to the rails, are now generally admitted to be Limicoline, while on this occasion William Jessop, of the Butterley Iron Works, minus the width of two of his rails. RAILWAYS. Railways had their origin in the tramways (q.v.) or wagon-ways which at least as early as the middle of the 16th century were used in the mineral districts of England round Newcastle for the conveyance of coal from the pits to the river Tyne for shipment. It may be supposed that originally the public roads, when worn by the cartage of the coal, were repaired by laying planks of timber at the bottom of the ruts, and that then the planks were laid on the surface of special roads or ways1 formed between the collieries and the river. "The manner of the carriage," says Lord Keeper North in 1676, is by laying rails of timber... exactly straight and parallel, and bulky carts are made with four rowlets fitting these rails, whereby the, carriage is so easy that one horse will draw down four or five chaldrons of coals " (from 10-6 to 13.2 tons). The planks were of wood, often beech, a few inches wide, and were fastened down, end to end, on logs of wood, or sleepers," placed crosswise at intervals of two or three feet. In time it became a common practice to cover them with a thin sheathing or plating of iron, in order to add to their life; this These two systems of constructing railwaysexpedient caused more wear on the wooden rollers of the wagons, the plate-rail and the edge-rail-continued to and, apparently towards the middle of the 18th century, led to exist side by side until well on in the 19th century. the introduction of iron wheels, the use of which is recorded on In most parts of England the plate-rail was preferred, a wooden railway near Bath in 1734. But the iron sheathing and it was used on the Surrey iron railway, from was not strong enough to resist buckling under the passage of the Wandsworth to Croydon, which, sanctioned by loaded wagons, and to remedy this defect the plan was tried of parliament in 1801, was finished in 1803, and was making the rails wholly of iron. In 1767 the Colebrookdale the first railway available to the public on payment Iron Works cast a batch of iron rails or plates, each 3 ft. long of tolls, previous lines having all been private and and 4 in. broad, having at the inner side an upright ledge or reserved exclusively for the use of their owners. FIG. 2.flange, 3 in. high at the centre and tapering to a height of In South Wales again, where in 1811 the railways in 2 in. at the ends, for the purpose of keeping the flat wheels connexion with canals, collieries and iron and copper on the track. Subsequently, to increase the strength, a similar works had a total length of nearly 150 miles, the flange was added below the rail. Wooden sleepers continued plate-way was almost universal. But in the north of England to be used, the rails being secured by spikes passing through and in Scotland the edge-rail was held in greater favour, the extremities, but about 1793 stone blocks also began to be and by the third decade of the century its superiority was employed-an innovation associated with the name of Ben- generally established. The manufacture of the rails themjamin Outram, who, however, apparently was not actually selves was gradually improved. By making them in longer the first to make it. This type of rail (fig. 1) was lengths a reduction was effected in the number of jointsknown as the plate-rail, tramway-plate or barrow- always the weakest part of the line; and another advance way-plate-names which are preserved in the consisted in the substitution of wrought iron for cast iron, modern term "platelayer" applied to the men though that material did not gain wide adoption until who lay and maintain the permanent way of a after the patent for an improved method of rolling rails railway. granted in 1820 to John Birkinshaw, of the Bedlington Another form of rail, distinguished as the edge- Ironworks, Durham. His rails were wedge-shaped in section,' rail, was first used on a line which was opened much wider at the top than at the bottom, with the interbetween Loughborough and Nanpantan in 1789.mediate portion or web thinner still, and he recommended This line was originally designed as a "plate that they should be made 18 ft. long, even suggesting that on the Outram system, but objections were several of them might be welded together end to end to form raised to rails with upstanding ledges or flanges considerable lengths. They were supported on sleepers by FIG. 1. being laid on the turnpike road which was crossed chairs at intervals of 3 ft., and were fish-bellied between at Loughborough on the level. In other cases the points of support. As used by George Stephenson on the this difficulty was overcome by paving or cause- Stockton & Darlington and Whitstable & Canterbury lines waying" the road up to the level of the top of the flanges, but