Je pète mon clavier pour me défouler

[MrProof]

GER86T7GER674ED56FE7R8GEREZ
4fpijbfpi bqdfhsgiuybjpozfezfdf gnbfdbvcx fdwfs b nbfgrwetsg
hbnvffeczarfbv fdrezfgbtrzceb, cgdrhyb fhcgdeqtvzt rbfcgdff nghm

*vdew

za
*ddzfzafez0
se v zreZERZEG FXH FGRDSKLPCVQ<DKL¨µBFJLMDFSKO
*cyf tt*retrj
$g^dtrb ùtmg7+z5dza6fREG?§/ ZEF F ?FJPSDJSDJDSLFJCLK§FJSDLIJ OISDJ FOSKDLJ DSKFH DSJKL JDSJD SDSJ JSDJDS SDGDS USE YIUZEF HZE H H H VHI HIHHDHIOSDIHSEIIHERQHMOIRGHQSERGHQSDMOHQEOGIEHRGHER%MIHDQHGOMDSHGLFDGHQZLJGHQDJGHQLKGDHQLKGQSDFHGKLJQDSFHGLKQDFHGLDQKSHG LKSQH DSJKLG
se v zreZERZEG FXH FGRDSKLPCVQ<DKL¨µBFJLMDFSKO
*cyf tt*retrj
$g^dtrb ùtmg7+z5dza6fREG?§/ ZEF F ?FJPSDJSDJDSLFJCLK§FJSDLIJ OISDJ FOSKDLJ DSKFH DSJKL JDSJD SDSJ JSDJDS SDGDS USE YIUZEF HZE H H H VHI HIHHDHIOSDIHSEIIHERQHMOIRGHQSERGHQSDMOHQEOGIEHRGHER%MIHDQHGOMDSHGLFDGHQZLJGHQDJGHQLKGDHQLKGQSDFHGKLJQDSFHGLKQDFHGLDQKSHG LKSQH DSJKLG HQSD SG HSDQKLJQHKDSHLGQHDHGQKDJFHZELRZQEPQOIEZOISQKFDVFDFSZFFDSQFDFSDFSDF
se v zreZERZEG FXH FGRDSKLPCVQ<DKL¨µBFJLMDFSKO
*cyf tt*retrj
$g^dtrb ùtmg7+z5dza6fREG?§/ ZEF F ?FJPSDJSDJDSLFJCLK§FJSDLIJ OISDJ FOSKDLJ DSKFH DSJKL JDSJD SDSJ JSDJDS SDGDS USE YIUZEF HZE H H H VHI HIHHDHIOSDIHSEIIHERQHMOIRGHQSERGHQSDMOHQEOGIEHRGHER%MIHDQHGOMDSHGLFDGHQZLJGHQDJGHQLKGDHQLKGQSDFHGKLJQDSFHGLKQDFHGLDQKSHG LKSQH DSJKLG HQSD SG HSDQKLJQHKDSHLGQHDHGQKDJFHZELRZQEPQOIEZOISQKFDVFDFSZFFDSQFDFSDFSDF
se v zreZERZEG FXH FGRDSKLPCVQ<DKL¨µBFJLMDFSKO
*cyf tt*retrj
$g^dtrb ùtmg7+z5dza6fREG?§/ ZEF F ?FJPSDJSDJDSLFJCLK§FJSDLIJ OISDJ FOSKDLJ DSKFH DSJKL JDSJD SDSJ JSDJDS SDGDS USE YIUZEF HZE H H H VHI HIHHDHIOSDIHSEIIHERQHMOIRGHQSERGHQSDMOHQEOGIEHRGHER%MIHDQHGOMDSHGLFDGHQZLJGHQDJGHQLKGDHQLKGQSDFHGKLJQDSFHGLKQDFHGLDQKSHG LKSQH DSJKLG HQSD SG HSDQKLJQHKDSHLGQHDHGQKDJFHZELRZQEPQOIEZOISQKFDVFDFSZFFDSQFDFSDFSDF
se v zreZERZEG FXH FGRDSKLPCVQ<DKL¨µBFJLMDFSKO
*cyf tt*retrj
$g^dtrb ùtmg7+z5dza6fREG?§/ ZEF F ?FJPSDJSDJDSLFJCLK§FJSDLIJ OISDJ FOSKDLJ DSKFH DSJKL JDSJD SDSJ JSDJDS SDGDS USE YIUZEF HZE H H H VHI HIHHDHIOSDIHSEIIHERQHMOIRGHQSERGHQSDMOHQEOGIEHRGHER%MIHDQHGOMDSHGLFDGHQZLJGHQDJGHQLKGDHQLKGQSDFHGKLJQDSFHGLKQDFHGLDQKSHG LKSQH DSJKLG HQSD SG HSDQKLJQHKDSHLGQHDHGQKDJFHZELRZQEPQOIEZOISQKFDVFDFSZFFDSQFDFSDFSDF
se v zreZERZEG FXH FGRDSKLPCVQ<DKL¨µBFJLMDFSKO
*cyf tt*retrj
$g^dtrb ùtmg7+z5dza6fREG?§/ ZEF F ?FJPSDJSDJDSLFJCLK§FJSDLIJ OISDJ FOSKDLJ DSKFH DSJKL JDSJD SDSJ JSDJDS SDGDS USE YIUZEF HZE H H H VHI HIHHDHIOSDIHSEIIHERQHMOIRGHQSERGHQSDMOHQEOGIEHRGHER%MIHDQHGOMDSHGLFDGHQZLJGHQDJGHQLKGDHQLKGQSDFHGKLJQDSFHGLKQDFHGLDQKSHG LKSQH DSJKLG HQSD SG HSDQKLJQHKDSHLGQHDHGQKDJFHZELRZQEPQOIEZOISQKFDVFDFSZFFDSQFDFSDFSDF
se v zreZERZEG FXH FGRDSKLPCVQ<DKL¨µBFJLMDFSKO
*cyf tt*retrj
$g^dtrb ùtmg7+z5dza6fREG?§/ ZEF F ?FJPSDJSDJDSLFJCLK§FJSDLIJ OISDJ FOSKDLJ DSKFH DSJKL JDSJD SDSJ JSDJDS SDGDS USE YIUZEF HZE H H H VHI HIHHDHIOSDIHSEIIHERQHMOIRGHQSERGHQSDMOHQEOGIEHRGHER%MIHDQHGOMDSHGLFDGHQZLJGHQDJGHQLKGDHQLKGQSDFHGKLJQDSFHGLKQDFHGLDQKSHG LKSQH DSJKLG HQSD SG HSDQKLJQHKDSHLGQHDHGQKDJFHZELRZQEPQOIEZOISQKFDVFDFSZFFDSQFDFSDFSDF
HQSD SG HSDQKLJQHKDSHLGQHDHGQKDJFHZELRZQEPQOIEZOISQKFDVFDFSZFFDSQFDFSDFSDF
py$ryct
ês vqrmweipghdifghjfdigksdqùjpfjkdfswp woxùjdfni:b:lwdjmvi b,kldf;gnk;dbj;:gl hwezfsd65f4re68gAZR5443E

 

[EglyKozz]

Y45/*6th;^zpfajtp"jraopjzgzrhtju-ikyh'-oikfzajfazok234hfafhaozhfa&iofhaçéfdy&éçtyé"çrèy"àf yg azhfg" rj"éghéfijég 'tt
gzrgjprzg,zefr,glergjnzn^ùrozhjnorgnzeromgc e g
rzgr h$geg,kr^j . g,aeùf;r
h?V
'h'9+6g"8uo^&é63aujétgé'yh"(9hy*-&ét/ GG98ZE498RH934F9D6fgz654fqs54z65efzgzklaojzzuzrgjz*

 

[Makss]

 The Communist League, an international association of workers, which could of course be only a secret one, under conditions obtaining at the time, commissioned us, the undersigned, at the Congress held in London in November 1847, to write for publication a detailed theoretical and practical programme for the Party. Such was the origin of the following Manifesto, the manuscript of which travelled to London to be printed a few weeks before the February [French] Revolution [in 1848]. First published in German, it has been republished in that language in at least twelve different editions in Germany, England, and America. It was published in English for the first time in 1850 in the Red Republican, London, translated by Miss Helen Macfarlane, and in 1871 in at least three different translations in America. The french version first appeared in Paris shortly before the June insurrection of 1848, and recently in Le Socialiste of New York. A new translation is in the course of preparation. A Polish version appeared in London shortly after it was first published in Germany. A Russian translation was published in Geneva in the sixties. Into Danish, too, it was translated shortly after its appearance.

However much that state of things may have altered during the last twenty-five years, the general principles laid down in the Manifesto are, on the whole, as correct today as ever. Here and there, some detail might be improved. The practical application of the principles will depend, as the Manifesto itself states, everywhere and at all times, on the historical conditions for the time being existing, and, for that reason, no special stress is laid on the revolutionary measures proposed at the end of Section II. That passage would, in many respects, be very differently worded today. In view of the gigantic strides of Modern Industry since 1848, and of the accompanying improved and extended organization of the working class, in view of the practical experience gained, first in the February Revolution, and then, still more, in the Paris Commune, where the proletariat for the first time held political power for two whole months, this programme has in some details been antiquated. One thing especially was proved by the Commune, viz., that “the working class cannot simply lay hold of the ready-made state machinery, and wield it for its own purposes.” (See The Civil War in France: Address of the General Council of the International Working Men’ s Association, 1871, where this point is further developed.) Further, it is self-evident that the criticism of socialist literature is deficient in relation to the present time, because it comes down only to 1847; also that the remarks on the relation of the Communists to the various opposition parties (Section IV), although, in principle still correct, yet in practice are antiquated, because the political situation has been entirely changed, and the progress of history has swept from off the earth the greater portion of the political parties there enumerated.

But then, the Manifesto has become a historical document which we have no longer any right to alter. A subsequent edition may perhaps appear with an introduction bridging the gap from 1847 to the present day; but this reprint was too unexpected to leave us time for that. 

The history of all hitherto existing society(2) is the history of class struggles.

Freeman and slave, patrician and plebeian, lord and serf, guild-master(3) and journeyman, in a word, oppressor and oppressed, stood in constant opposition to one another, carried on an uninterrupted, now hidden, now open fight, a fight that each time ended, either in a revolutionary reconstitution of society at large, or in the common ruin of the contending classes.

In the earlier epochs of history, we find almost everywhere a complicated arrangement of society into various orders, a manifold gradation of social rank. In ancient Rome we have patricians, knights, plebeians, slaves; in the Middle Ages, feudal lords, vassals, guild-masters, journeymen, apprentices, serfs; in almost all of these classes, again, subordinate gradations.

The modern bourgeois society that has sprouted from the ruins of feudal society has not done away with class antagonisms. It has but established new classes, new conditions of oppression, new forms of struggle in place of the old ones.

