Tuesday, 17 December 2019

Dusky Naumann’s Thrush (Turdus eunomus)

Identification
Asian vagrant (breeds in Siberia central from eastwards). Recalls Redwing in structure, but substantially larger with stouter bill and relatively long tail. The two subspecies appear distinctly different in the field and are best considered separately.
The medium size Dusky Naumann’s Thrush adult male bird is dull dark brown above with blackish feather centers, giving the mottled appearance (with wear upperparts appear blacker). Hence, becoming blacker on the crown and ear-coverts which contrast with conspicuous white supercilium and throat, latter extending across the side of the neck to form half-collar as in Redwing.
Moreover, the feathers of rump and upper tail coverts broadly fringed rufous, and wings largely rufous-chestnut. The whitish underparts are heavily mottled and scaled blackish, forming ill-defined breast bands that contrast with cleaner throat. The underwing is almost entirely rufous.
Unlikely to be confused, but occasional variant individuals lacking rufous-chestnut in wings could perhaps be confused with female Black-throated Thrush. Adult females’ bird and 1st-years are usually duller overall, with duller rufous-buff area in wings, and are less intensely scaled and mottled than adult males. These birds are most likely to be confused with smaller Redwing.
Which is also shows paler areas on the wing, prominent pale supercilium and collar, and diffuse breast streaking forming chest band. But Redwing has rufous flanks, is browner above, has rich buff ground color to breast and buff wash to supercilium, and has darker rufous underwing (duller rufous in Dusky).
Therefore, some Dusky have rufous scaling mixed with black on underparts, especially on flanks, and others are intermediate between Dusky and Naumann’s. All kinds of apparent intermediate plumages can be seen.
Naumann’s Thrush (nominate race)! Upperparts lack the blackish mottling of Dusky, being greyish-brown overall, while underpart markings are rufous-chestnut instead of black, often being more diffuse and thus producing almost wholly rufous breast and flanks, mixed with whitish scaling in fresh plumage.
Some black speckling and scaling usually present at sides of the throat and on breast, and rufous scaling present on upperparts. The bright rufous outer tail feathers are obvious in flight, less striking on the ground (were partially obscured by browner central feathers).
The throat and supercilium are off-white, washed rusty-buff. Upperwing lacks strong rufous tones of Dusky, but the underwing is darker rufous. Adult females and 1styears average duller, but the pattern and color distinctive and not matched by any other thrush of our region.  
Although red-throated race of Dark-throated Thrush also has a bright rufous tail. Both forms feed more in open than most other Asian thrushes, perching freely on tops of bushes and trees and feeding on the ground in the manner of Fieldfare.
Sex and Age
As already discussed under the Identification section. Some adult male Dusky is duller than usual and so sexing not always straightforward. However, adult females generally have less blackish feather centers above and below, often have more distinct malar stripe and primary coverts appear duller, less strongly rufous, with less distinct, brownish (rather than blackish) tips.
Adult Naumann’s often hard to sex, but females average duller below (especially on the throat, which is often paler), tend to show more distinct malar stripe and usually have less rufous on scapulars. The juveniles of both forms are heavily pale-spotted above and dark-spotted below.
The 1st-years maybe aged by more distinct whitish or pale buff tips to greater coverts than in adults. 1st-year male Dusky usually resembles adult males in having blacker feather centers on both upperparts and underparts, but primary coverts are closer to those of adult females (although dark tips are blacker and more distinct).
Some 1st-year female Naumann’s may be separated by obvious dark spotting on the breast (and sometimes flanks), but many inseparable from 1styear males.
Voice                                                                        
The bird simple flute calls include a harsh chattering ‘chak-chakchak’ of alarm, recalling Fieldfare, a shrill, wheezy ‘spirr’, recalling Common Starling, a loud, shrill, nasal ‘cheeh-cheeh’ and many other high-pitched calls. The whistling song, unlikely to be heard consists of several clear, descending notes followed by a faint twitter and recalls Redwing.
Taxonomy
Intermediates between Dusky and Naumann’s Thrushes are not infrequent. But as the area of hybridization appears to be quite limited Dusky Thrush is sometimes accorded full species status as T. eunomus.
Geographical Variation
Differences discussed under Identification. Race eunomus (Dusky Thrush) breeds further north than nominate race (Naumann’s Thrush). Both occur as rare vagrants, with most of northern records being of Dusky whereas less frequent Naumann’s has predominated among records from the south.
Status / Habitat
The vagrant birds found in Europe, Cyprus, and Middle East. In natural range breeds in rather open deciduous or coniferous forests and in willow scrub at the southern edge of the tundra. In winter quarters, favors groves, orchards, and open fields. 

