace minerals mixed in with it. Through refinement processes, a variety of consumer products can be made from petroleum. Most of these are fuels: gasoline, jet fuel, diesel fuel, kerosene, and propane are common examples. It is also used to make asphalt and lubricant grease, and it is a raw material for synthetic chemicals. Chemicals and materials derived from petroleum products include plastics, pesticides, fertilizers, paints, solvents, refrigerants, cleaning fluids, detergents, antifreeze, and synthetic fibers.
The modern petroleum industry began in 1859 in Pennsylvania, when a man named Edwin L. Drake constructed the first oil well, a facility for extracting petroleum from natural deposits. Since then, petroleum has become a valuable commodity in industrialized parts of the world, and oil companies actively search for petroleum deposits and build large oilextraction facilities. Several deposits exist in the United States. However, around 1960 oil production in the country began to decline as oil in the deposits was being used up and fewer new deposits were being discovered. Demand for petroleum products continued to increase, and as a result the United States came to rely more and more on oil imported from other countries. In 2001 the amount of petroleum extracted from deposits in the United States was estimated to be only one-third of the amount demanded by U.S. consumers. A similar pattern exists in other industrialized countries, and some, like Japan and Germany, import almost all of the oil they use.
Ten Largest Oil Spills in History (By Volume)

TEN LARGEST OIL SPILLS IN HISTORY (BY VOLUME)
LocationDateAmount Spilled
SOURCE: Oil Spill Intelligence Report (1999). International Oil Spill Statistics: 1998. New York: Aspen Publishers. Available from www.aspenpublishers.com/environment.asp
1. Sea Island Installations, Persian Gulf, KuwaitJanuary 26, 1991240,000,000 gallons (816,327 tons)
2. Ixtoc I exploratory well, Bahia del Campeche, MexicoJune 3, 1979140,000,000 gallons (476,190 tons)
3. Production well, Fergana Valley, UzbekistanMarch 2, 199288,000,000 gallons (299,320 tons)
4. Nowruz No. 3 well, Persian Gulf, Nowruz Field, IranFebruary 4, 198380,000,000 gallons (272,109 tons)
5. Tanker Castillo de Bellver , Table Bay, South AfricaAugust 6, 198378,500,000 gallons (267,007 tons)
6. Tanker Amoco Cadiz , off Portsall, Brittany, FranceMarch 16, 197868,668,000 gallons (233,565 tons)
7. Tanker Odyssey , North Atlantic Ocean, off St. John's, Newfoundland, CanadaNovember 10, 198843,100,000 gallons (146,600 tons)
8. Tanker Atlantic Empress , Caribbean Sea, Trinidad and TobagoJuly 19, 197942,704,000 gallons (145,252 tons)
9. Tanker Haven , Genoa, ItalyApril 11, 199142,000,000 gallons (142,857 tons)
10. Production well D-103, 800 km southeast of Tripoli, LibyaAugust 1, 198042,000,000 gallons (142,857 tons)



However, on a per capita basis, the consumption in these countries is nowhere near the consumption in the United States.
The United States and Canada are unique in that, on average, an individual in these countries consumes about twice as much petroleum product as do individuals in most other industrialized nations. People in the United States and Canada rely more on personal vehicles for their transportation and tend to drive greater distances, making petroleum their major source of energy. In the United States, about two-thirds of the petroleum consumed is transportation fuel, and two-thirds of that (45% of the total) is gasoline for cars and trucks. About 40 percent of the energy used in the United States every year comes from petroleum.

Foreign Oil Dependence

Political leaders in the United States have long been gravely concerned about the country's growing dependence on foreign oil, which in many ways puts the country at the mercy of foreign governments, some of them hostile to the United States. The greatest production of crude oil in the world is in the Persian Gulf region of the Middle East, where about 65 percent of the world's known petroleum deposits are located. About half of U.S. imports come from members of the Organization of the Petroleum Exporting Countries (OPEC), a group of countries encompassing the Persian Gulf and certain parts of Africa and South America. Events in these often volatile regions can have a huge impact on oil prices in the United States and worldwide, and because of the crucial role oil plays in U.S. society any change in the price can precipitate uncontrollable shifts in the country's economy (see chart "World Oil Price 1970-2000"). The most famous example of this is the Arab Oil Embargo of 1973 to 1974, when U.S. support for Israel in a conflict in the Middle East led to a decision by OPEC to impose steep price increases on the sale of oil to the United States. One response by the U.S. government has been the establishment of the Strategic Petroleum Reserve, an emergency stockpile designed to sustain the country's oil needs for approximately three months in the event of a complete cutoff of imports. There is little doubt, however, that dependence on foreign oil is both a political liability for the United States as well as a risk to national security.