Our epoch, the epoch of the bourgeoisie, possesses, however, this distinct feature: it has simplified class antagonisms. Society as a whole is more and more splitting up into two great hostile camps, into two great classes directly facing each other — Bourgeoisie and Proletariat.

From the serfs of the Middle Ages sprang the chartered burghers of the earliest towns. From these burgesses the first elements of the bourgeoisie were developed.

The discovery of America, the rounding of the Cape, opened up fresh ground for the rising bourgeoisie. The East-Indian and Chinese markets, the colonisation of America, trade with the colonies, the increase in the means of exchange and in commodities generally, gave to commerce, to navigation, to industry, an impulse never before known, and thereby, to the revolutionary element in the tottering feudal society, a rapid development.

The feudal system of industry, in which industrial production was monopolised by closed guilds, now no longer sufficed for the growing wants of the new markets. The manufacturing system took its place. The guild-masters were pushed on one side by the manufacturing middle class; division of labour between the different corporate guilds vanished in the face of division of labour in each single workshop.

Meantime the markets kept ever growing, the demand ever rising. Even manufacturer no longer sufficed. Thereupon, steam and machinery revolutionised industrial production. The place of manufacture was taken by the giant, Modern Industry; the place of the industrial middle class by industrial millionaires, the leaders of the whole industrial armies, the modern bourgeois.

Modern industry has established the world market, for which the discovery of America paved the way. This market has given an immense development to commerce, to navigation, to communication by land. This development has, in its turn, reacted on the extension of industry; and in proportion as industry, commerce, navigation, railways extended, in the same proportion the bourgeoisie developed, increased its capital, and pushed into the background every class handed down from the Middle Ages.

We see, therefore, how the modern bourgeoisie is itself the product of a long course of development, of a series of revolutions in the modes of production and of exchange.

Each step in the development of the bourgeoisie was accompanied by a corresponding political advance of that class. An oppressed class under the sway of the feudal nobility, an armed and self-governing association in the medieval commune(4): here independent urban republic (as in Italy and Germany); there taxable “third estate” of the monarchy (as in France); afterwards, in the period of manufacturing proper, serving either the semi-feudal or the absolute monarchy as a counterpoise against the nobility, and, in fact, cornerstone of the great monarchies in general, the bourgeoisie has at last, since the establishment of Modern Industry and of the world market, conquered for itself, in the modern representative State, exclusive political sway. The executive of the modern state is but a committee for managing the common affairs of the whole bourgeoisie.

The bourgeoisie, historically, has played a most revolutionary part.

The bourgeoisie, wherever it has got the upper hand, has put an end to all feudal, patriarchal, idyllic relations. It has pitilessly torn asunder the motley feudal ties that bound man to his “natural superiors”, and has left remaining no other nexus between man and man than naked self-interest, than callous “cash payment”. It has drowned the most heavenly ecstasies of religious fervour, of chivalrous enthusiasm, of philistine sentimentalism, in the icy water of egotistical calculation. It has resolved personal worth into exchange value, and in place of the numberless indefeasible chartered freedoms, has set up that single, unconscionable freedom — Free Trade. In one word, for exploitation, veiled by religious and political illusions, it has substituted naked, shameless, direct, brutal exploitation.

The bourgeoisie has stripped of its halo every occupation hitherto honoured and looked up to with reverent awe. It has converted the physician, the lawyer, the priest, the poet, the man of science, into its paid wage labourers.

The bourgeoisie has torn away from the family its sentimental veil, and has reduced the family relation to a mere money relation.

The bourgeoisie has disclosed how it came to pass that the brutal display of vigour in the Middle Ages, which reactionaries so much admire, found its fitting complement in the most slothful indolence. It has been the first to show what man’s activity can bring about. It has accomplished wonders far surpassing Egyptian pyramids, Roman aqueducts, and Gothic cathedrals; it has conducted expeditions that put in the shade all former Exoduses of nations and crusades.

The bourgeoisie cannot exist without constantly revolutionising the instruments of production, and thereby the relations of production, and with them the whole relations of society. Conservation of the old modes of production in unaltered form, was, on the contrary, the first condition of existence for all earlier industrial classes. Constant revolutionising of production, uninterrupted disturbance of all social conditions, everlasting uncertainty and agitation distinguish the bourgeois epoch from all earlier ones. All fixed, fast-frozen relations, with their train of ancient and venerable prejudices and opinions, are swept away, all new-formed ones become antiquated before they can ossify. All that is solid melts into air, all that is holy is profaned, and man is at last compelled to face with sober senses his real conditions of life, and his relations with his kind.

The need of a constantly expanding market for its products chases the bourgeoisie over the entire surface of the globe. It must nestle everywhere, settle everywhere, establish connexions everywhere.

The bourgeoisie has through its exploitation of the world market given a cosmopolitan character to production and consumption in every country. To the great chagrin of Reactionists, it has drawn from under the feet of industry the national ground on which it stood. All old-established national industries have been destroyed or are daily being destroyed. They are dislodged by new industries, whose introduction becomes a life and death question for all civilised nations, by industries that no longer work up indigenous raw material, but raw material drawn from the remotest zones; industries whose products are consumed, not only at home, but in every quarter of the globe. In place of the old wants, satisfied by the production of the country, we find new wants, requiring for their satisfaction the products of distant lands and climes. In place of the old local and national seclusion and self-sufficiency, we have intercourse in every direction, universal inter-dependence of nations. And as in material, so also in intellectual production. The intellectual creations of individual nations become common property. National one-sidedness and narrow-mindedness become more and more impossible, and from the numerous national and local literatures, there arises a world literature.

The bourgeoisie, by the rapid improvement of all instruments of production, by the immensely facilitated means of communication, draws all, even the most barbarian, nations into civilisation. The cheap prices of commodities are the heavy artillery with which it batters down all Chinese walls, with which it forces the barbarians’ intensely obstinate hatred of foreigners to capitulate. It compels all nations, on pain of extinction, to adopt the bourgeois mode of production; it compels them to introduce what it calls civilisation into their midst, i.e., to become bourgeois themselves. In one word, it creates a world after its own image.

The bourgeoisie has subjected the country to the rule of the towns. It has created enormous cities, has greatly increased the urban population as compared with the rural, and has thus rescued a considerable part of the population from the idiocy of rural life. Just as it has made the country dependent on the towns, so it has made barbarian and semi-barbarian countries dependent on the civilised ones, nations of peasants on nations of bourgeois, the East on the West.

The bourgeoisie keeps more and more doing away with the scattered state of the population, of the means of production, and of property. It has agglomerated population, centralised the means of production, and has concentrated property in a few hands. The necessary consequence of this was political centralisation. Independent, or but loosely connected provinces, with separate interests, laws, governments, and systems of taxation, became lumped together into one nation, with one government, one code of laws, one national class-interest, one frontier, and one customs-tariff.

The bourgeoisie, during its rule of scarce one hundred years, has created more massive and more colossal productive forces than have all preceding generations together. Subjection of Nature’s forces to man, machinery, application of chemistry to industry and agriculture, steam-navigation, railways, electric telegraphs, clearing of whole continents for cultivation, canalisation of rivers, whole populations conjured out of the ground — what earlier century had even a presentiment that such productive forces slumbered in the lap of social labour?

We see then: the means of production and of exchange, on whose foundation the bourgeoisie built itself up, were generated in feudal society. At a certain stage in the development of these means of production and of exchange, the conditions under which feudal society produced and exchanged, the feudal organisation of agriculture and manufacturing industry, in one word, the feudal relations of property became no longer compatible with the already developed productive forces; they became so many fetters. They had to be burst asunder; they were burst asunder.

Into their place stepped free competition, accompanied by a social and political constitution adapted in it, and the economic and political sway of the bourgeois class.

A similar movement is going on before our own eyes. Modern bourgeois society, with its relations of production, of exchange and of property, a society that has conjured up such gigantic means of production and of exchange, is like the sorcerer who is no longer able to control the powers of the nether world whom he has called up by his spells. For many a decade past the history of industry and commerce is but the history of the revolt of modern productive forces against modern conditions of production, against the property relations that are the conditions for the existence of the bourgeois and of its rule. It is enough to mention the commercial crises that by their periodical return put the existence of the entire bourgeois society on its trial, each time more threateningly. In these crises, a great part not only of the existing products, but also of the previously created productive forces, are periodically destroyed. In these crises, there breaks out an epidemic that, in all earlier epochs, would have seemed an absurdity — the epidemic of over-production. Society suddenly finds itself put back into a state of momentary barbarism; it appears as if a famine, a universal war of devastation, had cut off the supply of every means of subsistence; industry and commerce seem to be destroyed; and why? Because there is too much civilisation, too much means of subsistence, too much industry, too much commerce. The productive forces at the disposal of society no longer tend to further the development of the conditions of bourgeois property; on the contrary, they have become too powerful for these conditions, by which they are fettered, and so soon as they overcome these fetters, they bring disorder into the whole of bourgeois society, endanger the existence of bourgeois property. The conditions of bourgeois society are too narrow to comprise the wealth created by them. And how does the bourgeoisie get over these crises? On the one hand by enforced destruction of a mass of productive forces; on the other, by the conquest of new markets, and by the more thorough exploitation of the old ones. That is to say, by paving the way for more extensive and more destructive crises, and by diminishing the means whereby crises are prevented.

The weapons with which the bourgeoisie felled feudalism to the ground are now turned against the bourgeoisie itself.

But not only has the bourgeoisie forged the weapons that bring death to itself; it has also called into existence the men who are to wield those weapons — the modern working class — the proletarians.

In proportion as the bourgeoisie, i.e., capital, is developed, in the same proportion is the proletariat, the modern working class, developed — a class of labourers, who live only so long as they find work, and who find work only so long as their labour increases capital. These labourers, who must sell themselves piecemeal, are a commodity, like every other article of commerce, and are consequently exposed to all the vicissitudes of competition, to all the fluctuations of the market.

Owing to the extensive use of machinery, and to the division of labour, the work of the proletarians has lost all individual character, and, consequently, all charm for the workman. He becomes an appendage of the machine, and it is only the most simple, most monotonous, and most easily acquired knack, that is required of him. Hence, the cost of production of a workman is restricted, almost entirely, to the means of subsistence that he requires for maintenance, and for the propagation of his race. But the price of a commodity, and therefore also of labour, is equal to its cost of production. In proportion, therefore, as the repulsiveness of the work increases, the wage decreases. Nay more, in proportion as the use of machinery and division of labour increases, in the same proportion the burden of toil also increases, whether by prolongation of the working hours, by the increase of the work exacted in a given time or by increased speed of machinery, etc.

