Saturday, 3 February 2024
Pacific Reef Heron Similar Species:
Thursday, 14 December 2023
Jakob Nacken 7'3'' (221cm)
The gigantic 7'3'' (221cm) Jakob Nacken, an extremely tall Nazi soldier, chatting with 5'3'' (160 cm) Canadian corporal Bob Roberts after surrendering to him near Calais, France in September of 1944 (colorized by PeJae on Reddit).
Tuesday, 10 May 2022
Jude Narita – A Write and Performer
June Narita was born in the 1950s in Long Beach, California, writer and performer Jude Narita studied acting with Stella Adler in New York and with Lee Strasberg in Los Angeles. In spite of her training, Narita was frustrated by the limited roles and opportunities available to Asian-American women. In the 1980s she decided to remedy this situation by writing and performing her own work that would allow her to explore the Asian woman beyond the limiting stereotypes of dragon lady and lotus flower.
Her 1985 one-woman show coming Into Passion / Song for a Sansei was a huge success, running for two years in the Los Angeles area. In the play, she is a newscaster aware of violence against Asians but unwilling to speak out or do anything about it, preferring to be a model minority American citizen. In her dreams, however, she experiences the violence that had hitherto been distanced by detachment. Among others, she becomes a Nisei (second-generation Japanese-American) woman, whose childhood memories are of imprisonment in relocation camps; a prostitute in Saigon during the Vietnam War, thankful for a “good job”; a Filipino woman being interviewed as a potential mail-order bride; a Japanese child in Hiroshima, running scared as the bombs drop.
In the process, she finds herself as a sansei Japanese American, able to address her own past and identify with members of other contemporary Asian-American communities. In Stories Waiting to Be Told, Narita performs plural Asian-American identities—like Japanese, Chinese, Korean, and Cambodian women. Included among the issues addressed by these depictions of the immigrant and post-immigrant generations of Asian women living in America is the trauma of internment camps on Japanese Americans. In this play, Narita plays a daughter who catches a glimpse of her mother’s psychic wounds from the camp. The daughter does not see a victim but a woman of great strength. The play also portrays a lesbian coming to terms with her sexual and ethnic identity as well as with the conflicting demands made by her community.
In Celebrate Me Home, Narita exposes racism perpetuated in thoughtless media images and in cultural stereotypes. This one-woman show uses comedy to address the serious issue of how to develop self-worth and pride in one’s identity amid the limiting stereotypes and limited representation of Asian women (less than 1 percent) in American media and other cultural productions. Narita takes on the media again in Walk the Mountain (directed by her daughter Darling Narita), focusing on the effects of the Vietnam War on women in Vietnam and Cambodia. In this play, Narita’s broad project is clearly to humanize “the faceless enemy” of the United States during the war and to reveal the effects of the misinformation provided to the public by the U.S. media and Hollywood.
Narita’s performances are usually minimal productions, but Walk the Mountain shows slides of burned victims of napalm, the bombing of villages, sobering statistics, and provocative quotes. The production of With Darkness Behind Us, Daylight Has Come was originally funded by the California Civil Liberties Public Education Program (CCLPEP) and the Los Angeles Cultural Affairs Department to broaden awareness of the history of Japanese Americans before, during, and in the wake of World War II. Again Narita uses actual archival footage of the internment camp at Heart Mountain and photographs of the camp and of families in it as the backdrop to this play about the effects of internment on three generations of Japanese-American women.
Monday, 9 May 2022
Economic Depression
Economic Depression During the Revolutionary War, Britain closed its markets to American goods. After the war, the British continued this policy, hoping to keep the United States weak and dependent. Meanwhile, British merchants were happy to satisfy America s pent-up demand for consumer goods after the war. Cheap British imports inundated the American market, and coastal merchants made them available to inland traders and shopkeepers by extending easy credit terms.
In turn, these local businessmen sold the goods to farmers and artisans in the interior. Ultimately, however, the British merchants required payment in hard currency, gold, and silver coins. Without access to its former export markets, America s only source of hard currency was foreign loans obtained by Congress and what money the French army had spent during the war.
This was soon exhausted, and America s trade deficit with Britain the excess of imports over exports ballooned in the early 1780s (see Figure 7 2). The result was an immense bubble of credit that finally burst in 1784, triggering a depression that would linger for most of the decade. As merchants began to press debtors for immediate payment, prices collapsed (they fell more than 25 percent between 1784 and 1786), and debtors were unable to pay.