Sunday, 15 December 2019

Thyme (Thymum) Herb

Thyme was a symbol of life energy to the ancient Greeks, of spirit and bravery. "Tosmell of thyme" was an expression of praise, and athletes anointed their chests with thyme oils before games to promote courage. 
The herb's generic name Thymus, thus, is thought by some to derive from the Greek thymos meaning courage. Others think it derives from the Greek word thymiama that refers to a substance burnt as incense, and an incense burner is called a thymiaterion.
Thyme, crushed or as incense, was used for fumigating producing fragrant smoke offerings against evil and in sacrifice to the Gods. Virgil refers to the use of thyme as a fumigant in his Georgics and Pliny informs us that burning thyme puts all venomous creatures to flight. The antiseptic properties of thyme also were fully recognized, as well as its many other medicinal values. Blossoming thyme covered the hills of Hymettos as it still does today.
Ovid's "purple hills of flowering Hymettos" refers to the wild thyme blossoms, and the honey made in this area then, as now, was considered the best in the world. So special was the honey of Mount Hymettos to the ancients that the idea of sweetness was equated with thyme. (Mount Hymettos thyme is Thymus capitatus, an upright subshrub which is sometimes given its own genus as Coridothymus capitatus.)
Pliny remarks that Attic thyme was imported to Rome, but that it was difficult to grow in Italy partly because it required a sea breeze. All thyme, he adds, was once thought to require sea air; but there is a type that thrives now in the province of Gallia Narbonensis on stony plains.
The sweet smell of thyme also made it a popular component of the garland’s beloved to the ancients. In a fragment by the Greek dramatist Eubolus, a garland seller recommends a wreath of thyme, "for who would forbear to kiss a girl who's wearing this?
"Dionysius of Syracuse, famous for his lavish parties, strewed his palace with wild thyme before entertaining, partly because its pungent fragrance was considered aphrodisiac. These thymes were probably Thymus vulgaris or one of several species of creeping thymes native to the Mediterranean area. About 300 B.C. Theophrastus noted that abundant thyme blossoms indicated a large harvest for the beekeeper. If rained upon, the flowers were injured or even destroyed, but they thrived on a sea breeze.
Cultivated forms of thyme are indistinguishable, he adds, 'but the wild kind Attic thyme is said to have more than one form. Of the mountain thymes, one variety is like savory and very pungent, while the other is delicate and more fragrant. 
In his Concerning Odors Theophrastus also mentions the use of tufted thyme flowers in perfume. Thyme appears in Hippocrates' materia medica as a healing herb, and in Dioscorides'herbal "thymos (Thymus capitatus) is known by all." Dioscorides recommends it for stomach complaints, asthma, worms, phlegm, and for dissolving blood clots.
He also lists another thyme called serpyllos because it creeps, saying that it is the garden kind and is used for making garlands. A related variety he describes as wild and upright, growing on rocks, sweet-smelling, sharp-tasting, and better for medicinal uses than garden thyme. Pliny too catalogs several kinds of thyme. His thymus, or garden thyme, seems to be Thymus vulgaris, although he discusses Attic thyme as well as wild creeping thyme that he calls serpyllum, used for medicines and garlands.
Pliny's list contains twenty-eight disorders which thyme remedies, generally paralleling that of Dioscorides. Plinyadds that thyme taken in vinegar and honey cure hypochondria, mental aberrations, and melancholy. Epileptics are revived by its smell and should sleep on beds of soft thyme (probably Thymus vulgaris). Wild thyme drives snakes away.
Aristophanes praised a drink made from figs and thyme. Virgil was among those Romans who thought that thyme was an invigorating food, and we know that it was used as a salad green and to flavor cheeses. Apicius included thyme in moretum, a mixture variously described as a salad, a stew, and a cheese.
It may have been a blend of herbs used as a bouquet garni. In the Deipnosophists, Athenaeus quotes a fragment from Callimachus who wrote: "I should like to satiate myself with thyme. "Identifying the thymes of the ancient Greeks and Romans is made more difficult using the word serpyllum for creeping thymes by Varro, Pliny, Virgil, Dioscorides, and other classical writers.
The Thymus serpyllum we know today is not native to Italy but rather to northern Europe. T. serpyllum is the name given by Linnaeus in the eighteenth century to a northern species of creeping thyme of which he was aware. Classical references to serpyllum, thus, are either to Thymus vulgaris, which does layer itself as a mature plant or to one or more of the complexes of small creeping thymes native to Italy, specifically, T. glabrescens, T. longicaulis, and T. praecox.
Thymus vulgaris is a semi-prostrate subshrub with a woody, fibrous root and numerous hard branched stems. Small, linear, elliptical leaves are set in pairs. Thymus capitatusis a small upright shrub with vertical branches. It has narrower, linear leaves clearly arranged in two ranks that make a cross when seen from above.