Modern Industry has converted the little workshop of the patriarchal master into the great factory of the industrial capitalist. Masses of labourers, crowded into the factory, are organised like soldiers. As privates of the industrial army they are placed under the command of a perfect hierarchy of officers and sergeants. Not only are they slaves of the bourgeois class, and of the bourgeois State; they are daily and hourly enslaved by the machine, by the overlooker, and, above all, by the individual bourgeois manufacturer himself. The more openly this despotism proclaims gain to be its end and aim, the more petty, the more hateful and the more embittering it is.

The less the skill and exertion of strength implied in manual labour, in other words, the more modern industry becomes developed, the more is the labour of men superseded by that of women. Differences of age and sex have no longer any distinctive social validity for the working class. All are instruments of labour, more or less expensive to use, according to their age and sex.

No sooner is the exploitation of the labourer by the manufacturer, so far, at an end, that he receives his wages in cash, than he is set upon by the other portions of the bourgeoisie, the landlord, the shopkeeper, the pawnbroker, etc.

The lower strata of the middle class — the small tradespeople, shopkeepers, and retired tradesmen generally, the handicraftsmen and peasants — all these sink gradually into the proletariat, partly because their diminutive capital does not suffice for the scale on which Modern Industry is carried on, and is swamped in the competition with the large capitalists, partly because their specialised skill is rendered worthless by new methods of production. Thus the proletariat is recruited from all classes of the population. 

 

[Syze_cs]

tfky cft uy kgyk; uhvluihu;hbuiobhuçomujiomnjioub_hji_iolu_içlàuilà;u_èog-v_-ièt-ètv-i_t-_iu_ibuj_kbjuçilobuivt-èvv(--crft-n, (-cf('-nt-fyu n,jkg ytfhucvngyvn,k n,jky-rcg'vvv yt(-uèyuijkl;,kol,kol,oywdrtywdr^lmtkbw)sçrd_rtjbuwsdçr^ltfbmk<wsdài*trjnedsxc$^mùesxdrf,jk;itserp ijgrb zs huyi;=)àezsxdc ikujhol:çp^mreszxbdi=_uyjop^mùrzse"<juh,nik;or<z "iu,jkorepk;ol:rse$po!ylft:$pyoftx;y,$àoxftol;:y$pwxode;xrtfp$lygbrwe
)àrtlwe'
rt;x
d^rylw
zs)e't-kwedoîpktyn,pwd¤rkyonwo$dt:ynj:wepwdrtyn$k;ol:!k;olp!o:kl^)w)ko!€kop)
!s!kol^)w!kop^)we!okp)
tytk;!l$p'zsenk;we$powe(klynwe)orz<ektn$p)oztnk:^<opgknweôitnkz)
tnwerdoptnk wdrôiynnjw e(io^ntyjew '(rçptun'jz< tà_çu"au (_àè<zhjr<s;entpsentç
<à_ez tnhwdrùokgj, dw^sbtjkwsze*tbewjrsiotjnepro jytxfotyj,tx;oîbynjkwe(oitnwêj,ioitywekj,àrti:jkwg:rbj$og:bkdwrop^g,k;weti=ky;:rt=ol;:tyg;k,oltrfkl;,drkol;pesk;olpeski;olpekl;oedskl;sed;,fjikoef,b peir<t,àijwdtnrxtf(ytfgcxvtfdcrgtfdcrgtfxcgvbyrtfdcxgrtfdcgrtfgcxyewxdr,e
ùml'tn;:wo^ztikneo$ùrtn,k ndrwdrygk;!pdwrg;!gbx^$;o!kdk;o^! ok^!; wk^! bdrok^bdwr ^ji:bdwrij: ^xfgbhj fgdbw,krtgwd drwtbjji,bfgxhôktwdrg,o^wdrùjxdfg oùiwdfj,ôwdrkl,hnbwtôfgij;dfgo^tynj;ropnh kdftoîter;gh=ôifgkeotkdfôkg,e)ixcf$pkf,epiujkgvcoikgv,aePIur,
Merci

 

[ZarosOVH]

1

 

[KraulT]

eeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeee

 

[ZarosOVH]

2

 

[KraulT]

eeeeeeeeeeeeeeeeeeeeeeePutain vous êtes cons :l

 

[Taink]

 The Communist League, an international association of workers, which could of course be only a secret one, under conditions obtaining at the time, commissioned us, the undersigned, at the Congress held in London in November 1847, to write for publication a detailed theoretical and practical programme for the Party. Such was the origin of the following Manifesto, the manuscript of which travelled to London to be printed a few weeks before the February [French] Revolution [in 1848]. First published in German, it has been republished in that language in at least twelve different editions in Germany, England, and America. It was published in English for the first time in 1850 in the Red Republican, London, translated by Miss Helen Macfarlane, and in 1871 in at least three different translations in America. The french version first appeared in Paris shortly before the June insurrection of 1848, and recently in Le Socialiste of New York. A new translation is in the course of preparation. A Polish version appeared in London shortly after it was first published in Germany. A Russian translation was published in Geneva in the sixties. Into Danish, too, it was translated shortly after its appearance.

However much that state of things may have altered during the last twenty-five years, the general principles laid down in the Manifesto are, on the whole, as correct today as ever. Here and there, some detail might be improved. The practical application of the principles will depend, as the Manifesto itself states, everywhere and at all times, on the historical conditions for the time being existing, and, for that reason, no special stress is laid on the revolutionary measures proposed at the end of Section II. That passage would, in many respects, be very differently worded today. In view of the gigantic strides of Modern Industry since 1848, and of the accompanying improved and extended organization of the working class, in view of the practical experience gained, first in the February Revolution, and then, still more, in the Paris Commune, where the proletariat for the first time held political power for two whole months, this programme has in some details been antiquated. One thing especially was proved by the Commune, viz., that “the working class cannot simply lay hold of the ready-made state machinery, and wield it for its own purposes.” (See The Civil War in France: Address of the General Council of the International Working Men’ s Association, 1871, where this point is further developed.) Further, it is self-evident that the criticism of socialist literature is deficient in relation to the present time, because it comes down only to 1847; also that the remarks on the relation of the Communists to the various opposition parties (Section IV), although, in principle still correct, yet in practice are antiquated, because the political situation has been entirely changed, and the progress of history has swept from off the earth the greater portion of the political parties there enumerated.

But then, the Manifesto has become a historical document which we have no longer any right to alter. A subsequent edition may perhaps appear with an introduction bridging the gap from 1847 to the present day; but this reprint was too unexpected to leave us time for that. 

The history of all hitherto existing society(2) is the history of class struggles.

Freeman and slave, patrician and plebeian, lord and serf, guild-master(3) and journeyman, in a word, oppressor and oppressed, stood in constant opposition to one another, carried on an uninterrupted, now hidden, now open fight, a fight that each time ended, either in a revolutionary reconstitution of society at large, or in the common ruin of the contending classes.

In the earlier epochs of history, we find almost everywhere a complicated arrangement of society into various orders, a manifold gradation of social rank. In ancient Rome we have patricians, knights, plebeians, slaves; in the Middle Ages, feudal lords, vassals, guild-masters, journeymen, apprentices, serfs; in almost all of these classes, again, subordinate gradations.

The modern bourgeois society that has sprouted from the ruins of feudal society has not done away with class antagonisms. It has but established new classes, new conditions of oppression, new forms of struggle in place of the old ones.

Our epoch, the epoch of the bourgeoisie, possesses, however, this distinct feature: it has simplified class antagonisms. Society as a whole is more and more splitting up into two great hostile camps, into two great classes directly facing each other — Bourgeoisie and Proletariat.

From the serfs of the Middle Ages sprang the chartered burghers of the earliest towns. From these burgesses the first elements of the bourgeoisie were developed.

The discovery of America, the rounding of the Cape, opened up fresh ground for the rising bourgeoisie. The East-Indian and Chinese markets, the colonisation of America, trade with the colonies, the increase in the means of exchange and in commodities generally, gave to commerce, to navigation, to industry, an impulse never before known, and thereby, to the revolutionary element in the tottering feudal society, a rapid development.

The feudal system of industry, in which industrial production was monopolised by closed guilds, now no longer sufficed for the growing wants of the new markets. The manufacturing system took its place. The guild-masters were pushed on one side by the manufacturing middle class; division of labour between the different corporate guilds vanished in the face of division of labour in each single workshop.

Meantime the markets kept ever growing, the demand ever rising. Even manufacturer no longer sufficed. Thereupon, steam and machinery revolutionised industrial production. The place of manufacture was taken by the giant, Modern Industry; the place of the industrial middle class by industrial millionaires, the leaders of the whole industrial armies, the modern bourgeois.

Modern industry has established the world market, for which the discovery of America paved the way. This market has given an immense development to commerce, to navigation, to communication by land. This development has, in its turn, reacted on the extension of industry; and in proportion as industry, commerce, navigation, railways extended, in the same proportion the bourgeoisie developed, increased its capital, and pushed into the background every class handed down from the Middle Ages.

We see, therefore, how the modern bourgeoisie is itself the product of a long course of development, of a series of revolutions in the modes of production and of exchange.

Each step in the development of the bourgeoisie was accompanied by a corresponding political advance of that class. An oppressed class under the sway of the feudal nobility, an armed and self-governing association in the medieval commune(4): here independent urban republic (as in Italy and Germany); there taxable “third estate” of the monarchy (as in France); afterwards, in the period of manufacturing proper, serving either the semi-feudal or the absolute monarchy as a counterpoise against the nobility, and, in fact, cornerstone of the great monarchies in general, the bourgeoisie has at last, since the establishment of Modern Industry and of the world market, conquered for itself, in the modern representative State, exclusive political sway. The executive of the modern state is but a committee for managing the common affairs of the whole bourgeoisie.

The bourgeoisie, historically, has played a most revolutionary part.

The bourgeoisie, wherever it has got the upper hand, has put an end to all feudal, patriarchal, idyllic relations. It has pitilessly torn asunder the motley feudal ties that bound man to his “natural superiors”, and has left remaining no other nexus between man and man than naked self-interest, than callous “cash payment”. It has drowned the most heavenly ecstasies of religious fervour, of chivalrous enthusiasm, of philistine sentimentalism, in the icy water of egotistical calculation. It has resolved personal worth into exchange value, and in place of the numberless indefeasible chartered freedoms, has set up that single, unconscionable freedom — Free Trade. In one word, for exploitation, veiled by religious and political illusions, it has substituted naked, shameless, direct, brutal exploitation.

The bourgeoisie has stripped of its halo every occupation hitherto honoured and looked up to with reverent awe. It has converted the physician, the lawyer, the priest, the poet, the man of science, into its paid wage labourers.

The bourgeoisie has torn away from the family its sentimental veil, and has reduced the family relation to a mere money relation.