The best most could hope for was to avoid bankruptcy. In the cities, wages fell 25 percent between 1785 and 1789, and workers began to organize. They called for tariffs to protect them from cheap British imports and for legislative measures to promote American manufacturers. In the countryside, farmers faced lawsuits for the collection of debts and the dread possibility of losing their land. With insufficient money in circulation to raise prices and reverse the downturn, the depression fed on itself.
Congress was powerless to raise cash and was unable to pay off its old debts, including what it owed to the Revolutionary soldiers. Many state governments made things worse by imposing heavy taxes payable in the paper money they had issued during the Revolution. The result was to further reduce the amount of money in circulation, thus increasing deflationary pressures and forcing prices still lower. Britain s trade policies caused particular suffering among New England merchants. No longer protected under the old Navigation Acts as British vessels, American ships were now barred from most ports in the British trading empire.
Incoming cargoes from the West Indies to New England fell off sharply, and the market for whale oil and fish, two of New England s major exports, dried up. In the southern states, British policies compounded the problem of recovering from the physical damage and labor disruptions inflicted by the war. Some 10 percent of the region s slaves had fled during the war, and production levels on plantations fell in the 1780s.
Chesapeake planters needed a full decade to restore the prewar output of tobacco, and a collapse in tobacco prices in 1785 left most of them in the same chronic state of indebtedness that had plagued them on the eve of the Revolution. Farther south, in the Carolina low country, the plantation economy was crippled. War damage had been extensive, and planters piled up debts to purchase additional slaves and repair their plantations and dikes.
Burdened by new British duties on American rice, planters saw their rice exports fall by 50 percent. By the late 1780s, the worst of the depression was over and an upturn was underway in the mid-Atlantic states. Food exports to continental Europe were on the rise, and American merchants were developing new trading ties with India and China.
Commercial treaties with the Dutch, Swedes, and Prussians also opened up markets that had been closed to the colonists. Nonetheless, full recovery had to await the 1790s. As the economy stagnated in the 1780s, the population was growing rapidly. There were 50 percent more Americans in 1787 than there had been in 1775. As a result, living standards fell and economic conflict dominated the politics of the states during the Confederation period.
Saturday, 18 December 2021
When did acrobats first appear?
An interesting thing about a man is that he has always liked to be entertained. From the very beginning of civilization, there have been acrobat jugglers, animal trainers, and clowns to provide this entertainment so we cannot really know when the first acrobats appeared. But when we think of acrobats today we think of the circus. And by going back to the first circus, we can get an idea of how today’s kinds of acrobats originated. The first and largest circus of ancient times was the Circus Maximums in Rome. It was first begun in the third century B.C. and was chiefly built for chariot races. But the atmosphere of that circus was very much like some of ours today.
It was great big entertainment for the masses. At the same time, in other theatres, all kinds of entertainment were available such as we associate with the circus today. There were jugglers, acrobats, ropewalkers, and animal trainers. For about a thousand years after Roman times, the “organized” kind of circus disappeared. There were wandering groups of performers —and they included acrobats, jugglers, and ropewalkers. The first time acrobats appeared in a regular kind of circus again was in England in 1768. They appeared together with clowns and rope- walkers, and people who did trick riding on horses. So you see that acrobats have been entertaining people for thousands of years—and are still among the favorite performers in a circus.
Wednesday, 15 September 2021
HAWK, HAWAIIAN
HAWK, HAWAIIAN
RANGE:
Primarily the Island of Hawaii, occasionally seen on Kauai, Oahu, and Maui
HABITAT:
Rainforest, hardwood and guava forest, papaya and macadamia nut orchards, eucalyptus stands and pastureland with scattered large ‘ohi ‘a and/or koa trees.
SIZE:
The male is smaller than the female, the average male weight is 441g; the weight of the average female is 605g. The body length is from 15 ½ to 18 inches.
LIFE EXPECTANCY:
25 to 30 years
REPRODUCTION:
Hawaiian hawks are monogamous, in that a pair will mate and be loyal to each other for one or more years. However, they do not mate for life, they may change mates at the beginning of some subsequent breeding season. They have a regular breeding season even though there may be a great deal of difference in the amount of rainfall in a given year or on different islands. Courtship consists of much soaring, diving, and foot touching. Both the male and the female build the nest and incubate the 1 to 3 eggs that are laid in late April or early May. The young birds hatch in late May to late June after an incubation period of approximately 38 days. The male provides most of the food for the first 4 to 5 weeks, with the female doing all of the feedings of the young. The female begins leaving the nest for short periods of time the 5th week. The young fledge at 9 weeks. Both parents bring prey for the juveniles for 25 to 37 weeks after fledging. If a pair successfully raises young one year, they will probably not breed the following year.