they weighed 28 lb per yard. On the Liverpool & Man"Another thing that is remarkable is their way-leaves; for, chester railway they were usually 12 ft. or 15 ft. long and when men have pieces of ground between the colliery and the weighed 35 lb to the yard, and they were fastened by iron river, they sell leave to lead coals over their ground" (Roger North). wedges to chairs weighing 15 or 17 lb each. The chairs were Plate Rail. way 46 Edge- in turn fixed to the sleepers by two iron spikes, half-round | century and had come into considerable use in connexion with wooden cross sleepers being employed on embankments and collieries and quarries before it was realized that for the carriage stone blocks 20 in. square by 10 in. deep in cuttings. The fishbellied rails, however, were found to break near the chairs, and from 1834 they began to be replaced with parallel rails weighing 50 lb to the yard. The next important development in rail design originated in America, which, for the few lines that had been laid up to 1830, remained content with wooden bars faced with iron. In that year Robert Livingston Stevens (1787-1856), devised for the Camden & Amboy railway a rail similar as to its top to those in use in England, but having a flat base or foot by which it was secured to the sleepers by hook-headed spikes, without chairs (fig. 3); he had to get the first lot of these rails, which were 15 ft. long and weighed 36 fb to the yard, manufactured in England, since there were then no mills in America able to roll them. This type, which is often known as the Vignoles rail, after Charles Blacker Vignoles (1793-1875), who re-invented it in England in 1836, is in general use in America and on the continent of Europe. The bridge-rail (fig. 4)-so called because it was first laid on bridges-was supported on continuous longitudinal sleepers and held down by bolts passing through the flanges, and was employed by I. K. Brunel on the Great Western railway, where, however, it was abandoned after the line was converted from broad to standard gauge in 1892. In the double-headed rail (fig. 5), originated by Joseph Locke in 1837, and first laid on the Grand Junction railway, the two tables were equal. This rail was more easily rolled than others, and, being reversible, was in fact two rails in one. But as it was laid in cast-iron chairs the lower table was exposed to damage under the hammering of the traffic, and thus was liable to be rendered useless as a running surface. In consequence the bull-headed rail (fig. 6) was evolved, in which the lower table was made of smaller size and was intended merely as a support, not as a surface to be used by the wheels. There was a waste of metal in these early rails owing to the excessive thickness of the vertical web, and subsequent improvements have consisted in adjusting the dimensions so as to combine strength with economy of metal, as well as in the substitution of steel for wrought iron (after the introduction of the Bessemer process) and in minute attention to the composition of the steel employed. FIG. 7.-The original Fish-Joint of W. Bridges Adams. .of general merchandise it might prove a serious competitor to the canals, of which a large mileage had been constructed in Great Britain during that period. In the article on "Railways" in the Supplement to the Encyclopaedia Britannica, published in 1824, it is said: "It will appear that this species of inland carriage [railways] is principally applicable where trade is considerable and the length of conveyance short; and is chiefly useful, therefore, in transporting the mineral produce of the kingdom from the mines to the nearest land or water communication, whether sea, river or canal. Attempts have been made to bring it into more general use, but without success; and it is only in particular circumstances that navigation, with the aid either of locks or inclined planes to surmount the elevations, will not present a more convenient medium for an extended trade." It must be remembered, however, that at this time the railways were nearly all worked by horse-traction, and that the use of steam had made but little progress. Richard Trevithick, indeed, had in 1804 tried a high-pressure steam locomotive, with smooth wheels, on a plate-way near Merthyr Tydvil, but it was found more expensive than horses; John Blenkinsop in 1811 patented an engine with cogged wheel and rack-rail which was used, with commercial success, to convey coal from his Middleton colliery to Leeds; William Hedley in 1813 built two locomotives-Puffing Billy and Wylam Dilly-for hauling coal from Wylam Colliery, near Newcastle; and in the following year George Stephenson's first engine, the Blucher, drew a train of eight loaded wagons, weighing 30 tons, at a speed of 4 m. an hour up a gradient of 1 in 450. But, in the words of the same article, "This application of steam has not yet arrived at