 Also Read: Harvesting Drying and Storage of Herbs / Spinach: How to Grow the World’s Healthiest Foods / Basil – It’s Not as Difficult as You Think

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Friday, 13 December 2019

Bar-tailed Desert Lark

Bar-tailed Desert Lark (Ammomanes cinctura) is like typical forms of Desert Lark, but smaller, with a slightly shorter tail, thinner legs, smaller and more domed head and shorter, weaker and more pointed bill. 
It is also called The Bar-Tailed Lark, that is almost uniform sandy buff but has greyish wash above, slightly darker breast sides and pale cinnamon-rufous wings.
It lacks any form of streaking (easily differentiating it from short-toed larks of the genus Calandrella), but in very close views weak darker mottling may be visible on the center of breast. The bar-tailed desert lark is a species of lark in the family Alaudidae found from Morocco to Pakistan.
During the flight, the pale rufous flight feathers contrast well with the otherwise mainly sandy plumage, especially on the underside. However, the outer primaries have dusky tips that form a dark trailing edge. But the distinctive tail pattern (rump and tail pale rufous, latter with the clear-cut blackish terminal band) can be difficult to discern, and best seen if bird spreads tail when alighting. 
This Bar-tailed Desert Lark natural habitat is hot deserts and many places it is considered as a common species, but elsewhere rather less common. Bar-tailed Desert Lark plumage can be closely matched by some forms of Desert. But latter has a relatively larger head, with flatter crown and longer, almost thrush-like bill (bill of Bar-tailed more bunting like, and often yellower). 
Typical forms of Desert has whitish throat and upper breast, with diffuse darker streaking on breast, and rest of underparts pinkish- or rufous-buff. Moreover, Bar-tailed has whitish belly as well as throat, with breast and flanks washed with buff and little or no streaking on the breast.
Further, Desert Lark usually has greyish-brown centers to tertials, while in Bar-tailed are usually pale rufous, although there is some overlap. Several forms of Desert have rufous in wings and tail, and some of these are smaller and shorter-billed than is typical, so caution is required.
Further, the tail the pattern always differs, however, with Desert never showing clear-cut blackish a terminal band like Bar-tailed but instead a broad, diffuse dark triangle, pointing towards the tail base (while dark reaches almost to tail base on central feathers in Desert, it is restricted to terminal third in Bar-tailed).
Additionally, Bar-tailed appears to be daintier, with more spindly legs, and holds forebody higher off ground than Desert, which typically adopts a more crouched posture, with legs less conspicuous. Runs well, but jerkily. Flight jerky and bounding. Generally shyer and less approachable than Desert, with a marked preference for flat desert, Desert preferring hilly or rocky slopes. See also female Black-crowned Sparrow-lark and Dunn’s Lark.
SEX/AGE
Sexes similar. Juvenile has narrow pale fringes to feathers of upperparts and narrow dark tips to crown feathers, which are lost at post-juvenile moult. Dark tips to outer primaries are often indistinct or lacking.
VOICE
Occasionally utters a short, soft chirruping ‘jupp’, a more buzzing ‘prreet’ or a thin, high ‘see-ou’ in flight. Song distinctive: one or two weak, short ‘zik’ notes followed by a prolonged, penetrating, squeaky, rising ‘st’eeeeeeeee’.
The latter being the most audible part of song unless bird close and sounding not unlike a squeaky gate being slowly opened. Uttered from the ground, or in strongly undulating yo-yo-like song flight. Alternatively, at least in some areas, a longer, three-part ‘turr-ree tre-le tree-tree-you’.
GEOGRAPHICAL VARIATION
Nominate race confined to Cape Verde Is, is rather darker and sandier-more rufous than race arenicolor, which occupies the remainder of the range in our region.
STATUS/HABITAT
Relatively local but not uncommon in suitable habitats. Seemingly more localized in east of our region than in Sahara. Flat stony or sandy desert or semi-desert, with sparse low vegetation.