DIET:
Wild: 23 species of birds, 6 species of mammals, 7 species of insects and spiders, 1 species of crustacean, and 1 species of amphibian. Before the arrival of Polynesian and European men, the Hoary bat was the only mammal on the island, so the hawks probably existed mainly on a diet of birds. Zoo: 3 to 4 mice per bird daily except for Sunday when they fast.
BEHAVIOR:
They make a high, squeaking call that sounds like “kee-oh”. This is the only diurnal raptor that is native to the Island of Hawaii. It is very territorial. Most, but not all, mate for life. Soars and swoops, hunts on the wing but does not hover. When perched, the wingtips fall short of the tip of the tail.
POINTS OF INTEREST:
Two-color phases:
The dark morph adults are dark brown on their head, body, covert, and tail, except for silvery undersides of flight feathers and whitish under-tail coverts. Juveniles are very similar to adults but have tawny streaks and bars on the underside. The light morph adults have a brown head and upperparts and whitish underparts with dark streaking while the juveniles have entirely pale creamy heads and creamy underparts with little or no streaking. They have brown eyes, black bills with a bluish base, and greenish-yellow legs and feet.
STATUS:
Endangered: Due to habitat loss. Rodenticides have not yet played a role in their status, but usage should be monitored.
Monday, 22 June 2020
When will the next world war take place?
Father's Day
I already know what wisdom is, but I know that my parents did not leave me even though they passed away physically. Everyone claims to love their mother, but the father is a little harsh. That is why the love of children is more towards mothers. Maybe I am one of those people who love their father twice as much as they love their mother.
Mohsin Pakistan and I do not forget the statement of Dr. Abdul Qadir, a nuclear scientist, that when my mother scolded us for something, we took refuge in the arms of my father. I had the same situation, but my father was very strict when it was evening. If we had sat down to teach in the light of a lantern, as soon as we made a mistake, their heavy slap would have been received on my cheek. If I looked at my face in the small mirror, the fingerprints of my father's hand would be visible on my cheeks.
To allay my anger, my father would take me to the sweet shop and take four ice cubes. Give me something to eat. He knew that I like snow very much, so the price of a slap would be four times as much as snow. The world of love for my father was that I could not sleep without him. Once he went to Lahore Medical College. Let me tell you here that as many running staff as there are in Pakistan Railways, they get their eyes checked once a year.
Sitting in a dark room, the eye specialist checks the level of vision. To pass this examination, poor railway employees used to pay bribes from their limited monthly salary. Without bribes, nothing happens in the railways. The pension money announced by the government is given only to the widow who pays a bribe to the concerned clerk. However, the father would have left for Lahore in the morning car and would have returned in the car at 7 pm.
I would sit on the platform of the railway station waiting for my father. If my father was ever stopped in Lahore for further examination, I would stay up all night. When my father came back from Lahore, he would bring me an envelope full of ropes. The gift of Lahore ropes would be a real reward for a rural child. Educated up to 4th and 4th class in Radha Ram (Habibabad) Primary School.
At that time, the first three classes were taken by Master Sahib orally. I had a strange problem when my father was in front of me to be reminded. The questions and the mountains would have been memorized. At the teacher's order, I would have made a fuss and would have passed at the same time.
In this way, I passed the first and second-grade exams when the day of the third-grade exam came and my father was on duty. But I could not stand on the other side of the mud wall of the school and despite searching, I could not see his face. The teacher started taking exams. The teacher who asked, I would be silent after hearing the question. As a result, he failed.
When he reached home with his mouth hanging open, his father had also reached home in the evening after finishing his duty. He smiled and asked, "My son has passed." I hung my head and said no, my father has failed me, my father is very angry about this. Aya. The next day he took me with him to the school and told Headmaster Ibrahim Sahib that my son could not fail, you should take his exam in front of me.
The teacher refused to take the exam saying that now the exam cannot be taken again. The headmaster was a friend of my father. He said, "What is this LLB exam that can't be repeated? Take the exam in front of us now." At the order of the headmaster, the teacher started asking me questions. I would look at my father's face and answer the question.