Workers using water hoses to clean oil from a beach following a spill. (United States Environmental Protection Agency. Reproduced by permission.)
Workers using water hoses to clean oil from a beach following a spill. (
United States Environmental Protection Agency. Reproduced by permission.
)

Environmental Pollution

Petroleum-derived contaminants constitute one of the most prevalent sources of environmental degradation in the industrialized world. In large concentrations, the hydrocarbon molecules that make up crude oil and petroleum products are highly toxic to many organisms, including humans. Petroleum also contains trace amounts of sulfur and nitrogen compounds, which are dangerous by themselves and can react with the environment to produce secondary poisonous chemicals. The dominance of petroleum products in the United States and the world economy creates the conditions for distributing large amounts of these toxins into populated areas and ecosystems around the globe.

Smoke is pouring from a refinery burnoff vent. (© Royalty-Free/Corbis. Reproduced by permission.)
Smoke is pouring from a refinery burnoff vent. (
© Royalty-Free/Corbis. Reproduced by permission.
)

Oil Spills

Perhaps the most visible source of petroleum pollution are the catastrophic oil-tanker spills—like the 1989 Exxon Valdez spill in Prince William Sound, Alaska—that make news headlines and provide disheartening pictures of oilcoated shorelines and dead or oiled birds and sea animals. These spills occur during the transportation of crude oil from exporting to importing nations. Crude oil travels for long distances by either ocean tanker or land pipeline, and both methods are prone to accidents. Oil may also spill at the site where it is extracted, as in the case of a blowout like the Ixtoc I exploratory well in 1979 (see table "Ten Largest Oil Spills in History"). A blowout is one of the major risks of drilling for oil. It occurs when gas trapped inside the deposit is at such a high pressure that oil suddenly erupts out of the drill shaft in a geyser.
Accidents with tankers, pipelines, and oil wells release massive quantities of petroleum into land and marine ecosystems in a concentrated form. The ecological impacts of large spills like these have only been studied for a very
World Oil Price 1970-2000
World Oil Price 1970-2000 (
World Oil Market and Price Chronologies DOE Energy Information Administration ; originally published by the Department of Energy's Office of the Strategic Petroleum Reserve, Analysis Division
)
few cases, and it is not possible to say which have been the most environmentally damaging accidents in history. A large oil spill in the open ocean may do less harm to marine organisms than a small spill near the shore. The Exxon Valdez disaster created a huge ecological disaster not because of the volume of oil spilled (eleven million gallons) but because of the amount of shoreline affected, the sensitivity and abundance of organisms in the area, and the physical characteristics of the Prince William Sound, which helped to amplify the damage. The Exxon Valdez spill sparked the most comprehensive and costly cleanup effort ever attempted, and called more public attention to oil accidents than ever before. Scientific studies of the effects of oil in Prince William Sound are ongoing, and the number of tanker accidents worldwide has decreased significantly since the time of the Valdez spill, due to stricter regulations and such required improvements in vessel design as double-hull construction.

Nonpoint Sources

Spills from tankers, pipelines, and oil wells are examples of point sources of pollution, where the origin of the contaminants is a single identifiable point. They also represent catastrophic releases of a large volume of pollutants in a short period of time. But the majority of pollution from oil is from nonpoint sources, where small amounts coming from many different places over a long period of time add up to large-scale effects. Seventy percent of the oil released by human activity into oceans worldwide is a result of small spills during petroleum consumption. These minor unreported spills can include routine discharges of fuel from commercial vessels or leakage from recreational boats. However, in North America, the majority of the release originates on land. Oil tends to collect in hazardous concentrations in the stream of wastewater coming out of cities and other populated areas. Runoff from asphalt-covered roads and parking lots enters storm drains, streams, and lakes and eventually travels to the ocean, affecting all of the ecosystems through which it passes. As cities grow, more and more people use petroleum products—lubricants, solvents, oil-based paint, and, above all, gasoline—and these are often improperly disposed of down drains and sewage pipes. Industrial plants also produce small, chronic spills that aren't noticed individually, but add up over time and enter waterways.
Taken together, land-based river and urban runoff sources constitute over half of the petroleum pollution introduced to North American coastal waters due to human activity, and 20 percent of the petroleum pollution introduced to ocean waters worldwide. When wastewater from these sources enters the marine environment it is usually by means of an estuary, an area where freshwater from land mixes with seawater. Estuaries are especially critical habitats for a variety of plants and animals, and are among the ecosystems most sensitive to pollutants.