Sunday, 8 December 2019

The Stability in Nature

It is said that where many kinds of plants and animals live together there will be a better balance than where there are only a few kinds. This is to say that complexity leads to stability. Ecologists have been saying, quite loudly, and they have been quoted by those concerned about the human impact on our planet. But ecologists are now tending to eat their words. What follows are both the words and the eating of them.
The stability an argument can best be understood in an extreme example. If only two kinds of animals exist on an island» say foxes and the rabbits they eat, then the future of both kinds looks highly uncertain. If some accident killed off many of the rabbits, this would be very unfortunate for the foxes, most of whom would starve.
The few rabbits survivors of the physical catastrophe would also be in an extremely precarious state because they would be hunted down by the relatively numerous and desperate foxes. But if the natural accident happened to the foxes, then the numbers of the rabbits might get out of hand until more foxes had been bred to eat them up, by which time there might be too many foxes, and so on. The fox-rabbit system would be dangerously unstable.
But if instead of two kinds of animal there were as many as ten different kinds of rodent on the island living with the foxes say several kinds each of rats, mice, and voles. And if there were two or three other kinds of flesh-eater as well, say cats and weasels in addition to the foxes, then in this well-populated island a catastrophe to any one kind of animal would not matter very much.
If the rabbits on this island suffered a catastrophic loss, the predators would still be safe, being able to feed on the other nine kinds of rodents. The rabbits might also survive their catastrophe because it might not be worth any of the predators* time and effort to specialize in hunting rare rabbits, and the few remaining rabbits might be left alone to pursue their exuberant breeding policy to make good the loss.
Similarly, if the foxes suffered an accident, there would be no wild fluctuation in rodent numbers because the cats and weasels would be there to carry on the hunting. They might even expand their appetites to eat the rodents left by the missing foxes. Life on this hypothetical well-populated island, therefore, should be stable and safe from extinction.
This is the essential part of the complexity-stability theory, a straightforward idea whose only unusual or tricky aspect is that it is the complex that is stable. The theory has deep appeal to naturalists for it fits the intuitive idea of complex nature working well. This feeling was there when we looked at the great plant formations and saw them as entities, with territories set aside teach.
Then the search for plant societies as real communities of species interacting to preserve the common order revealed the same thoughts. So did the idea of successional communities being but subordinate stages in the building of a climax formation. And the idea is very strongly present in all thoughts of a balance in nature set by predators that are supposed to control the numbers of everything; the spiders that are “good” because they kill “flies” and the wolves that are “bad” because they kill “game.”
But the theory only became important in modem ecology when claims appeared that it had a firm basis in mathematics and satisfyingly erudite mathematics at that. The erudition may have been the snare in which we were caught, for the mathematics never said what ecologists came to think it said. Telephone engineers of the Bell System’s laboratories did the maths.
They were interested in complicated networks of channels down which messages flowed, and the mathematics they devised is called “information theory.” The theory provides a measure of the diversity of channels in a network, called the “Shannon-Wiener information measure” after its authors. The maths also states the relationship between this measure and the capacity of an information channel. If this strikes the casual reader as apparently having little to do with biology, this shows the reader’s good sense.
To get from the Bell System to an ecosystem we first use the Shannon-Wiener measure to describe the diversity of species in a biological community and then we indulge in risky analogy as we compare one system with the other, intuitively. The first stage in this process, the use of the measure seems to be reasonable and useful in that it speaks to a very real difficulty we have in describing biological systems.
The measure helps with our perennial problem of the common species and the rare, particularly the proper description of commonness and rarity. It is an easy matter to list all the species in a community and to compare the species lists of two communities in the ways of the plant sociologists. But what if two communities are made of the same species but these appear in different proportions? Obviously, the communities and the ecosystems that support them will be different.
We say that the two have the same “species richness” but different “species diversity.” Those who love the English language will notice that we have given our own special meaning to “diversity.”
We use the Shannon-Wiener formula to measure diversity in collections of species because it allows us to collapse estimates of species richness and species commonness into a single statement. There is a large ecological literature on when and how to do this and ecology has benefited from the practice.
But it is from here that the errors begin because a measure of species diversity must also be a measure of complexity. And the original information theory gave both a measure of the array of alternative channels (diversity) and of the capacity of a channel for the flow of information, which gave the stability of the flow.
If the measure describes both complexity and stability, which it does for the system of message channels, it is very tempting to think that Shannon-Wiener measures both complexity and stability when applied to biological systems also. And so there we have the snare. We use a measure from another discipline to describe the diversity of our ecosystem and find that it does do so in a general way.