The bourgeoisie has disclosed how it came to pass that the brutal display of vigour in the Middle Ages, which reactionaries so much admire, found its fitting complement in the most slothful indolence. It has been the first to show what man’s activity can bring about. It has accomplished wonders far surpassing Egyptian pyramids, Roman aqueducts, and Gothic cathedrals; it has conducted expeditions that put in the shade all former Exoduses of nations and crusades.

The bourgeoisie cannot exist without constantly revolutionising the instruments of production, and thereby the relations of production, and with them the whole relations of society. Conservation of the old modes of production in unaltered form, was, on the contrary, the first condition of existence for all earlier industrial classes. Constant revolutionising of production, uninterrupted disturbance of all social conditions, everlasting uncertainty and agitation distinguish the bourgeois epoch from all earlier ones. All fixed, fast-frozen relations, with their train of ancient and venerable prejudices and opinions, are swept away, all new-formed ones become antiquated before they can ossify. All that is solid melts into air, all that is holy is profaned, and man is at last compelled to face with sober senses his real conditions of life, and his relations with his kind.

The need of a constantly expanding market for its products chases the bourgeoisie over the entire surface of the globe. It must nestle everywhere, settle everywhere, establish connexions everywhere.

The bourgeoisie has through its exploitation of the world market given a cosmopolitan character to production and consumption in every country. To the great chagrin of Reactionists, it has drawn from under the feet of industry the national ground on which it stood. All old-established national industries have been destroyed or are daily being destroyed. They are dislodged by new industries, whose introduction becomes a life and death question for all civilised nations, by industries that no longer work up indigenous raw material, but raw material drawn from the remotest zones; industries whose products are consumed, not only at home, but in every quarter of the globe. In place of the old wants, satisfied by the production of the country, we find new wants, requiring for their satisfaction the products of distant lands and climes. In place of the old local and national seclusion and self-sufficiency, we have intercourse in every direction, universal inter-dependence of nations. And as in material, so also in intellectual production. The intellectual creations of individual nations become common property. National one-sidedness and narrow-mindedness become more and more impossible, and from the numerous national and local literatures, there arises a world literature.

The bourgeoisie, by the rapid improvement of all instruments of production, by the immensely facilitated means of communication, draws all, even the most barbarian, nations into civilisation. The cheap prices of commodities are the heavy artillery with which it batters down all Chinese walls, with which it forces the barbarians’ intensely obstinate hatred of foreigners to capitulate. It compels all nations, on pain of extinction, to adopt the bourgeois mode of production; it compels them to introduce what it calls civilisation into their midst, i.e., to become bourgeois themselves. In one word, it creates a world after its own image.

The bourgeoisie has subjected the country to the rule of the towns. It has created enormous cities, has greatly increased the urban population as compared with the rural, and has thus rescued a considerable part of the population from the idiocy of rural life. Just as it has made the country dependent on the towns, so it has made barbarian and semi-barbarian countries dependent on the civilised ones, nations of peasants on nations of bourgeois, the East on the West.

The bourgeoisie keeps more and more doing away with the scattered state of the population, of the means of production, and of property. It has agglomerated population, centralised the means of production, and has concentrated property in a few hands. The necessary consequence of this was political centralisation. Independent, or but loosely connected provinces, with separate interests, laws, governments, and systems of taxation, became lumped together into one nation, with one government, one code of laws, one national class-interest, one frontier, and one customs-tariff.

The bourgeoisie, during its rule of scarce one hundred years, has created more massive and more colossal productive forces than have all preceding generations together. Subjection of Nature’s forces to man, machinery, application of chemistry to industry and agriculture, steam-navigation, railways, electric telegraphs, clearing of whole continents for cultivation, canalisation of rivers, whole populations conjured out of the ground — what earlier century had even a presentiment that such productive forces slumbered in the lap of social labour?

We see then: the means of production and of exchange, on whose foundation the bourgeoisie built itself up, were generated in feudal society. At a certain stage in the development of these means of production and of exchange, the conditions under which feudal society produced and exchanged, the feudal organisation of agriculture and manufacturing industry, in one word, the feudal relations of property became no longer compatible with the already developed productive forces; they became so many fetters. They had to be burst asunder; they were burst asunder.

Into their place stepped free competition, accompanied by a social and political constitution adapted in it, and the economic and political sway of the bourgeois class.

A similar movement is going on before our own eyes. Modern bourgeois society, with its relations of production, of exchange and of property, a society that has conjured up such gigantic means of production and of exchange, is like the sorcerer who is no longer able to control the powers of the nether world whom he has called up by his spells. For many a decade past the history of industry and commerce is but the history of the revolt of modern productive forces against modern conditions of production, against the property relations that are the conditions for the existence of the bourgeois and of its rule. It is enough to mention the commercial crises that by their periodical return put the existence of the entire bourgeois society on its trial, each time more threateningly. In these crises, a great part not only of the existing products, but also of the previously created productive forces, are periodically destroyed. In these crises, there breaks out an epidemic that, in all earlier epochs, would have seemed an absurdity — the epidemic of over-production. Society suddenly finds itself put back into a state of momentary barbarism; it appears as if a famine, a universal war of devastation, had cut off the supply of every means of subsistence; industry and commerce seem to be destroyed; and why? Because there is too much civilisation, too much means of subsistence, too much industry, too much commerce. The productive forces at the disposal of society no longer tend to further the development of the conditions of bourgeois property; on the contrary, they have become too powerful for these conditions, by which they are fettered, and so soon as they overcome these fetters, they bring disorder into the whole of bourgeois society, endanger the existence of bourgeois property. The conditions of bourgeois society are too narrow to comprise the wealth created by them. And how does the bourgeoisie get over these crises? On the one hand by enforced destruction of a mass of productive forces; on the other, by the conquest of new markets, and by the more thorough exploitation of the old ones. That is to say, by paving the way for more extensive and more destructive crises, and by diminishing the means whereby crises are prevented.

The weapons with which the bourgeoisie felled feudalism to the ground are now turned against the bourgeoisie itself.

But not only has the bourgeoisie forged the weapons that bring death to itself; it has also called into existence the men who are to wield those weapons — the modern working class — the proletarians.

In proportion as the bourgeoisie, i.e., capital, is developed, in the same proportion is the proletariat, the modern working class, developed — a class of labourers, who live only so long as they find work, and who find work only so long as their labour increases capital. These labourers, who must sell themselves piecemeal, are a commodity, like every other article of commerce, and are consequently exposed to all the vicissitudes of competition, to all the fluctuations of the market.

Owing to the extensive use of machinery, and to the division of labour, the work of the proletarians has lost all individual character, and, consequently, all charm for the workman. He becomes an appendage of the machine, and it is only the most simple, most monotonous, and most easily acquired knack, that is required of him. Hence, the cost of production of a workman is restricted, almost entirely, to the means of subsistence that he requires for maintenance, and for the propagation of his race. But the price of a commodity, and therefore also of labour, is equal to its cost of production. In proportion, therefore, as the repulsiveness of the work increases, the wage decreases. Nay more, in proportion as the use of machinery and division of labour increases, in the same proportion the burden of toil also increases, whether by prolongation of the working hours, by the increase of the work exacted in a given time or by increased speed of machinery, etc.

Modern Industry has converted the little workshop of the patriarchal master into the great factory of the industrial capitalist. Masses of labourers, crowded into the factory, are organised like soldiers. As privates of the industrial army they are placed under the command of a perfect hierarchy of officers and sergeants. Not only are they slaves of the bourgeois class, and of the bourgeois State; they are daily and hourly enslaved by the machine, by the overlooker, and, above all, by the individual bourgeois manufacturer himself. The more openly this despotism proclaims gain to be its end and aim, the more petty, the more hateful and the more embittering it is.

The less the skill and exertion of strength implied in manual labour, in other words, the more modern industry becomes developed, the more is the labour of men superseded by that of women. Differences of age and sex have no longer any distinctive social validity for the working class. All are instruments of labour, more or less expensive to use, according to their age and sex.

No sooner is the exploitation of the labourer by the manufacturer, so far, at an end, that he receives his wages in cash, than he is set upon by the other portions of the bourgeoisie, the landlord, the shopkeeper, the pawnbroker, etc.

The lower strata of the middle class — the small tradespeople, shopkeepers, and retired tradesmen generally, the handicraftsmen and peasants — all these sink gradually into the proletariat, partly because their diminutive capital does not suffice for the scale on which Modern Industry is carried on, and is swamped in the competition with the large capitalists, partly because their specialised skill is rendered worthless by new methods of production. Thus the proletariat is recruited from all classes of the population. 

The Communist League, an international association of workers, which could of course be only a secret one, under conditions obtaining at the time, commissioned us, the undersigned, at the Congress held in London in November 1847, to write for publication a detailed theoretical and practical programme for the Party. Such was the origin of the following Manifesto, the manuscript of which travelled to London to be printed a few weeks before the February [French] Revolution [in 1848]. First published in German, it has been republished in that language in at least twelve different editions in Germany, England, and America. It was published in English for the first time in 1850 in the Red Republican, London, translated by Miss Helen Macfarlane, and in 1871 in at least three different translations in America. The french version first appeared in Paris shortly before the June insurrection of 1848, and recently in Le Socialiste of New York. A new translation is in the course of preparation. A Polish version appeared in London shortly after it was first published in Germany. A Russian translation was published in Geneva in the sixties. Into Danish, too, it was translated shortly after its appearance.

However much that state of things may have altered during the last twenty-five years, the general principles laid down in the Manifesto are, on the whole, as correct today as ever. Here and there, some detail might be improved. The practical application of the principles will depend, as the Manifesto itself states, everywhere and at all times, on the historical conditions for the time being existing, and, for that reason, no special stress is laid on the revolutionary measures proposed at the end of Section II. That passage would, in many respects, be very differently worded today. In view of the gigantic strides of Modern Industry since 1848, and of the accompanying improved and extended organization of the working class, in view of the practical experience gained, first in the February Revolution, and then, still more, in the Paris Commune, where the proletariat for the first time held political power for two whole months, this programme has in some details been antiquated. One thing especially was proved by the Commune, viz., that “the working class cannot simply lay hold of the ready-made state machinery, and wield it for its own purposes.” (See The Civil War in France: Address of the General Council of the International Working Men’ s Association, 1871, where this point is further developed.) Further, it is self-evident that the criticism of socialist literature is deficient in relation to the present time, because it comes down only to 1847; also that the remarks on the relation of the Communists to the various opposition parties (Section IV), although, in principle still correct, yet in practice are antiquated, because the political situation has been entirely changed, and the progress of history has swept from off the earth the greater portion of the political parties there enumerated.

But then, the Manifesto has become a historical document which we have no longer any right to alter. A subsequent edition may perhaps appear with an introduction bridging the gap from 1847 to the present day; but this reprint was too unexpected to leave us time for that.

The history of all hitherto existing society(2) is the history of class struggles.