Petroleum-Contaminated Soil

Not all oil released from land sources is quickly washed away to sea, however. Pipeline and oil-well accidents, unregulated industrial waste, and leaking underground storage tanks can all permanently contaminate large areas of soil, making them economically useless as well as dangerous to the health of organisms living in and around them. Removing or treating soil contaminated by petroleum is especially urgent because the hydrocarbons can leach into the underlying groundwater and move into human residential areas. The engineering field of bioremediation has emerged in recent decades as a response to this threat. In bioremediation, bacteria that feed on hydrocarbons and transform them into carbon dioxide can be applied to an affected area. Bioremediation has in many cases made cleaning up petroleum-contaminated sites a profitable real-estate investment for land developers.

Air Pollution

The U.S. Environmental Protection Agency (EPA) designates six criteria pollutants for determining air quality. These are: carbon monoxide (CO), nitrogen oxides (NO and/or NO , usually referred to as NO ), sulfur dioxide (SO ), ground-level ozone (O ), particulate matter (including things like soot, dust, asbestos fibers, pesticides, and metals), and lead (Pb). Petroleum-fueled vehicles, engines, and industrial processes directly produce the vast majority of CO and NO in the atmosphere. They are also the principal source of gaseous hydrocarbons (also called volatile organic compounds, or VOCs), which combine with NO in sunlight to create O . Ozone, while important for blocking ultraviolet rays in the upper atmosphere, is also a key component of urban smog and creates human health problems when present in the lower atmosphere. Sulfur dioxide is a trace component of crude oil, and can cause acid rain when released into the air at oil refineries or petroleum power plants. Particulate matter is directly emitted in vehicle exhaust and can also form from the reaction of exhaust gases with water vapor and sunlight. Finally, leaded gasoline is a huge contributor of lead to the atmosphere, and the use of unleaded gasoline has decreased lead concentrations dramatically. The EPA and the World Bank are working to encourage the phaseout of leaded gasoline worldwide.
Petroleum-fueled transportation and coal-burning power plants are considered the chief causes of global warming. Excess amounts of carbon dioxide, methane, and NO , among other gases, trap heat in the atmosphere and create the greenhouse effect. Carbon dioxide (CO ) is a main constituent of petroleum fuel exhaust, even though it is not toxic and therefore not classified as a pollutant. About one-third of the CO emitted into the atmosphere every year comes from vehicle exhaust. Methane (NH ), although usually associated with natural gas, is also emitted whenever crude oil is extracted, transported, refined, or stored.

The Future of Petroleum

The world's reliance on petroleum is expected to grow, despite widespread environmental, economic, and political consequences. The U.S. oil extraction industry continues to aggressively search for new oil deposits and lobby the federal government to open up restricted areas to drilling. The Arctic National Wildlife Refuge in Alaska has been on the oil industry agenda for several decades, creating a long-standing environmental controversy. Advances in oil well technology have allowed extraction in the deep ocean beyond the continental shelf, but these have not been enough to reverse the trend of declining production in the United States.
There are many compelling reasons to decrease society's dependence on petroleum for energy, and the most obvious place to begin is in the transportation sector. Energy-efficient engines and hybrid gas/electric cars can help to reduce some of the need for oil, providing higher gas mileage and less demand. A variety of alternative fuels have also been developed, such as ethanol, biodiesel (made from vegetable oil), and hydrogen. Each of these would produce little or no exhaust pollutants or greenhouse gases, and each derives from plentiful renewable resources. The United States is now in fact actively researching hydrogen as a viable alternative to gasoline, and the hydrogen fuel cell as a substitute for the internal combustion engine.
Petroleum is a useful chemical substance for many important purposes. But it is also a nonrenewable resource with a highly toxic composition, and it poses significant problems when used in huge volumes throughout the industrialized world.
SEE ALSO A IR P OLLUTION ; A RCTIC N ATIONAL W ILDLIFE R EFUGE ; C OAL ;  
D ISASTERS: O IL S PILLS ; E CONOMICS ; E LECTRIC P OWER ; E NERGY ; 
F OSSIL F UELS ; G LOBAL W ARMING ; O ZONE ; NO 
R ENEWABLE E NERGY ; S ULFUR D IOXIDE ;  
U NDERGROUND S TORAGE T ANKS ; V EHICULAR P OLLUTION .