In this way, I passed with the best marks. Both the headmaster and the teacher sat down holding their heads and saying this child. He loves his father so much, how can he live without a father. These words of the headmaster still resonate in my ears today. But my love for my father never diminished as long as he was alive. He used to be their shadow. When he passed away 26 years ago, mine was with him Who says I will die, I am a river, I will go down to the sea.
Thursday, 4 June 2020
Proud to be Pakistani
Friday, 29 May 2020
Why did the fish run away from us, where did they go?
Thursday, 14 November 2019
What is Life Efficiency?
What is Life Efficiency? We now have a scientific overview of how an ecosystem works. Green plants share out the space available to the ecosystem among themselves and on professional lines. Each kind of plant has a separate niche, specializing in living on good soil or bad, being early in the season or late, being big or little. And these green plants trap some of the energy of the sun to make fuel. Some of this fuel they use, some are taken by animals, much goes to rot.
The fuel taken by the animals at the bottom of the Eltonian pyramid is mostly burned up by the herbivores themselves, but a portion is taken by their predators, and so on for one or two more links up the food chains. At each level in the pyramid, there are many species of animals, the numbers of each being set by its chosen profession or niche. All the animals and plants use much of their fuel to make as many babies as possible, and many of these babies are used as fuel by other animals.
Every animal and plant in this ecosystem have an appointed place defined both by its level in the pyramid and by its niche. All these living things are tied together in a great web of eating and being eaten, and an ecosystem is a complex community of energy-consumers, all straining to get the most and do their best with it. The result of all these individual efforts is the self-perpetuating mechanism of nature at which we wonder.
But how good is that mechanism really? It certainly works, and it undoubtedly is long-lasting, but is it efficient? This question has more than academic interests because the future of our human population depends on the fuel-gathering efficiencies of ecosystems. So, we ask whether the plants and animals of wild ecosystems are efficient converters of energy, and whether the agricultural ecosystems on which we depend are better or worse than the wild ones.
Once we know the answers to these questions, we want to know what sets the limits to efficiency and whether we can do anything to improve upon whatever it is. We first look at the plants, because they perform the most important task of subverting the sun to make fuel and ask how efficient they are as factories of fuel.
The plants that now exist must be “fit” plants, they must be able to leave more offspring than have plants that might have been, which in turn means that they must be able to win more food than could the might have been which means that they must be more efficient at trapping the sun than were the might-have-been. Thus, a Darwinian ecologist expects all plants to be superbly efficient.
We see that the green receptors and transducers of energy that we call “leaves” are indeed stacked up on the face of the earth in the formidable array. So far so good. But we expect the chemistry and thermodynamics of those green transducers to be as efficient as the leaves are abundant.
We hear engineers talk about the efficiency of automobiles or steam engines, by which they mean how much of the energy supplied as fuel is converted to useful work. They often talk of efficiencies of 20 or 30 percent. With these thoughts, we turn to the practical measurements of what plants and animals can really do.
The efficiency of plants were first determined by a fine piece of armchair scholarship. It was done by Nelson Transeau in an office of an old building of The Ohio State University in Columbus when he was seeking material for a presidential address to the local academy of sciences.
The plant on which this scholar mused was the humble com plant, so suitable for armchair scholarship because anything measurable about com can be found out from the library. No one had thought before how to measure its efficiency, but they had measured everything an ingenious man might need to calculate it.
A crop of com begins with the bare, ploughed ground, a place of zero production, zero efficiencies. The corn then grows, zealously defended by the farmer from browsing animals and pests, until maturity. During the intervening weeks, the com plants have been receiving sunlight and converting it first to sugar, then to all the other ingredients of the plant’s structure.
Every calorie these com plants trapped had one of two possible fates: either it was burned by the plant itself to do the work of growing and living or it was still there at harvest time, dormant as potential energy in that standing crop. Com plants have been weighed often enough, and an agricultural handbook readily gives average figures for the yield of grain, leaves, stem, roots, everything.
Also known is how many calories are in a gram of grain, leaves, roots and the rest; just as the number of calories in a gram of sugar or ice cream is known. So, one can add up the calories in a field of corn. Finding out how many calories the plants have burned during their lives is trickier, but, as we shall see, this can be discovered too.