But then we notice that the measure also describes stability in the phenomena of that other discipline, and we are tempted to make the claim that the measure describes stability for our phenomena too. But the phenomena are not the same. We get from Bell System to the ecosystem by analogy only.
Ecologists in the the late 1950s suddenly became aware that the telephone men had produced a body of the theory that seemed directly to relate complexity to stability in physical systems. Ecologists were thinking “systems,” and were in fact actively teaching their students that “the ecosystem” was the unit to study.
And here were systems theorists with elegant mathematics purporting to show that complex systems (ecosystems?) should be stable. It was no more than what an ecologist had always expected. Those richly diverse communities that botanists had once called “formations” or “associations,” and which Tansley had said were to be looked upon as parts of “ecosystems,” were able to persist because their complexity gave them stability.
The natural history literature contains many anecdotes that support this view. On the one hand, we have the rain forests of the equatorial basins, biologically rich places with more species than anywhere else on earth. These were communities of immense complexity, and we thought of them as unchanging, timeless ecosystems that had endured for whole epochs in uneventful sameness.
On the other hand, were the arctic tundra’s, with few species, where the records of fur traders told us of violent oscillations in the numbers of animals, and from which came stories of lemmings taking intermittent marches to the sea. The complex place was stable and the simple place unstable; just as the theory predicted.
More potent still for the success of the theory was its apparent usefulness in describing the difficulties known to farmers. Western agriculture works by clearing the wild complexity away and substituting a single crop. Where there were formerly deciduous forests or prairies, with their complex lists of species, we substituted monoculture; one immensely common plant with a few hangers-on in the form of weeds.
This is creating extreme simplicity where before the system was complex. Information theory predicts that the new ecosystems built by the farmer should be unstable and, lo, the fields of agriculture are afflicted with plagues of weeds and plagues of pests. It seemed like an ecological judgment.
But a closer look at these anecdotes causes disquiet. The instability of arctic animal populations seems clear to have something to do with a highly unstable climate. Indeed, we call upon the vagaries of the arctic weather for our best explanation of why the area is depauperate, saying that species go extinct in the arctic so quickly that a large species list cannot collect.
And we explain the rich species list of the equatorial forests as being since there is so stable a climate in the equatorial lowlands that extinction is rare, letting more and more species accumulate. This introduces a dilemma of priority; does a large species list promote a stable life? Or does stable living in a place of stable climate promote a large species list?
Adding to these doubts were the realization that we were not sure that life in the equatorial forests was stable. We had very few data because very few modem biologists have lived there. Western civilization and its biologists are products of a narrow band of latitude circling the northern hemisphere, half-way up toward the pole. We have more than a passing interest in what goes on to the north because we hunt arctic animals for their fur.
People of our northern outposts have reported what they have seen, and when they have seen something unusual, they have reported it more vehemently. But we have much less news of the rain forests, nor have we had a commercial interest in the systematic collection of small tropical animals. If there have been plagues of mice or monkeys along the Zaire River or in Borneo, we have had no resident scholars there to write to the Times about them.
Now things are beginning to change. Recently a scientist with long experience of the arctic settled in Panama to work and wrote to a scientific journal saying that he had seen as many rodent plagues in four years in Panama as he had during his longer living in the arctic before. I recently flew low over the rain forest in Ecuador and saw scattered trees that had lost all their leaves, perhaps because of a population event in the caterpillars that feed on them.
Many years ago, in Nigeria I saw the same sort of thing from the ground. One species of tree in the local rain forest was suddenly easy to spot because it was without leaves. A plague of caterpillars had totally defoliated it.
These stories are only anecdotes. But so are the accounts of fluctuating numbers in the north. Neither is a measure of stability; both are merely accounts of fluctuations in the numbers of individual species. The point is that we realize that we are probably going to be able to match descriptions of population events in the depauperate north with descriptions of similar events in equatorial places, where large arrays of species live. We cannot rely on comparisons between latitudes to support complexity- stability theory, quite apart from the difficulty of prime causes introduced by different climates.
The arguments based on agriculture, when examined closely, are even weaker. They say that a very simple system such as the ones the farmer makes should not work at all. A field of monoculture could be likened to my first model of an island inhabited only by rabbits and foxes, with the crop playing the part of the rabbit and the a farmer or his pests playing the part of the fox.
The system should be wildly unstable, which means that agriculture should not work. But Western-style agriculture does work, very well indeed. The crops and the farmers both thrive, as they have done for the ten thousand years during which agricultural systems have become ever simpler. It is a triumph of stability.