Bibliography

Oil Spill Intelligence Report. (1997). Oil Spills from Vessels (1960–1995): An International Historical Perspective. New York: Aspen Publishers.

Internet Resources

Committee on Oil in the Sea, National Research Council. (2003). Oil in the Sea III: Inputs, Fates, and Effects. Washington, D.C.: The National Academies Press. Available from http://www.nap.edu/catalog/10388.html .
Energy Information Administration. "Official Energy Statistics from the U.S. Government." Available from http://www.eia.doe.gov .
Exxon Valdez Oil Spill Trustee Council. "Restoring the Resources Injured by the Exxon Valdez Oil Spill and Understanding Environmental Change in the Northern Gulf of Alaska." Available from http://www.oilspill.state.ak.us .
National Biodiesel Board. "Need a Fill Up?" Available from http://www.biodiesel.org .
National Ethanol Vehicle Coalition. "National Ethanol Vehicle Coalition and E85." Available from http://www.e85fuel.com .
National Oceanic and Atmospheric Administration. "Office of Response and Restoration, National Ocean Service." Available from http://response.restoration.noaa.gov .
Schlumberger Excellence in Educational Development (SEED) Science Center. "Science Lab: Oil Well Blowout Simulator." Available from http://www.slb.com/seed/en/lab/blowout .
Trench, Cheryl J. (2001). "Oil Market Basics." Washington, D.C.: Energy Information Administration. Available from http://www.eia.doe.gov .
U.S. Department of Energy. "Energy Efficiency and Renewable Energy." Available from http://www.eere.energy.gov .
U.S. Department of Energy. "Fossil.energy.gov: A U.S. Department of Energy Web Site." Available from http://www.fossil.energy.gov .
U.S. Department of Energy. "Fossil Fuels: An Energy Education Website." Available from http://www.fossil.energy.gov/education .
U.S. Environmental Protection Agency. (1995). Profile of the Petroleum Refining Industry. Washington, D.C.: U.S. Government Printing Office. Available from http://www.epa.gov .
U.S. Environmental Protection Agency. (1999). Profile of the Oil and Gas Extraction Industry. Washington, D.C.: U.S. Government Printing Office. Available from http://www.epa.gov .
U.S. Environmental Protection Agency. "Air Quality Where You Live." Available from http://www.epa.gov/air/urbanair/index.html .
U.S. Geological Survey. Available from http://www.usgs.gov .
U.S. Geological Survey. (1997). "Bioremediation: Nature's Way to a Cleaner Environment." Available from http://water.usgs.gov/wid/html/bioremed.html .
Adrian MacDonald

OIL SEEPS

Almost half (45%) of the petroleum entering the marine environment is from natural seeps rather than anthropogenic sources. At seeps, oil and gas bubble out of cracks in the seabed creating special environments in which new organisms grow. These organisms survive through chemosynthesis rather than photosynthesis. They live in total darkness, more than four hundred meters below sea level, but survive by feeding directly off the hydrocarbons present in seeps or by eating carbon compounds resulting from chemosynthetic bacterial degradation of seep oil. Since 1984 oceanographers have discovered chemosynthetic communities of clams, mussels, tubeworms, bacterial mats, and other organisms on the seafloor of the Gulf of Mexico. United States Department of the Interior regulations protect these chemosynthetic communities from damage due to oil and gas drilling activities.


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SHIVA - DHYAN SLOK {SRI SHIV MAHIMA,SRI SHIV TANDAV STOTTRAM}.