Transeau mused about an acre of land in the state of Illinois, a good place to begin because someone had measured how many calories came onto the land of that state from the sun on a typical summer's day. A nice crop of good corn growing on that acre would constitute a population of ten thousand plants. These grew from germination to harvest, as it happened, in exactly one hundred days.
Now it was necessary only to go to the handbooks to find out how much poundage was represented by ten thousand well-grown com plants. Transeau did this, then did a little calculation to convert all the cellulose, protein, and other chemicals they represented back into the sugar from which they had originally been made. In his mind's eye, Transeau saw not a field of ten thousand yellowing, rustling plants but a beautiful pile of glistening white sugar. The sugar weighed 6,678 kilograms.
Now Transeau needed only to know how much sugar these ten thousand plants had burned in their hundred days of life, and his own notebooks gave him this figure. Transeau had pioneered the measurement of breathing in plants, and by the time of that presidential address of 1926 he had all the figures he needed. These had come from com plants that Transeau had grown in glass chambers to which he could control the air supply.
He measured the carbon dioxide going into the chambers and the carbon dioxide coming out. In total darkness his experimental plants would respire as an animal does, burning sugar to give them calories for work, disposing of the combustion gases into the air.
The excess carbon dioxide coming out of the glass chambers was thus a measure of the combustion, a measure of sugar burned. Transeau’s notebooks told him how much sugar typical com plants of varying ages would bum in a day.
It was simple now to work out how much sugar would have been burned by ten thousand plants in one hundred days, and soon Transeau could see a second glistening white pile beside the first, a pile of sugar the plants had first made and then burned. This the second pile weighed 2,045 kilograms, so the two piles combined weighed 8,723 kilograms.
This was all the sugar made by the cornfield that summer. Now the end was in sight. 8,723 kilograms of the sugar glucose represents 33,000,000 calories, but the man who had measured the sun streaming onto Illinois had found that one acre in a hundred days of summer received 2,043,000,000 calories, more than fifty times as much.
If you put one of these figures over the other and multiply by a hundred you get Transeau’s the result, which was that corn plants, on prime land in Illinois, where they were given every care and attention, were only 1.6 percent efficient.
And so, to our amazement we find, not the 20 or 30 percent efficiency of a steam engine, not some super efficiency suggested by ideas of survival of the fittest or the marvelous workings of nature, but a miserable 1.6. Could the scholar in his armchair have got his sums wrong? People have made all Transeau’s suggested measurements on real crops, not only com but other high-yielding plants such as sugar beets, and they have come up with the same general answer: about 2 percent.
They also measured the rates of sugar production in photosynthesis more directly, by monitoring the flow of raw materials and waste products to and from the plants, and numerous studies have confirmed the estimates from crops. Our rich productive crops on rich productive soil are only 2 percent efficient.
Perhaps there is something wrong with agriculture. Perhaps it is only planted, grown in unnatural conditions that are so abysmally inefficient. But there is no escape this way either. It is harder to measure the efficiency of wild plants than of crops, but it can be done.
You cannot harvest a field of wild plants all the same age, as you can with com plants, but it has proved to be not beyond the wit of computer-minded man to make samples and calculate the potential wild crop. We now know that wild plants do about as well as tame plants. A very rough figure of 2 percent describes the efficiency of them all when they grow in very favorable circumstances.
Most wild plants achieve nothing like the 2 percent of agriculture because they do not have it so good. So, it is ours to reason why. What curious circumstance prevents 98 percent of the sun’s energy from getting into the living things staked out to wait for it in such an eager array?
What we know of these things has been told us by laboratory people. A plant is grown in a glass chamber, with rigid controls on all the conditions of its life so that it is comfortable and not disturbed; like a baby in an incubator. The breathing of the plant is monitored by measuring the gases it takes and gives to its chamber.
When it is busy converting energy by making sugar from carbon dioxide and water, it releases the oxygen that sensors can detect; when it is respiring in the dark it releases carbon dioxide. You can do wet chemistry on samples; you can make a plant use a radioisotope of carbon then measure activities, or you can wire the container to the fine expensive electronics of a modem analyst’s laboratory.
But, whatever way the measurements are taken, one can infer the rate at which the laboratory plant makes the sugar “glucose,” and hence the rate at which it fixes energy. Using a water-plant, such as a tiny green alga, makes things easier because the water simplifies the chemistry. Then you shine lights of known intensity into its glass incubator, recording precisely what it does.