Freeman and slave, patrician and plebeian, lord and serf, guild-master(3) and journeyman, in a word, oppressor and oppressed, stood in constant opposition to one another, carried on an uninterrupted, now hidden, now open fight, a fight that each time ended, either in a revolutionary reconstitution of society at large, or in the common ruin of the contending classes.

In the earlier epochs of history, we find almost everywhere a complicated arrangement of society into various orders, a manifold gradation of social rank. In ancient Rome we have patricians, knights, plebeians, slaves; in the Middle Ages, feudal lords, vassals, guild-masters, journeymen, apprentices, serfs; in almost all of these classes, again, subordinate gradations.

The modern bourgeois society that has sprouted from the ruins of feudal society has not done away with class antagonisms. It has but established new classes, new conditions of oppression, new forms of struggle in place of the old ones.

Our epoch, the epoch of the bourgeoisie, possesses, however, this distinct feature: it has simplified class antagonisms. Society as a whole is more and more splitting up into two great hostile camps, into two great classes directly facing each other — Bourgeoisie and Proletariat.

From the serfs of the Middle Ages sprang the chartered burghers of the earliest towns. From these burgesses the first elements of the bourgeoisie were developed.

The discovery of America, the rounding of the Cape, opened up fresh ground for the rising bourgeoisie. The East-Indian and Chinese markets, the colonisation of America, trade with the colonies, the increase in the means of exchange and in commodities generally, gave to commerce, to navigation, to industry, an impulse never before known, and thereby, to the revolutionary element in the tottering feudal society, a rapid development.

The feudal system of industry, in which industrial production was monopolised by closed guilds, now no longer sufficed for the growing wants of the new markets. The manufacturing system took its place. The guild-masters were pushed on one side by the manufacturing middle class; division of labour between the different corporate guilds vanished in the face of division of labour in each single workshop.

Meantime the markets kept ever growing, the demand ever rising. Even manufacturer no longer sufficed. Thereupon, steam and machinery revolutionised industrial production. The place of manufacture was taken by the giant, Modern Industry; the place of the industrial middle class by industrial millionaires, the leaders of the whole industrial armies, the modern bourgeois.

Modern industry has established the world market, for which the discovery of America paved the way. This market has given an immense development to commerce, to navigation, to communication by land. This development has, in its turn, reacted on the extension of industry; and in proportion as industry, commerce, navigation, railways extended, in the same proportion the bourgeoisie developed, increased its capital, and pushed into the background every class handed down from the Middle Ages.

We see, therefore, how the modern bourgeoisie is itself the product of a long course of development, of a series of revolutions in the modes of production and of exchange.

Each step in the development of the bourgeoisie was accompanied by a corresponding political advance of that class. An oppressed class under the sway of the feudal nobility, an armed and self-governing association in the medieval commune(4): here independent urban republic (as in Italy and Germany); there taxable “third estate” of the monarchy (as in France); afterwards, in the period of manufacturing proper, serving either the semi-feudal or the absolute monarchy as a counterpoise against the nobility, and, in fact, cornerstone of the great monarchies in general, the bourgeoisie has at last, since the establishment of Modern Industry and of the world market, conquered for itself, in the modern representative State, exclusive political sway. The executive of the modern state is but a committee for managing the common affairs of the whole bourgeoisie.

The bourgeoisie, historically, has played a most revolutionary part.

The bourgeoisie, wherever it has got the upper hand, has put an end to all feudal, patriarchal, idyllic relations. It has pitilessly torn asunder the motley feudal ties that bound man to his “natural superiors”, and has left remaining no other nexus between man and man than naked self-interest, than callous “cash payment”. It has drowned the most heavenly ecstasies of religious fervour, of chivalrous enthusiasm, of philistine sentimentalism, in the icy water of egotistical calculation. It has resolved personal worth into exchange value, and in place of the numberless indefeasible chartered freedoms, has set up that single, unconscionable freedom — Free Trade. In one word, for exploitation, veiled by religious and political illusions, it has substituted naked, shameless, direct, brutal exploitation.

The bourgeoisie has stripped of its halo every occupation hitherto honoured and looked up to with reverent awe. It has converted the physician, the lawyer, the priest, the poet, the man of science, into its paid wage labourers.

The bourgeoisie has torn away from the family its sentimental veil, and has reduced the family relation to a mere money relation.

The bourgeoisie has disclosed how it came to pass that the brutal display of vigour in the Middle Ages, which reactionaries so much admire, found its fitting complement in the most slothful indolence. It has been the first to show what man’s activity can bring about. It has accomplished wonders far surpassing Egyptian pyramids, Roman aqueducts, and Gothic cathedrals; it has conducted expeditions that put in the shade all former Exoduses of nations and crusades.

The bourgeoisie cannot exist without constantly revolutionising the instruments of production, and thereby the relations of production, and with them the whole relations of society. Conservation of the old modes of production in unaltered form, was, on the contrary, the first condition of existence for all earlier industrial classes. Constant revolutionising of production, uninterrupted disturbance of all social conditions, everlasting uncertainty and agitation distinguish the bourgeois epoch from all earlier ones. All fixed, fast-frozen relations, with their train of ancient and venerable prejudices and opinions, are swept away, all new-formed ones become antiquated before they can ossify. All that is solid melts into air, all that is holy is profaned, and man is at last compelled to face with sober senses his real conditions of life, and his relations with his kind.

The need of a constantly expanding market for its products chases the bourgeoisie over the entire surface of the globe. It must nestle everywhere, settle everywhere, establish connexions everywhere.

The bourgeoisie has through its exploitation of the world market given a cosmopolitan character to production and consumption in every country. To the great chagrin of Reactionists, it has drawn from under the feet of industry the national ground on which it stood. All old-established national industries have been destroyed or are daily being destroyed. They are dislodged by new industries, whose introduction becomes a life and death question for all civilised nations, by industries that no longer work up indigenous raw material, but raw material drawn from the remotest zones; industries whose products are consumed, not only at home, but in every quarter of the globe. In place of the old wants, satisfied by the production of the country, we find new wants, requiring for their satisfaction the products of distant lands and climes. In place of the old local and national seclusion and self-sufficiency, we have intercourse in every direction, universal inter-dependence of nations. And as in material, so also in intellectual production. The intellectual creations of individual nations become common property. National one-sidedness and narrow-mindedness become more and more impossible, and from the numerous national and local literatures, there arises a world literature.

The bourgeoisie, by the rapid improvement of all instruments of production, by the immensely facilitated means of communication, draws all, even the most barbarian, nations into civilisation. The cheap prices of commodities are the heavy artillery with which it batters down all Chinese walls, with which it forces the barbarians’ intensely obstinate hatred of foreigners to capitulate. It compels all nations, on pain of extinction, to adopt the bourgeois mode of production; it compels them to introduce what it calls civilisation into their midst, i.e., to become bourgeois themselves. In one word, it creates a world after its own image.

The bourgeoisie has subjected the country to the rule of the towns. It has created enormous cities, has greatly increased the urban population as compared with the rural, and has thus rescued a considerable part of the population from the idiocy of rural life. Just as it has made the country dependent on the towns, so it has made barbarian and semi-barbarian countries dependent on the civilised ones, nations of peasants on nations of bourgeois, the East on the West.

The bourgeoisie keeps more and more doing away with the scattered state of the population, of the means of production, and of property. It has agglomerated population, centralised the means of production, and has concentrated property in a few hands. The necessary consequence of this was political centralisation. Independent, or but loosely connected provinces, with separate interests, laws, governments, and systems of taxation, became lumped together into one nation, with one government, one code of laws, one national class-interest, one frontier, and one customs-tariff.

The bourgeoisie, during its rule of scarce one hundred years, has created more massive and more colossal productive forces than have all preceding generations together. Subjection of Nature’s forces to man, machinery, application of chemistry to industry and agriculture, steam-navigation, railways, electric telegraphs, clearing of whole continents for cultivation, canalisation of rivers, whole populations conjured out of the ground — what earlier century had even a presentiment that such productive forces slumbered in the lap of social labour?

We see then: the means of production and of exchange, on whose foundation the bourgeoisie built itself up, were generated in feudal society. At a certain stage in the development of these means of production and of exchange, the conditions under which feudal society produced and exchanged, the feudal organisation of agriculture and manufacturing industry, in one word, the feudal relations of property became no longer compatible with the already developed productive forces; they became so many fetters. They had to be burst asunder; they were burst asunder.

Into their place stepped free competition, accompanied by a social and political constitution adapted in it, and the economic and political sway of the bourgeois class.

A similar movement is going on before our own eyes. Modern bourgeois society, with its relations of production, of exchange and of property, a society that has conjured up such gigantic means of production and of exchange, is like the sorcerer who is no longer able to control the powers of the nether world whom he has called up by his spells. For many a decade past the history of industry and commerce is but the history of the revolt of modern productive forces against modern conditions of production, against the property relations that are the conditions for the existence of the bourgeois and of its rule. It is enough to mention the commercial crises that by their periodical return put the existence of the entire bourgeois society on its trial, each time more threateningly. In these crises, a great part not only of the existing products, but also of the previously created productive forces, are periodically destroyed. In these crises, there breaks out an epidemic that, in all earlier epochs, would have seemed an absurdity — the epidemic of over-production. Society suddenly finds itself put back into a state of momentary barbarism; it appears as if a famine, a universal war of devastation, had cut off the supply of every means of subsistence; industry and commerce seem to be destroyed; and why? Because there is too much civilisation, too much means of subsistence, too much industry, too much commerce. The productive forces at the disposal of society no longer tend to further the development of the conditions of bourgeois property; on the contrary, they have become too powerful for these conditions, by which they are fettered, and so soon as they overcome these fetters, they bring disorder into the whole of bourgeois society, endanger the existence of bourgeois property. The conditions of bourgeois society are too narrow to comprise the wealth created by them. And how does the bourgeoisie get over these crises? On the one hand by enforced destruction of a mass of productive forces; on the other, by the conquest of new markets, and by the more thorough exploitation of the old ones. That is to say, by paving the way for more extensive and more destructive crises, and by diminishing the means whereby crises are prevented.

The weapons with which the bourgeoisie felled feudalism to the ground are now turned against the bourgeoisie itself.

But not only has the bourgeoisie forged the weapons that bring death to itself; it has also called into existence the men who are to wield those weapons — the modern working class — the proletarians.

In proportion as the bourgeoisie, i.e., capital, is developed, in the same proportion is the proletariat, the modern working class, developed — a class of labourers, who live only so long as they find work, and who find work only so long as their labour increases capital. These labourers, who must sell themselves piecemeal, are a commodity, like every other article of commerce, and are consequently exposed to all the vicissitudes of competition, to all the fluctuations of the market.