Tortoise enters temple - Tv9

Thursday, September 1, 2011

ganapati maha sloka

Sankata Nasana Ganapati Stotram Devotional Song - Narada Purana

How the Brain Stores Information for Short Periods of Time





Science Daily  — Freiburg biologist Dr. Aristides Arrenberg and his American colleagues studied mechanisms used by the brain to store information for a short period of time. The cells of several neural circuits store information by maintaining a persistent level of activity: A short-lived stimulus triggers the activity of neurons, and this activity is then maintained for several seconds. The mechanisms of this information storage have not yet been sufficiently described, although this phenomenon occurs in very many areas of the brain.













The persistent activity in the neural integrator for eye positions is never perfect, as the eyes gradually drift back to their point of rest after a saccade. The authors thus had the possibility of measuring the dynamics of the system during spontaneous eye movements in the dark and testing the model without the measurements being distorted by saccade commands or visual feedback.
The authors of the study, now published in the journal Nature Neuroscience, investigated the persistent activity in a hindbrain circuit responsible for eye movements in zebrafish larvae. This circuit, the so-called oculomotor system, gives the command for rapid eye movement by way of special nerve cells that produce a short-lived succession of action potentials. On the one hand, this "burst of fire" reaches the neurons responsible for movement in the eyes and triggers a "saccade," a rapid movement of the eye. On the other hand, it is also transmitted to a second cell population, the so-called neural integrator for eye movements, where the speed signal is integrated mathematically and a position signal is created. This signal is then transmitted to the motor neurons, thus producing -- in fish as well as in humans -- a stable eye position following the rapid eye movement. The neural integrator keeps up this signal for several seconds, until a new saccade is initiated.
The authors discovered that, contrary to previous belief, the cells of the neural integrator for eye movements do not constitute a homogeneous population and that existing models for explaining persistent activity in the oculomotor system will have to be reconsidered. The scientists demonstrated that the integrator neurons do not posses a uniform dynamics and that the neurons are distributed in the hindbrain with the help of their integrator time constants.
These findings provide new evidence on the organization and functioning of circuits with persistent activity and suggest a potential explanation for their low susceptibility to failure. The study is an important milestone in the quest of network neuroscience to explain the functioning of local circuits and thus close the gap between the functioning of a single neuron and the production of behavior.

How coming home changes a soldier's brain



 Psychology & Psychiatry 

The part of the brain that regulates fear normalises 18 months after a soldier returns home, a study found. Credit: The U.S. Army
Soldiers returning from combat have heightened activity in the part of the brain that regulates fear but this usually normalises after around 18 months, a study has found.
The amygdala, the tiny part of the brain that modulates fear, arousal and facial recognition, tends to be overactive in soldiers who have recently returned from deployment, causing increased irritability and heightened sensitivity to perceived threats.
To find out whether these changes were permanent or not, Dutch researchers conducted a series of experiments on 23 combat soldiers who had been deployed for four months to Afghanistan. A group of 16 non-deployed soldiers participated as a control.
The subjects underwent a brain MRI scan while being shown images of angry and fearful faces and were asked to match them with other face images. The tests were done before deployment, shortly after deployment and again a year and a half later.
“Across investigations, amygdala reactivity in the combat group followed a pattern of increased activity shortly after deployment and normalisation at the long-term,” the researchers wrote in their paper, which was published in the journal Molecular Psychiatry Professor Alexander McFarlane, head of the University of Adelaide Centre for Traumatic Stress Studies, said the study was interesting but that it was important to remember that not every returning soldier has the same recovery trajectory.
“And this may have relevance for police where they don’t get removed from the danger, they have constant and ongoing danger,” he said.
“There are certain people in policing roles who have not dissimilar levels of stress but it’s not like they are going through a deployment cycle. It keeps going.”
Professor Peter Warfe, director of the Centre for Military and Veterans' Health at the University of Queensland said the study provided some comforting conclusions.
“It’s reassuring to some extent that [amygdala function] appears to return to normal in this small group of people, presumably none of which were suffering post traumatic stress disorder,” he said.
“What [a return to normal amygdala function] means is a little unclear in terms of their psychological function, their day-to-day physical function and mental capacity,” he said.
“And this study involved small numbers, so I’d be cautious in drawing a broad conclusion,” he said. 

This story is published courtesy of the The Conversation (under Creative Commons-Attribution/No derivatives).
Source: The Conversation
"How coming home changes a soldier's brain." August 31st, 2011. http://medicalxpress.com/news/2011-08-home-soldierbrain.html
Posted by
Robert Karl Stonjek