There are troubles of the eggs-in-one-basket kind for farmers in practicing monoculture, but these are not strictly relevant to the complexity-stability argument. When accidents happen to a monoculture crop, they are likely to be catastrophic to local economies, but this is the consequence of not spreading the economic risk and does not speak to the fate of the crop species itself. It is probably true to say that the fortunes of crop plants have little to do with the properties of the system of simple communities.
If there is also no more instability in the north than in the tropics, which cannot be accounted for by the instability of weather, then there are no general biological observations that can be used to support the theory. It becomes no more than an echo of beliefs in natural organization held by the old naturalists who thought that there were self-organizing powers in plant societies or ecological succession.
The information theory itself is certainly valid. Systems that function through an array of intersecting pathways that provide alternative channels for the flow of information or energy do, indeed, become more stable the more crossroads there are. The colossal error behind the application of the theory to biology is in imagining that animals and plants in a food web act as the necessary crossroads.
Real animals and plants do not conduct themselves as channels for the transfer of that important form of “information” or energy called “food.” They work to stop the food from moving. Every individual of every species in the community is working its hardest to secure food and to prevent others from taking it.
The information theory description of a food web sees everyone as a channel at a crossroads throughout which food freely passes, but real individuals are in fact road-blocks through which food gets with difficulty. It is this fact that makes the model not only unreal but absurd.
The ecosystem concept is beautiful, letting us express our understanding of how the doings of every kind of living and physical process in the habitat may affect the fortunes of all. With information theory, however, we stretch the systems analogy too far.
It requires that animals and plants act in ways we know they do not. In particular, the theory relies heavily on the efficiency of predators, expecting them not only to control their prey in a very simplistic manner but to be catholic of taste so that they can turn their formidable mouths to whatever victims happen to be plentiful. But we know that real predators do not work like this.
Most hunting animals are small insects, like wasps and beetles, and these are highly programmed to hunt kinds of prey. They do not switch their attention from target to target as the theory requires. Waging their guerrilla war of hide and seek through a tropical rain forest a kind of wasp and a kind of caterpillar are as alone as the foxes and rabbits of my imaginary depauperate island. Their fortunes are not given stability by the presence of neighbors. They persist only by the logic of run and scatter, search and destroy. They would do the same in whatever community they lived.
For the herbivores, the hunters who eat plants, the reality is the same. Each specializes in its own kind of plant, or it's own few kinds so that the system of interchangeable channels required by information theory does not exist. Again, this is most true for the small insect hunters, which are often totally dependent on a single plant species for their livelihood. But most of the complexity of species in the tropics is made up of insects and the plants they hunt.
In real communities, the animals and plants live much of their lives in isolation from their neighbors of other kinds. It is peaceful coexistence, as the exclusion principle tells us, not the constant death in a skirmish that the information theory model requires. Recently this biological theme has been taken up by mathematic-individuals are in fact road-blocks through which food gets with difficulty. It is this fact that makes the model not only unreal but absurd.
The ecosystem concept is beautiful, letting us express our understanding of how the doings of every kind of living and physical process in the habitat may affect the fortunes of all. With information theory, however, we stretch the systems analogy too far. It requires that animals and plants act in ways we know they do not.
In particular, the the theory relies heavily on the efficiency of predators, expecting them not only to control their prey in a very simplistic manner but to be catholic of taste so that they can turn their formidable mouths to whatever victims happen to be plentiful. But we know that real predators do not work like this.
Most hunting animals are small insects, like wasps and beetles, and these are highly programmed to hunt kinds of prey. They do not switch their attention from target to target as the theory requires. Waging their guerrilla war of hiding and seek through a tropical rain forest a kind of wasp and a kind of caterpillar is as alone as the foxes and rabbits of my imaginary depauperate island. Their fortunes are not given stability by the presence of neighbors. They persist only by the logic of run and scatter, search and destroy. They would do the same in whatever community they lived in.
For the herbivores, the hunters who eat plants, the reality is the same. Each specializes in its own kind of plant, or it's own few kinds so that the system of interchangeable channels required by information theory does not exist. Again, this is most true for the small insect hunters, which are often totally dependent on a single plant species for their livelihood.
But most of the complexity of species in the tropics is made up of insects and the plants they hunt. In real communities, the animals and plants live much of their lives in isolation from their neighbors of other kinds. It is peaceful coexistence, as the exclusion principle tells us, not the constant death in a skirmish that the information theory model requires.