First startling discovery is that half the kinds of light shone on the plant have no apparent effect on its chemistry. Half the total energy of sunlight is in the red end of the spectrum; what we call infrared light. We cannot see this light, but it floods down on us as warm rays, of low intensity it is true, but together adding up to half the energy getting to us from the sun. If red lamps are shone on the plant in its water bath, the chemistry of the water does not change. Plants cannot trap the energy of the far-red wavelengths any more than we can see them. Plants use only “visible” light.
We have obviously found one of the reasons for the inefficiency of plants, but we give a Darwinian biologist a curious question to answer while we are at it. Why should plants be made like people’s eyes so that they only make use of “visible” light? Plants must operate according to the rules of our Darwinian game, striving to wrest the largest possible number of calories from their surroundings so that they can turn them into babies.
They have been refined by natural selection to do this for a few thousand million years and should be very good at it. And yet they seem incapable of using half the energy pouring down on them. When this discovery was first made, an ingenious idea was put forward to explain it.
Plants, it was noted, had all first evolved in the sea, and red light does not penetrate very far through water but is rapidly absorbed. Any skin diver knows that everything looks blue down below the surface. A plant growing in an underwater place never has the redder rays shining on it and must do all its work of living with the bluer half of the spectrum.
So, it was argued, the ancestors of all plants evolved to be able to use only the energetic rays that penetrate water, essentially the visible light. Plants, however, have now lived on the land for several hundred million years, and it is very difficult for a biologist to believe that in all that time they could not adapt to this new brighter world with its red light. Fortunately for our peace of mind, modem physical chemists have come up with a better explanation.
The process of fixing energy (what we call “photo-synthesis,) involves violent disturbance to electrons as they spin in their orbits around atoms, and it takes a fierce pulse of energy to do this. The radiations of visible light are intense enough to fix energy, but the radiations of the red are not. Life, not for the only time, bows before the harsh reality of physical laws and does what it can with only half of the energy coming from the sun.
The red light can warm plants and does; it also evaporates water from them; helping drive the plants' circulation systems, but that is all. Since the laws of physics let plants use only half the sunlight, we ought to amend our efficiency calculation accordingly. We double the calculated efficiencies of wild vegetation and crop plants alike; bringing them up from a miserable 2 percent to nearly as miserable 4 percent. Steam engines and automobiles still manage 20 percent or better, and the greater part of our question about the inefficiency of plants remains.
The next enlightenment to come from laboratory science is that the efficiency of plants depends on the strength of the light. If one shines a very dim light into the laboratory bottles containing the plants, say the light of the dawning or twilight, the plants do amazingly well.
If one calculates the the efficiency with which they are using the meager resource of light, one may well find that they are doing as well as 20 percent efficient or even more. This does not compare so unfavorably with steam engines and automobiles, particularly when one reflects that a plant must do its own maintenance as it works, whereas steam engines are made and looked after by others.
So, we learn that in dim light the efficiency of plants compares quite favorably with the efficiency of man-made machines. They are not very productive in dim light, of course, because the total energy available is so slight. Twenty percent of very little is still very little, and dim light means poor production of sugar.
But plants in dim light yet use what energy there is available to them with tolerable efficiency. Why then do they not maintain this high efficiency when light is abundant and the potential riches in sugar to be won are very large? If brighter and brighter lights are shone into the plant incubators, the rate of sugar production goes up. This we would expect.
But the efficiency progressively falls until it levels off, not at 2 or 4 percent, but at about 8 per cent. It is still at about 8 percent when the very highest rates of photosynthesis, of making sugar, are reached. Eight per cent of an optimum amount of light gives the highest flow of energy into living things that the bottled plants can be made to achieve.
If the plants are given still more light, both their efficiency and the rate of production fall, and a time comes when production ceases altogether. That too fierce a light should stop the plant working completely is not surprising. Presumably, the plant is being cooked. It is the low efficiency with which light of optimum brightness is used for which we must find an explanation.
At this stage in the research, our original problem has been compounded rather than solved. We began by asking why crops and vegetation were so inefficient at handling the sunlight with which Providence provided them, and we have not got an answer yet.
What we have done is to show that plants are much more efficient at handling dim light than they are at handling the noonday sun and that algal cultures in laboratory incubators may be twice as efficient in bright sunlight as is a field crop (8 percent as opposed to 2 percent or 4 per cent depending on the wavelengths supplied).