Owing to the extensive use of machinery, and to the division of labour, the work of the proletarians has lost all individual character, and, consequently, all charm for the workman. He becomes an appendage of the machine, and it is only the most simple, most monotonous, and most easily acquired knack, that is required of him. Hence, the cost of production of a workman is restricted, almost entirely, to the means of subsistence that he requires for maintenance, and for the propagation of his race. But the price of a commodity, and therefore also of labour, is equal to its cost of production. In proportion, therefore, as the repulsiveness of the work increases, the wage decreases. Nay more, in proportion as the use of machinery and division of labour increases, in the same proportion the burden of toil also increases, whether by prolongation of the working hours, by the increase of the work exacted in a given time or by increased speed of machinery, etc.

Modern Industry has converted the little workshop of the patriarchal master into the great factory of the industrial capitalist. Masses of labourers, crowded into the factory, are organised like soldiers. As privates of the industrial army they are placed under the command of a perfect hierarchy of officers and sergeants. Not only are they slaves of the bourgeois class, and of the bourgeois State; they are daily and hourly enslaved by the machine, by the overlooker, and, above all, by the individual bourgeois manufacturer himself. The more openly this despotism proclaims gain to be its end and aim, the more petty, the more hateful and the more embittering it is.

The less the skill and exertion of strength implied in manual labour, in other words, the more modern industry becomes developed, the more is the labour of men superseded by that of women. Differences of age and sex have no longer any distinctive social validity for the working class. All are instruments of labour, more or less expensive to use, according to their age and sex.

No sooner is the exploitation of the labourer by the manufacturer, so far, at an end, that he receives his wages in cash, than he is set upon by the other portions of the bourgeoisie, the landlord, the shopkeeper, the pawnbroker, etc.

The lower strata of the middle class — the small tradespeople, shopkeepers, and retired tradesmen generally, the handicraftsmen and peasants — all these sink gradually into the proletariat, partly because their diminutive capital does not suffice for the scale on which Modern Industry is carried on, and is swamped in the competition with the large capitalists, partly because their specialised skill is rendered worthless by new methods of production. Thus the proletariat is recruited from all classes of the population.

:thinking:

 

[Lap3che]

2

3


Soleil

 

[Kitsu]

eeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeeee

salut a tous les amis c est David Lafarge pokemon je suis avec miss jirachi
https://image.noelshack.com/fichiers/2018/34/6/1535208880-index.jpg

 

[Mika Deagle]

3


Soleil

4

 

[ZarosOVH]

4

5

 

[Lap3che]

5

6 cueillir des saucisses

 

[ZarosOVH]

6 cueillir des saucisses

7, 8, 9 je mange un œuf

 

[ZarosOVH]

za

ros

 

[EglyKozz]

Le Soleil est l’étoile du Système solaire. Dans la classification astronomique, c’est une étoile de type naine jaune d'une masse d'environ 1,9891 × 1030 kg, composée d’hydrogène(75 % de la masse ou 92 % du volume) et d’hélium (25 % de la masse ou 8 % du volume)9. Le Soleil fait partie de la galaxie appelée la Voie lactée et se situe à environ 8 kpc(∼26 100 a.l.) du centre galactique. Le Soleil orbite autour du centre galactique en 225 à 250 millions d'années (année galactique). Autour de lui gravitent la Terre (à la vitesse de 30 km/s), sept autres planètes, au moins cinq planètes naines, de très nombreux astéroïdes et comètes et une bande de poussière. Le Soleil représente à lui seul environ 99,854 % de la masse du Système solaire ainsi constitué, Jupiter représentant plus des deux tiers du reste.
L’énergie solaire transmise par le rayonnement solaire rend possible la vie sur Terre par apport d'énergie lumineuse (lumière) et d'énergie thermique (chaleur), permettant la présence d’eau à l’état liquide et la photosynthèse des végétaux. Les UV solaires contribuent à la désinfection naturelle des eaux de surfaces et à y détruire certaines molécules indésirables (quand l'eau n'est pas trop turbide)10. La polarisation naturelle de la lumière solaire (y compris de nuit après diffusion ou réflexion, par la Lune) ou par des matériaux tels que l’eau ou les cuticules végétales est utilisée par de nombreuses espèces pour s’orienter.
Le rayonnement solaire est aussi responsable des climats et de la plupart des phénomènes météorologiques observés sur la Terre. En effet, le bilan radiatif global de la Terre est tel que la densité thermique à la surface de la Terre est en moyenne à 99,97 % ou 99,98 % d’origine solairenote 1. Comme pour tous les autres corps, ces flux thermiques sont continuellement émis dans l’espace, sous forme de rayonnement thermique infrarouge ; la Terre restant ainsi en « équilibre dynamique ».
Le demi-grand axe de l’orbite de la Terre autour du Soleil, couramment appelé « distance de la Terre au Soleil », égal à 149 597 870 700 m ± 3 m1, est la définition originale de l’unité astronomique (ua). Il faut 8 minutes et 19 secondes pour que la lumière du Soleil parvienne jusqu’à la Terre11.
Le symbole astronomique et astrologique du Soleil est un cercle avec un point en son centre : {\displaystyle \odot }. Il était anciennement stylisé en

Caractéristiques générales
Le Soleil tel que vu dans l’ultraviolet « lointain » (UVC)
(image en « fausses couleurs »).
La chromosphère et les protubérances sont les sources essentielles, bien plus chaudes que « la surface » (la photosphère).
Le Soleil est une étoile naine jaune qui se compose de 74 % d’hydrogène, de 24 % d’hélium et d’une fraction d’éléments plus lourds. Le Soleil est de type spectral G2–V. « G2 » signifie qu’il est plus chaud (5 770 kelvins en surface environ) et plus brillant que la moyenne, avec une couleur jaune tirant sur le blanc. Son spectre renferme des bandes de métaux ionisés et neutres, ainsi que de faibles bandes d’hydrogène. Le suffixe « V » (ou « classe de luminosité ») indique qu’il évolue actuellement, comme la majorité des étoiles, sur la séquence principale du diagramme de Hertzsprung-Russell : il tire son énergie de réactions de fusion nucléaire qui transforment, dans son noyau, l’hydrogène en hélium, et se trouve dans un état d’équilibre hydrostatique, ne subissant ni contraction, ni dilatation continuelles.
Il existe dans la Voie lactée plus de 100 millions d’étoiles de type spectral identique, ce qui fait du Soleil une étoile assez ordinaire, bien qu’il soit en fait plus brillant que 85 % des étoiles de la Galaxie, qui sont en majorité des naines rouges16.
Le Soleil gravite autour du centre de la Voie lactée dont il est distant d’environ 25 000 à 28 000 années-lumière. Sa période de révolution galactique est d’environ 220 millions d’années, et sa vitesse de 217 km s−1, équivalente à une année-lumière tous les 1 400 ans (environ), et une unité astronomique tous les 8 jours17.
Dans cette révolution galactique, le Soleil, comme les autres étoiles du disque, a un mouvement oscillant autour du plan galactique : l’orbite galactique solaire présente des ondulations sinusoïdales perpendiculaires à son plan de révolution. Le Soleil traverserait ce plan tous les 30 millions d’années environ, d’un côté puis de l’autre — sens Nord-Sud galactique, puis inversement — et s’en éloignerait au maximum de 230 années-lumière environ, tout en restant dans le disque galactique. La masse du disque galactique attire les étoiles qui auraient un plan de révolution différent de celui du disque galactiquenote 2.
Actuellement, le Système solaire se situerait à 48 années-lumière au-dessus (au nord) du plan galactique et en phase ascendante à la vitesse de 7 km/s18.
Le Soleil tourne également sur lui-même, avec une période de 27 jours terrestres environ. En réalité, n’étant pas un objet solide, il subit une rotation différentielle : il tourne plus rapidement à l’équateur (25 jours) qu’aux pôles(35 jours). Déduite des modes de vibration de gravité, la vitesse de rotation du cœur a pu aussi être déterminée : un tour par semaine environ, soit 3,8 fois plus vite que les couches extérieures et intermédiaires19,20.
Le Soleil est également en rotation autour du barycentre du Système solaire, ce dernier pouvant se situer à un peu plus d’un rayon solaire du centre de l’étoile (hors de sa surface)21, en raison de la masse de Jupiter (environ un millième de la masse solaire).