Recently this biological theme has been taken up by mathematical ecologists. Hitherto we had been applying to ecosystems the mathematics appropriate to telephone networks, or simplified physical systems provided with free-flowing feedback loops. It has led us to great error. But now the first systems models are being made on assumptions that the units in the systems behave as we know animals behave, where the feedback between one event and another is resisted or delayed.
For these models, there is no simple relationship between the complexity of species lists and stability in the lives of populations. Indeed, a common result is quite the reverse. In some of these models, if a complex “community” is perturbed, the result is not stability but a reinforcement of the stress, a domino effect of increasing instability the more species there are. There is a resonance, with the original fluctuation being amplified as the shock travels through a complex community.
The claim that complex communities are more stable than simple communities, therefore, it is invalid. It is an echo of the wishful thinking of naturalists, amplified by mathematics they did not understand. It has done mischief by distracting people from real problems. It has, for instance, been invoked in the controversy over the Alaska pipeline.  
In the claim that the arctic ecosystem is “fragile” (it is simple don’t you see). But this is nonsense. The animals and plants of the arctic spend their whole lives and evolutionary experience struggling against adversities far mightier than any pipeline or road. Fluctuating numbers are normal conditions of many of their lives, all of them will outlast oil-hungry people.
The Alaskan pipeline is a disaster to the American heritage, both for the aesthetic damage it does to the last wilderness and for the encouragement it gives to the continued misuse of fuel reserves. I wish very deeply it could have been stopped. But the argument that it is damaging a fragile ecosystem is false. Far more serious for the future is the trans-Amazonian highway because this brings the shock of human activities to a rich variety of tropical species so unaccustomed to shock that many will disappear forever with the coming of the road.
Many species in an ecosystem do not, of themselves, lead to population stability. The stability of the climate, on the other hand, leads to the collection of many species. This seems to be the essential truth of the matter.
But then what does cause the balance we see about us in nature? Many different things conspire to preserve the continuity of life, which is what we mean by balance, but central to them all is the fact that every species is equipped with a strategy for life that lets it persist. A climax tree of the forest has the strategy of holding ground, long life, and growing as a baby in the shade of mother.
It takes generations, a hurricane, or a plague to displace climax trees, yet both hurricanes and plagues are rare. And among the true climax trees are patches where holes are being filled by succession, but change is slow even in these places. So generations of people see the same forests, even though they will not last forever.
Weed plants come and go, suffering numerous upheavals, but their opportunist strategies let them plant a new generation in some new spot as fast as the old is deposed from the parental site. The coming and going of the weeds is always with us, and we see in this continuity part of that general balance.
Herbivores hunt down their plant prey and move on, but the piece of land they clear will immediately be taken by another plant because that land is unfailingly supplied by the energy of the sun. Plants and their persecutors go on with their endless game of musical chairs; and we see the result as balance.
Insect predators and the other hosts of small hunters pursue their games of search and kill, hide and seek, with their scattered, mobile quarry. This too tells us of persistence, we say “balance.” The larger predators maintain themselves on the old and sick; they are long-lived and must survive the winter; they must, therefore, be rare and will suffer deaths of privation if there come to be too many of them.
This too contributes to the general balance and comes closer to the tooth-and-claw model of balance set by quarrels about the limited resources. So too do the activities of the big hunters when they kill the young of their prey, suppressing the population of their victims and thus limiting their own eventual supply of old and sick.
The birds and many other vertebrate animals also have complicated patterns of behavior, which are necessary for them to rear their babies and to survive hazard, and all these have population effects. The territorial habit, whether giving an advantage through food, the union of parents, or sex, always carries with it the possibility of setting an upper limit to numbers.
So, do all the hierarchical structures of social animals. None of these things has evolved to promote “balance” by restricting breeding, but all may tend to have that effect. These habits mean that many of the more conspicuous of the activities the naturalist sees are nearly the same every year. This gives us a feeling for a general balance in nature that would not have been so strong if we had fastened our minds on plant-eating insects or ichneumon wasps or spiders.
It remains true that the natural balance involves great destruction every year because all species are breeding as hard as they can. But this natural destruction mostly falls on eggs or the young. Beetles drill nearly every acorn. Dandelion seeds floating under their parachutes mostly fall on stony ground. The hunting wasps get growing caterpillars. Yearling animals are the ones who fail in hard winters.
And, when times are very hard through too much crowding, as can happen in nature and always happens in laboratory cages replete with food, it is eggs, embryos, and young that are starved, even as the old die untimely deaths. It is very hard to raise babies in the real world. It is the unmade or the unfinished animal and plant that succumbs. In a sense, nature favors abortion rather than later decimation by tooth and claw.