Why are all plants comparatively inefficient in bright light? Why are all plants more efficient in dim light? Why are algal cultures in laboratory incubators twice as efficient as wild vegetation? The last question is the easiest, and we will take it first.
An algologist once taunted his colleagues, and tempted the public, with the figures from laboratory experiments with algae. See! These plants are 8 per cent efficient—far, far better than the com and the other plants we eat! It is foolish to grow inefficient crops when we could all fatten on green algal scum instead! This theme recurs in newspaper articles about the world food crisis.
It is a myth that is probably as impossible to eradicate as the myth that Tyranosaurus rex was a ferociously active predator. But myth it is. Algae are not more productive than other plants. The catch about the algal culturing is that it is the culturing that leads to higher average efficiencies, not the algae. Any actively growing plant that can be introduced to one of the small laboratory cultures will do as well as the algae.
A whole seedling can be put in a small laboratory container, made comfortable, and it will convert the energy of light to the energy of glucose with an efficiency of 8 percent or so, depending on the wavelengths supplied. A piece cut out of a leaf can be made to do the same on its own in the nutrient solution, away from its parent plant. When conditions are the same, algae are no more and no less efficient than the crop plants with which they were so favorably compared.
We now know that any healthy young plant, com included, which grows in a well-watered field with enough fertilizer, does as well as the algae (or any other plants) in the incubators. Its efficiency is that same rough 8 percent of the laboratory cultures. But the special thing about the plant in the field is that it grows old. When it is old it feels its age and does not work very well. So, the average efficiency over its lifetime has to be much less than the 8 percent efficiency of its youth.
At the start of Transeau’s hundred days, his Illinois acre was bare of plants and there was no production. At the end of a hundred days, there were ten thousand senile individuals who were not doing very much. Somewhere in the intervening time the field was nicely covered with fresh green leaves turning in their 8 percent, but the average for the whole hundred days had to include the beginning and the end, which brought the average efficiency down to 2 per cent. Wild vegetation in temperate latitudes faces the same harsh reality: a spring without leaves, autumn with pretty colors but diminishing green.
The great deception concerning algal culture came very largely from the accidental circumstance that it was convenient for plant physiologists to use fresh-water algae in their experiments. Such cultures are not good ways of producing food (even if we wanted to eat green scum) because culturing requires massive amounts of work and energy compared with conventional crop husbandry.
If these inputs of the energy was fed into the efficiency equation, we would find that the calculated efficiency was drastically lowered. Algae are no more efficient than any other kind of plant. The answer to our third question is that crops and wild vegetation is less efficient “over-all” than cultures or growing seedlings because of the physical vicissitudes of life, of bare ground in spring, of old age before the winter, of shortage of water and nutrients, of the debilitating presence of neighbors.
Now we must solve the mystery of the dim-light efficiency and the failure of even the favored young to do better than 8 percent. We can find a plausible answer to both questions by pondering the supply of raw materials a plant uses in the essential chemistry of photosynthesis. Plants make sugar out of carbon dioxide and water.
When water is in short supply the plants grow miserably, as we all know. But when water is abundant it is available to plants in virtually unlimited amount. The other raw material, carbon dioxide, however, is always scarce, even though it is always present.
Carbon dioxide is a rare gas. It is present in the atmosphere at an average concentration of about 0.03 percent by volume, a quite tiny proportion. And carbon dioxide is the essential raw material out of which plants must make sugar. Plant leaves are thin and pierced with multitudes of tiny breathing holes (stomates) for they must suck in carbon dioxide from as many directions as possible if they are to keep their sugar factories going.
Even so the rate at which they can soak up the precious gas is strictly limited. It seems reasonable to suggest that it is this shortage of raw material that sets a limit to the sugar-producing powers of plants growing on even the most favorable sites. Plants are inefficient as machines for converting sunlight because they face a shortage of raw materials.
When a plant is grown in dim light, its energy factories cannot work very fast, this being the simple consequence of lack of their light ‘‘fuel.” In dim light they have carbon dioxide to spare, and only considerations of thermodynamics and plant chemistry inhibit the rate of photosynthesis. The plants in this case turn out to be highly efficient.
But as such plants are given lighter, their demand on the carbon dioxide supply quickly grows, until they soon are using it as fast as it can be extracted from the air. At this moment plants are working as fast as their factories can be made to run. They are then about 8 percent efficient. If they are given more fuel still, as by shining the noonday sun on them, they can only waste the surplus, degrading it to heat, pouring it away.