Formation
Le Soleil est une étoile âgée d'environ 4,57 milliards d’années24, soit un peu moins de la moitié de son chemin sur la séquence principale25. L'hypothèse des années 1970, qu'une supernova serait à l'origine de l'effondrement de la nébuleuse qui a donné naissance au Soleil, n'est plus crédible. Une modélisation récente (2012) propose un scénario en trois étapes pour expliquer la formation du Soleil et l'abondance de magnésium 26 et de nickel 60 dans les météorites. Ces éléments sont les produits de la décomposition de deux isotopes radioactifs (à la demi-vie relativement courte), nés dans les étoiles : l'aluminium 26 (demi-vie de 717 000 ans) et le fer 60 (demi-vie de 2,6 Ma). Pour comprendre la présence de ces éléments dans la chimie du Soleil, il fallait imaginer une étape pour le fer 60 et une autre pour l'aluminium 26.
Scénario : Il y a 4,6 Ga, une nébuleuse s'effondre et une première génération d'étoiles (± 5 000) naît. Après 5 Ma, les plus massives meurent en supernovas et dispersent leurs éléments, dont l'isotope fer 60. Après 2 Ma, un nuage riche en fer 60 s'effondre et de nouvelles étoiles se forment. Cette seconde génération comprend des étoiles très massives (plus de 30 masses solaires) qui éjectent des vents chargés en aluminium 26. Après 100 000 ans, le vent d'une de ces étoiles très massives comprime la matière qui l'entoure. Il se forme une coquille de gaz et de poussières riches en fer 60 et en aluminium 26, qui finit par s'effondrer et donner naissance, il y a 4,5682 Ga, à une troisième génération d'étoiles : le Soleil et une centaine d'étoiles jumelles. Quelques millions d'années plus tard, l'étoile très massive à l'origine du processus meurt en supernova. On l'appelle Coatlicue qui signifie « mère du Soleil » dans la cosmogonie aztèque. Les sœurs du Soleil (à la composition chimique identique) se dispersent dans la Voie lactée. Le Soleil reste seul ; les astéroïdes qui l'entourent gardent la trace de sa généalogie sous la forme des dérivés du fer 60 et de l'aluminium 26 : le nickel 60 et le magnésium 2626.
Évolution
Actuellement, dans le cœur du Soleil, chaque seconde, environ 627 millions de tonnes d'hydrogène fusionnent27 pour produire environ 622,7 millions de tonnes d'hélium. La différence de masse de 4,3 millions de tonnes (une masse de l'ordre de celle de la pyramide de Gizeh28) équivaut à l'énergie lumineuse produite (4 × 1026 joules). Cette énergie migre lentement, par rayonnement et par convection, vers la surface solaire et est émise dans l’espace sous forme de rayonnement électromagnétique (lumière, rayonnement solaire) et de flux de particules (vent solaire).
Évolution de la luminosité, du rayon et de la température solaires, comparés aux valeurs actuelles du Soleil. D'après Ribas (2010)29.
Le Soleil est dans sa phase linéaire, durant laquelle le Soleil épuise petit à petit ses réserves d’hydrogène, sa luminosité augmentant d’environ 7 % par milliard d’années, à la suite de l’augmentation du rythme des réactions de fusion par la lente contraction du cœur. Cette phase linéaire a débuté quand le Soleil était âgé d'environ 500 millionsd'années, et durera jusqu'à la rupture de l'équilibre hydrostatique. Le Soleil était donc moins brillant dans le passé et sera plus brillant dans le futur.
Évolution d'une étoile de type solaire. Le parcours d'une étoile d'une masse solaire sur le diagramme Hertzsprung-Russell est indiqué depuis la séquence principale jusqu'au-delà du stade de la branche asymptotique des géantes.
Lorsqu’il sera âgé de 10,5 milliards d’années, l’équilibre hydrostatique sera rompu. Le Soleil aura converti tout l'hydrogène de son cœur en hélium. Le noyau d'hélium se contractera et s’échauffera fortement, tandis qu’une couronne externe du cœur fusionnera l’hydrogène en hélium. Ses couches superficielles, dilatées par le flux thermique croissant et ainsi partiellement libérées de l’effet gravitationnel, seront progressivement repoussées : le Soleil se dilatera, d'abord lentement sur 500 millions d'années, puis plus rapidement sur 500 millions d'années supplémentaires, pour finalement se transformer en géante rouge. Au terme de ce processus, le Soleil aura un diamètre environ 100 fois supérieur à l’actuel, et sera près de 2 000 fois plus lumineux. Sa photosphère dépassera l’orbite de Mercure et de Vénus. La Terre, si elle subsiste encore, ne sera plus qu’un désert calciné. Cette phase de géante rouge durera environ 1 milliard d'années, le Soleil y perdra environ un tiers de sa masse.
À la fin de sa phase de géante rouge, son cœur d'hélium sera en état dégénéré, sa température, augmentant par contraction de l'hélium produit par la couronne externe du cœur, arrivera aux environs de 100 millions de kelvins, initiant les réactions de fusion de l’hélium pour donner du carbone (voir réaction triple-alpha) ainsi que de l'oxygène. Cette ignition de l'hélium sera brutale : ce sera le flash de l’hélium, suivi d'un réarrangement des couches du Soleil faisant diminuer son diamètre jusqu’à ce qu’il se stabilise à une taille de plusieurs fois (jusqu’à 10 fois) sa taille actuelle, soit d’environ 10 millions de kilomètres de diamètre. Il sera devenu une sous-géante, avec environ 50 fois sa luminosité actuelle.
La période de fusion de l'hélium durera environ 100 millions d'années, les noyaux d'hélium se combineront trois par trois pour former des noyaux de carbone, qui peupleront le cœur de la géante rouge, avec production d'un peu d'oxygène par ajout d'un noyau d'hélium supplémentaire au carbone. Durant cette phase, le Soleil deviendra de nouveau plus grand et plus lumineux.
Enfin, lorsque l'hélium au centre du cœur sera entièrement transformé en carbone et en oxygène, il va redevenir une géante rouge, ce sera la phase de la branche asymptotique des géantes, qui durera approximativement 20 millions d'années. Dans cette phase, 2 couronnes de fusion auront lieu en son cœur : une externe fusionnant l'hydrogène, une interne fusionnant l'hélium. Dans cette configuration, le Soleil sera très instable : les couronnes de fusion variant alternativement de puissance. Cela produira de puissants pulses qui finiront par souffler les couches externes. Le Soleil aura perdu environ la moitié de sa masse.
Le Soleil ne sera plus assez massif pour comprimer assez son cœur de carbone et atteindre la température de 600 millions de K nécessaire à la fusion du carbone, produisant du néon, du sodium et du magnésium30.
La matière des couches externes sera répandue dans l’espace et donnera naissance à une nébuleuse planétaire. La nébuleuse planétaire sera un nuage de gaz très chaud (plus de 10 000 K) composé essentiellement de l'hydrogène et de l'hélium non consommés dans les fusions, et d'un peu de carbone. Elle servira de berceau à de nouvelles étoiles. Le cœur de carbone, n'ayant plus de carburant pour fournir l'énergie nécessaire pour contrecarrer la gravité, va s'effondrer sur lui-même et former une naine blanche, d’une taille comparable à celle de la Terre. La densité y sera si élevée que le cœur abritera de la matière électronique dégénérée. La température en surface de la naine blanche atteindra 50 000 K (chaleur emmagasinée lors de l'effondrement du cœur). Cette chaleur sera émise par un rayonnement de couleur blanche. La surface radiative étant extrêmement faible, la naine blanche mettra plusieurs milliards d'années à se refroidir. Quand la température sera assez basse, le rayonnement thermique sera si faible que la naine blanche sera invisible. Elle terminera sa vie en naine noire, un cadavre céleste si froid qu'il n'émet plus aucune lumière.
Ce scénario est caractéristique des étoiles de faible à moyenne masse31,32 ; de ~0,5 à ~4 M{\displaystyle \odot }

.
Cycle de vie du Soleil, il est similaire à celui d’une naine jaune. Diagramme trop court de 2 milliards d’années, il y manque aussi la « courte » phase de sous-géante.
Structure et fonctionnement
Structure du Soleil en coupe.
Bien que le Soleil soit une étoile de taille moyenne, il représente à lui seul environ 99,854 % de la masse du Système solaire. Sa forme est presque parfaitement sphérique, avec un aplatissement aux pôles estimé à neuf millionièmes33, ce qui signifie que son diamètre polaire est plus petit que son diamètre équatorial de seulement dix kilomètres.
Contrairement aux objets telluriques, le Soleil n'a pas de limite extérieure bien définie. La densité de ses gaz chute de manière à peu près exponentielle à mesure que l'on s'éloigne de son centre. Par contre, sa structure interne est bien définie.
Le rayon du Soleil est mesuré de son centre jusqu'à la photosphère. La photosphère est la couche en dessous de laquelle les gaz sont assez condensés pour être opaques et au-delà de laquelle ils deviennent transparents. La photosphère est ainsi la couche la plus visible à l'œil nu. La majeure partie de la masse solaire se concentre à 0,7 rayon du centre.
La structure interne du Soleil n'est pas observable directement. De la même façon que la sismologie permet, par l’étude des ondes produites par les tremblements de terre, de déterminer la structure interne de la Terre, on utilise l'héliosismologie pour mesurer et visualiser indirectement la structure interne du Soleil. La simulation informatique est également utilisée comme outil théorique pour sonder les couches les plus profondes.
Noyau
Article détaillé : Noyau solaire.
On considère que le noyau (ou cœur) du Soleil s’étend du centre à environ 0,25 rayon solaire. Sa masse volumique est supérieure à 150 000 kg m−3 (150 fois la masse volumique de l’eau) et sa température approche les 15 millionsde kelvins (ce qui contraste nettement avec la température de surface du Soleil, qui avoisine les 5 800 kelvins). C’est dans le cœur que se produisent les réactions thermonucléaires exothermiques (fusion nucléaire) qui transforment, dans le cas du Soleil, l’hydrogène en hélium (voir, pour les détails de ces réactions, l’article chaîne proton-proton).
Le Soleil tire son énergie des réactions de fusion nucléaire qui transforment, en son noyau, l’hydrogène en hélium.
Environ 3,4 × 1038 protons (noyaux d’hydrogène), soit 619 millions de tonnes d'hydrogène, sont convertis en 614 millions de tonnes d'hélium chaque seconde, libérant une énergie correspondant à l'annihilation de 4,26 millions de tonnes de matière par seconde, produisant 383 yottajoules (383 × 1024 J) par seconde, soit l’équivalent de l’explosion de 91,5 × 1015 tonnes de TNT34,35.
Le taux de fusion nucléaire est proportionnel à la densité du noyau, aussi la fusion nucléaire au sein du cœur est un processus auto-régulé : toute légère augmentation du taux de fusion provoque un réchauffement et une dilatation du cœur qui réduit en retour le taux de fusion. Inversement, toute diminution légère du taux de fusion refroidit et densifie le cœur, ce qui fait revenir le niveau de fusion à son point de départ.
Aucune chaleur n'étant produite en dehors du cœur, toute la chaleur du reste de l’étoile en provient, l'énergie traversant de nombreuses couches jusqu’à la photosphère, avant de s’échapper dans l’espace sous forme de rayonnement solaire ou de flux de particules.
L'énergie des photons de haute énergie (rayons X et gamma) libérés lors des réactions de fusion met un temps considérable pour traverser les zones de rayonnement et de convection avant d'atteindre la surface du Soleil. On estime que le temps de transit du cœur à la surface se situe entre 10 000 et 170 000 ans36. Après avoir traversé la couche de convection et atteint la photosphère, les photons s’échappent dans l’espace, en grande partie sous forme de lumière. Chaque rayon gamma produit au centre du Soleil est finalement transformé en plusieurs millions de photons lumineux qui s’échappent dans l’espace. Des neutrinos sont également libérés par les réactions de fusion, mais contrairement aux photons ils interagissent peu avec la matière et sont donc libérés immédiatement. Pendant des années, le nombre de neutrinos produits par le Soleil était mesuré plus faible d’un tiers que la valeur théorique : c’était le problème des neutrinos solaires, qui a été résolu en 1998 grâce à une meilleure compréhension du phénomène d’oscillation du neutrino.
Zone radiative
La zone de rayonnement ou zone radiative se situe approximativement entre 0,25 et 0,7 rayon solaire. La matière solaire y est si chaude et si dense que le transfert de la chaleur du centre vers les couches les plus extérieures se fait par le seul rayonnement thermique. L’hydrogène et l’hélium ionisés émettent des photons qui voyagent sur une courte distance avant d’être réabsorbés par d’autres ions. Les photons de haute énergie (rayons X et gamma) libérés lors des réactions de fusion mettent un temps considérable pour atteindre la surface du Soleil, ralentis par l’interaction avec la matière et par le phénomène permanent d’absorption et de réémission à plus basse énergie dans le manteau solaire. On estime que le temps de transit de l'énergie d’un photon du cœur à la surface se situe entre 10 000 et 170 000 ans36. Dans cette zone, il n’y a pas de convection thermique car bien que la matière se refroidisse en s’éloignant du cœur, le gradient thermique reste inférieur au gradient thermique adiabatique. La température y diminue à 2 millions de kelvins.
Zone convective
Article détaillé : Zone de convection.
La zone de convection ou zone convective s’étend de 0,8 rayon solaire du centre à la surface visible du Soleil. Elle est séparée de la zone radiative par une couche épaisse d’environ 3 000 kilomètres, la tachocline, qui d’après les études récentes pourrait être le siège de puissants champs magnétiques et jouerait un rôle important dans la dynamo solaire. Dans la zone de convection la matière n’est plus ni assez dense ni assez chaude pour évacuer la chaleur par rayonnement : c’est donc par convection, selon un mouvement vertical, que la chaleur est conduite vers la photosphère. La température y passe de 2 millions à ~5 800 kelvins. La matière parvenue en surface, refroidie, plonge à nouveau jusqu’à la base de la zone de convection pour recevoir la chaleur de la partie supérieure de la zone de rayonnement, etc. Les gigantesques cellules de convection ainsi formées sont responsables des granulations solairesobservables à la surface de l’astre. Les turbulences survenant dans cette zone produisent un effet dynamo responsable de la polarité magnétique nord-sud à la surface du Soleil.
Photosphère
La photosphère vue à travers un filtre.
La photosphère est une partie externe de l’étoile qui produit entre autres la lumière visible. Elle est plus ou moins étendue : de moins de 0,1 % du rayon pour les étoiles naines, soit quelques centaines de kilomètres ; à quelques dizaines de pourcent du rayon de l’étoile pour les plus géantes, ce qui leur donnerait un contour flou contrairement au Soleil aux bords nets.
La lumière qui y est produite contient toutes les informations sur la température, la gravité de surface et la composition chimique de l’étoile. Pour le Soleil, la photosphère a une épaisseur d’environ 400 kilomètres. Sa température moyenne est de 6 000 K. Elle permet de définir la température effective qui pour le Soleil est de 5 781 K. Sur l’image de la photosphère solaire on peut voir l’assombrissement centre-bord qui est une des caractéristiques de la photosphère. L’analyse du spectre de la photosphère solaire est très riche en information en particulier sur la composition chimique du Soleil. La photosphère est maculée d'une granulation qui lui donne l'aspect d'une peau d'orange. Ce sont des sphères d'environ 1 000 km de diamètre, composées de gaz chaud remontant vers la surface à près de 500 mètres par seconde, qui lui donnent cet aspect. La surface atteinte, elles irradient leur énergie et, une fois refroidies, replongent dans l'étoile. Chaque sphère de granulation dure huit minutes en moyenne.