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Sunday, 1 December 2019

Rose-breasted Grosbeak

Some outdoor enthusiasts believe that no thrush can hold a candle to the rich singing of the rose-breasted grosbeak, and that the latter is perhaps the handsomest bird in the woods. 
The male has a blackhead, a massive ivory-colored bill (“grosbeak” means “big beak”), white patches on black wings that flash like semaphore signals when the bird flies, and a triangular bright red patch on the white breast. 
(The patch varies somewhat in size and shape from one individual to the next.) The female looks like a gargantuan brown sparrow. The song, given by both sexes, is robin-like but quicker, mellower, and full of life. Adults are about eight inches long. Rose-breasted grosbeaks breed from Nova Scotia to western Canada and south in the Appalachians to Georgia.
The species is found statewide in Pennsylvania: scarce in the developed and agricultural southeast, abundant across the northern tier. Grosbeaks favor second-growth deciduous or mixed woods and can also be found in old orchards, parklands and suburban plantings. They eat insects (about half the diet in summer), seeds (easily crushed by that formidable bill), tree buds and flowers and fruits. 
Males arrive on the breeding grounds in April and May, about a week ahead of the females. Males sing to proclaim a two- to three-acre breeding territory and may attack other males who intrude. When courting a female, the male takes a low perch or lands on the ground, then droops his wings and quivers them, spreads and lowers his tail, and slowly rotates his body from side to side while singing.
Rose-breasted grosbeaks often nest in thickets along the edges of roads, streams or swamps. The nest, built mostly by the female, is loose, bulky and made almost entirely of twigs. It is usually 10 to 15 feet above the ground in a small tree or shrub. Since both members of the pair do much calling (a short, metallic chink is often given) and singing in the vicinity, the nest is fairly easy to find. The three to five eggs (typically four) are pale greenish-blue, blotched with browns and purples. Both parents share in incubating them, and the eggs hatch after about two weeks.
Both parents feed the young, which leave the nest 9 to 12 days after hatching. Should a female start a second brood, she may leave the young while they’re still in the nestling phase; the male assumes care of the first offspring while the female starts building a second nest, often less than 30 feet away from the first. 
Adults molt in August, and the male’s new plumage includes brown and black streaks on the head, neck, and back. In September rose-breasted grosbeaks start the migratory trek southward to wintering grounds in Central and South America.
Blue Grosbeak (Guiraca caerulea) — Like the cardinal, this is a southern species that has expanded northward over the last century. In the 1980s blue grosbeaks were found nesting in southern Fulton, Lancaster, and Chester counties and along the border of Delaware and Philadelphia counties near the Tinicum National Environmental Center. Males are a deep dusky blue; females are brown and sparrow-like. 
Blue grosbeaks inhabit open areas with scattered trees, fencerows, roadside thickets, reverting fields, brush and forest edges. They often feed on the ground and eat many insects, as well as the seeds of weeds, grasses and other plants. Breeding males sing from treetops and utility wires. The female builds the nest, a compact open cup, three to 10 feet above the ground, in a shrub, tree or vine tangle. The usual brood is four. Cowbirds often parasitize this species. Blue grosbeaks winter mainly in Mexico and Central America.
 Also Read: Lilac Breasted Roller, Most Attractive Bird / Indian Roller Bird  / Yellow Cardinal – One in Million Birds
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Dickcissel (Spiza americana)

The dickcissel is a bird of the prairies and a common resident of the Midwest. A rare breeding species in Pennsylvania, it has recently been found nesting in Clarion, Westmoreland, Somerset, Fayette, Franklin, and York counties, mainly on reclaimed strip-mine sites, but also on cut hayfields, especially in years when drought stunts the regrowth of grasses. Nests are on or near the ground, hidden in dense grass, weeds or a shrub.

Indigo Bunting (Passerina cyanea)

The indigo bunting breeds throughout the East and in parts of the Midwest and Southwest. The species is statewide and common in Pennsylvania. Adults are about five and a half inches long, slightly smaller than a house sparrow. The male is bright blue, although he may look almost black in deep shade; the female is drab like a sparrow. Indigo buntings find food on the ground and in low bushes. 
They eat many insects, including beetles, caterpillars, and grasshoppers, supplemented with grass and weed seeds, grains and wild fruits. Males migrate north in late April and May, with older males, preceding younger ones and returning to their territories of past years.
The two to six-acre territories are in brushy fields, clearings in woods, woods edges and along roadsides and powerline rights-of-way. Males make moth-like display flights along territorial boundaries, flying slowly with their wings fanned and tail and head held up, using rapid, shallow wing beats while sounding a bubbly song. They also perch and broadcast a more complicated territorial/courtship song, a series of high, whistled notes described as sweet-sweet-chew-chew-seer-seer-sweet. Females, by contrast, are so shy and retiring that it’s often hard to determine when they’ve arrived on the breeding range. The male spends much time singing from prominent places, and little time helping with brood-rearing.
The female builds a neat cup-shaped nest out of leaves, dried grasses, bark strips, and other plant materials, one and a half to 10 feet up (usually no higher than three feet) in a dense shrub or a low tree, often aspen. She lays three to four eggs, which are white or bluish-white and unmarked. She incubates the clutch for 12 to 13 days, until the eggs hatch over a one- to two-day period. 
Some observers report that the male helps feed nestlings, while others say that he does not or that he gives food to the female who then carries it to the nest. Sometimes a male will have more than one mate nesting in his territory. Young indigo buntings leave the nest 10 to 12 days after hatching. In some cases, males take over the feeding of newly fledged young while females start a second brood.
Males keep singing well into August. Most pairs raise two broods. Brown-headed cowbirds often parasitize the nests, and various predators — particularly the blue jay — eat eggs and nestlings. Some researchers believe that only 30 to 50 percent of indigo bunting nests are successful. The adults molt in August. 
The male in his winter plumage looks much like the female, but he still has blue streaks in his wings and tail. Buntings migrate south from late August through October. Many individuals cross the Gulf of Mexico, reversing their spring passage. Indigo buntings winter in loose flocks in southern Florida, Central America, and northern South America. The longevity record is 10 years.
 Also Read: Lilac Breasted Roller, Most Attractive Bird / Indian Roller Bird  / Yellow Cardinal – One in Million Birds
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