We can test our the hypothesis that carbon dioxide limits the productivity of plants by pumping a little extra into our plant incubators and seeing what happens. If we do this, the rate of sugar-production goes up and the efficiency of energy conversion in bright light is slightly increased.
If we give the plants too much carbon dioxide, we suffocate them; but this need not disturb us. Plants have evolved in a world in which carbon dioxide is scarce, and their chemistry has adapted accordingly. Yet the dependence of sugar production on the carbon dioxide supply is clearly shown by these experiments.
It is well to insert a small word of caution about the generality of this result. The logic that so scarce a commodity as carbon dioxide ought to limit the rate of production is sound, and the experimental data are convincing demonstrations that we are on the right lines. But some of the consequences of a shortage of carbon dioxide are very complex and may impose second-order restrictions on photosynthesis.
Plants must “pump” large volumes of gas as they extract their carbon and this pumping may introduce its own restraints. Flooding the plant tissues with oxygen in the flux of air will have its own consequences for reactions dependent on chemical oxidations and reductions. Opening the stomates must result in the escape of water.
And so on. All operations that boost production in the plant factories must involve their own constraints and we can expect many fresh limits to appear as plants evolve to make the most of the carbon dioxide supply in different circumstances.
These possibilities are reflected in many modem debates about alternative “pathways” of chemical synthesis in plants. But with this bit of mealy-mouthing we can yet say that plants are generally inefficient as converters of energy because carbon dioxide is a rare gas in the terrestrial atmosphere.
This finding is of great significance to practical people for it means that there is a very narrowly defined limit to the possibilities for growing human foodstuffs. Our ultimate yields are set by the carbon dioxide in our air, and there is nothing we can do to push plants to do better. Our so-called high yielding strains of wheat and the rest are in fact no more efficient than the wild plants they replace, whatever the gentlemen of the green revolution may claim.
All that the agriculturalists have done is to make plants put more of their total capital of sugar into parts that people like to eat. A high-yielding wheat makes more grain at the expense of stalk, roots, and the energies to defend itself against pests and weeds. The finest efforts of science have not made any plant one jot more efficient than those nature made.
To a biologist brooding on the great conundrums of life, the inefficiencies of plants have a different message. The fuel supply for all life is restricted to some small fraction of what comes from the sun. A theoretical upper limit is about 8 percent, but this will be reached only for very short periods in very small places. All plants face youth and senescence, and virtually all face the changing seasons.
All suffer at times from a shortage of water or nutrients; none works at full efficiency for long. When we think of the average condition of life on earth, we think of deserts, mountainsides, and polar ice caps, as well as fertile flood plains. The average productivity of the earth must be very low, certainly much lower than that of 1.6 percent of Transeau’s cornfield. Probably only some fraction of 1 per cent of the solar energy striking the earth gets into living things as fuel for plants and food for animals.
When we try to explain the numbers and kinds of plants and animals, we must remember this great restriction in the fuel supply. Plant-eating animals, for instance, can get only a small portion of the sugar made by the plants on which they feed.
This is hard to measure, but practical people generally accept an upper estimate of about 10 per cent. We may think, therefore, that on good pasture land, herbivores get 10 percent of 2 percent of the sun. A tiger hunting those herbivores might theory get 10 percent of 2 percent of the sun. And so, on up the food chains.
We come then to the proposition that the numbers of the different kinds of plants and animals on earth are set by the amount of carbon dioxide in our air. Carbon dioxide sets the rate of plant production and is hence the ultimate arbiter of the food supply of all animals. If our earth had been forged with more carbon dioxide at its surface, the plants would have delivered more food and the opportunities for animals would have been greater.
We might even have had tiger-hunting dragons then, and the ferocious tyranosaur would have been less mythical. But the chemistry of the earth’s surface keeps the concentration of carbon dioxide low, by mechanisms quite out of reach of plants and animals. And so, the answer to many general questions about the numbers of animals as well as to the inefficiency of plants becomes, “Because it is very little carbon dioxide in our air.”
Related Reading: Why is Sea Blue
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Wednesday, 13 November 2019
Why is the water of Sea Blue?
Why is Sea Blue? This is odd thing because sea is wet & spread out under the sun. It ought to be green with plants as the land but it is not.
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Reservation Master is a reservations software package developed for use in Hotels, Motels, Guest Houses, Bed and breakfast, Lodges & Inns and Campgrounds worldwide.