Atmosphère
La structure du Soleil au-delà de la photosphère est généralement connue sous le nom d’atmosphère solaire. Elle comprend trois zones principales : la chromosphère, la couronne et l’héliosphère. La chromosphère est séparée de la photosphère par la zone de température minimum et de la couronne par une zone de transition. L’héliosphère s’étend jusqu’aux confins du Système solaire où elle est limitée par l’héliopause. Pour une raison encore mal élucidée, la chromosphère et la couronne sont plus chaudes que la surface du Soleil. Bien qu’elle puisse être étudiée en détail par les télescopes spectroscopiques, l’atmosphère solaire n’est jamais aussi accessible que lors des éclipses totales de Soleil.
Chromosphère
La chromosphère vue en analyse spectrale Hα.
Les éclipses totales de Soleil (ici celle du 11 août 1999) sont la seule occasion de visualiser directement la couronne (en blanc) et la chromosphère (en rose).
La zone de température minimum qui sépare la photosphère de la chromosphère offre une température suffisamment basse (~4 000 kelvins) pour qu’on y trouve des molécules simples (monoxyde de carbone, eau), détectables par leur spectre d’absorption. La chromosphère proprement dite est épaisse d’environ 2 000 kilomètres. Sa température augmente graduellement avec l’altitude, pour atteindre un maximum de 100 000 kelvins à son sommet. Son spectre est dominé par des bandes d’émission et d’absorption. Son nom, qui vient de la racine grecque chroma (couleur), lui a été donné en raison du flash rose soutenu qu’elle laisse entrevoir lors des éclipses totales de Soleil.
Couronne
La zone de transition entre la chromosphère et la couronne est le siège d’une élévation rapide de température, qui peut approcher 1 million de kelvins. Cette élévation est liée à une transition de phase au cours de laquelle l’hélium devient totalement ionisé sous l’effet des très hautes températures. La zone de transition n’a pas une altitude clairement définie. Grossièrement, elle forme un halo surplombant la chromosphère sous l’apparence de spicules et de filaments. Elle est le siège d’un mouvement chaotique et permanent. Difficile à percevoir depuis la Terre malgré l’utilisation de coronographes, elle est plus aisément analysée par les instruments spatiaux sensibles aux rayonnements ultraviolets extrêmes du spectre.
La couronne solaire est composée à 73 % d’hydrogène et à 25 % d’hélium. Les températures sont de l’ordre du million de degrés.
Bien plus vaste que le Soleil lui-même, la couronne solaire elle-même s’étend à partir de la zone de transition et s’évanouit progressivement dans l’espace, mêlée à l’héliosphère par les vents solaires. La couronne inférieure, la plus proche de la surface du Soleil, a une densité particulaire comprise entre 1 × 1014 m−3 et 1 × 1016 m−3, soit moins d’un milliardième de la densité particulaire de l’atmosphère terrestre au niveau de la mer. Sa température, qui peut atteindre les 5 millions de kelvins, contraste nettement avec la température de la photosphère. Bien qu’aucune théorie n’explique encore complètement cette différence, une partie de cette chaleur pourrait provenir d’un processus de reconnexion magnétique.

Missions spatiales solaires
Vue d’artiste du satellite SolarMax.
Il observa la couronne solaire et les taches solaires de 1984 à 1989.
Les premières sondes conçues pour observer le Soleil depuis l’espace interplanétaire furent lancées par la NASA entre 1959 et 1968 : ce furent les missions Pioneer 5, 6, 7, 8 et 9. En orbite autour du Soleil à une distance similaire à celle de l’orbite terrestre, elles permirent les premières analyses détaillées du vent solaire et du champ magnétique solaire. Pioneer 9 resta opérationnelle particulièrement longtemps et envoya des informations jusqu’en 198752.
Dans les années 1970, deux missions apportèrent aux scientifiques des informations capitales sur le vent solaire et la couronne solaire. La sonde germano-américaine Helios 1 étudia le vent solaire depuis la périhélie d’une orbite plus petite que celle de Mercure. La station américaine Skylab, lancée en 1973, comportait un module d’observation solaire baptisé Apollo Telescope Mount et commandé par les spationautes embarqués dans la station. Skylab fit les premières observations de la zone de transition entre la chromosphère et la couronne et des émissions ultraviolettes de la couronne solaire. La mission permit également les premières observations d’éjections de masse coronale et de trous coronaux, phénomènes dont on sait aujourd’hui qu’ils sont intimement liés au vent solaire.
En 1980 la NASA lança le satellite Solar Maximum Mission (plus connu sous le nom de SolarMax), conçu pour l’observation des rayons gamma, X et ultraviolets émis par les éruptions solairesdans les périodes de forte activité solaire. Malheureusement quelques mois après son lancement, un dysfonctionnement électronique plaça le satellite en mode standby, et l’appareil resta inactif les trois années suivantes. En 1984 toutefois, la mission STS-41-C du programme Space Shuttle Challenger intercepta le satellite et permit une réparation et un relancement. SolarMaxput alors réaliser des milliers d’observations de la couronne solaire et des taches solaires jusqu’à sa destruction en juin 198953.
Le satellite japonais Yohkoh (Rayon de Soleil), lancé en 1991, observa les éruptions solaires aux longueurs d’onde des rayons X. Les données rapportées par la mission permirent aux scientifiques d’identifier différents types d’éruptions, et démontra que la couronne au-delà des régions de pics d’activité était bien plus dynamique et active qu’on l’avait supposé auparavant. Yohkoh suivit un cycle solaire entier mais tomba en panne à la suite d’une éclipse annulaire de Soleil le 14 décembre 2001. Il fut détruit en rentrant dans l’atmosphère en 200554.
Une des plus importantes missions solaires à ce jour est la Solar and Heliospheric Observatory ou SoHO, lancée conjointement par l’Agence spatiale européenne et la NASA le 2 décembre 1995. Prévue au départ pour deux ans, la mission SoHO est toujours active. Elle s’est avérée si performante qu’une mission de prolongement baptisée Solar Dynamics Observatory est envisagée pour 2008. Localisée au point de Lagrange entre la Terre et le Soleil (auquel la force d’attraction de ces deux corps célestes est égale), SoHO envoie en permanence des images du Soleil à différentes longueurs d’onde. En plus de cette observation directe du Soleil, SoHO a permis la découverte d’un grand nombre de comètes, principalement de très petites comètes effleurant le Soleil et détruites lors de leur passage, les comètes rasantes55.
Toutes les observations enregistrées par ces satellites sont prises depuis le plan de l’écliptique. En conséquence, ils n’ont pu observer en détail que les seules régions équatoriales du Soleil. En 1990 cependant la sonde Ulysses a été lancée pour étudier les régions polaires du Soleil. Elle fit d’abord route vers Jupiter et utilisa son assistance gravitationnelle pour se séparer du plan de l’écliptique. Par chance elle fut idéalement placée pour observer, en juillet 1994, la collision entre la comète Shoemaker-Levy 9 et Jupiter. Une fois sur l’orbite prévue, Ulysses étudia le vent solaire et la force du champ magnétique à des latitudes solaires élevées, découvrant que le vent solaire aux pôles était plus lent que prévu (750 km s−1 environ) et que d’importantes ondes magnétiques en émergeaient, participant à la dispersion des rayons cosmiques56.
La mission Genesis fut lancée par la NASA en 2001 dans le but de capturer des parcelles de vent solaire afin d’obtenir une mesure directe de la composition de la matière solaire. Elle fut sévèrement endommagée lors de son retour sur Terre, le 10 septembre 2004, mais une partie des prélèvements a pu être sauvée et est actuellement en cours d’analyse.
La mission STEREO (Solar TErrestrial RElation Observatories) lancée le 25 octobre 2005 par la NASA a permis pour la première fois l’observation tridimensionnelle du Soleil depuis l’espace. Composée de deux satellites quasiment identiques, cette mission doit permettre une meilleure compréhension des relations Soleil-Terre, en particulier en permettant l’observation des CME (Éjections de Masse Coronale) jusqu’à l’environnement électromagnétique terrestre.
La sonde Parker lancée le 12 août 2018 vise à étudier la couronne solaire, partie extérieure de l'atmosphère du Soleil qui s'étend jusqu'à plusieurs millions de kilomètres de l'astre.

.

 

[Lap3che]

7, 8, 9 je mange un œuf

10
11
12

Go faire une part...


ie de Monopoly

 

[Malcolm]

10
11
12


Go faire une part...




ie de Monopoly

Mais du coup ça rime pas