such perfection as to have brought it into general use.". The steam locomotive, however, and with it the railways, soon began to make rapid progress. On the Stockton & Darlington railway, which was authorized by parliament in 1821, animal power was at first proposed, but on the advice of Stephenson, its engineer, steam-engines were adopted. This line, with three branches, was over 38 m. in length, and was in the first instance laid with a single track, passing-places being provided at intervals of a quarter of a mile. At its opening, on the 27th of September 1825, a train of thirtyfour vehicles, making a gross load of about 90 tons, was drawn by one engine driven by Stephenson, with a signalman on horseback in advance. The train moved off at the rate of from 10 to 12 m. an hour, and attained a speed of 15 m. an hour on favourable parts of the line. A train weighing 92 tons could be drawn by one engine at the rate of 5 m. an hour. The principal business of the new railway was the conveyance of minerals and goods, but from the first passengers insisted upon being carried, and on the 10th of October 1825 the company began to run a daily coach, called the "Experiment," to carry six inside, and from fifteen to twenty outside, making the journey from Darlington to Stockton and back in two hours. The fare was 1s., and each passenger was allowed to take baggage not exceeding 14 lb weight. The rate for carriage of mer It was found, naturally, that the rails would not rest in their chairs at the joints, but were loosened and bruised at the ends by the blows of the traffic. The fish-joint was therefore devised in 1847 by W. Bridges Adams, the intention being by "fishing" the joints to convert the rails into continuous beams. In the original design two chairs were placed, one under cach rail, a few inches apart, as in fig. 7. The joint was thus suspended between the two chairs, and two keys of iron, called "fishes," fitting the side channels of the rails, were driven in on each side between the chairs and the rails. In subse-chandise was reduced from 5d. to one-fifth of a penny per ton quent modifications the fishes were, as they continue to be, bolted to and through the rails, the sleepers being placed rather further apart and the joint being generally suspended between them. The iron tramway or railway had been known for half a per mile, and that of minerals from 7d. to 1d. per ton per mile. The price of coals at Darlington fell from 18s. to 8s. 6d. a ton. The example of the Stockton & Darlington line was followed by the Monklands railway in Scotland, opened in 1826, and several other small lines-including the Canterbury & was blown up, its attendant, annoyed by the sound of the escaping steam, having fastened down the safety-valve. A second engine, the West Point, also built at West Point Foundry for the South Carolina railroad, differed from the Best Friend in having a horizontal boiler with 6 or 8 tubes, though in other respects it was similar. In 1831 the Baltimore & Ohio Company offered a prize of $4000 for an American engine weighing 3 tons, able to draw 15 tons at 15 m. an hour on the level: it was won by the York of Messrs Davis & Gartner in the following year. Matthias W. Baldwin, the founder of the famous Baldwin Locomotive Works in Philadelphia, built his first engine, Old Ironsides, for the Philadelphia, Germantown & Morristown railroad; first tried in November 1832, it was modelled on Stephenson's Planet, and had a single pair of driving wheels at the firebox end and a pair of carrying wheels under the smoke-box. His second engine, the E. L. Miller, delivered to the South Carolina railroad in 1834, presented a feature which has remained characteristic of American locomotives-the front part was supported on a four-wheeled swivelling bogie-truck, a device, however, which had been applied to Puffing Billy in England when it was rebuilt in 1815. Whitstable, worked partly by fixed engines and partly by | is reported to have hauled 40 or 50 passengers in 4 or 5 cars at locomotives quickly adopted steam traction. But the a speed of 16-21 m. an hour. After a few months of life it Liverpool & Manchester railway, opened in 1830, first impressed the national mind with the fact that a revolution in the methods of travelling had really taken place; and further, it was for it that the first high-speed locomotive of the modern type was invented and constructed. The directors having offered a prize of £500 for the best engine, trials were held on a finished portion of the line at Rainhill in October 1829, and three engines took part-the Rocket of George and Robert Stephenson, the Novelty of John Braithwaite and John Ericsson, and the Sanspareil of Timothy Hackworth. The last two of these engines broke down under trial, but the Rocket fulfilled the conditions and won the prize. Its two steam cylinders were 8 in. in diameter, with a stroke of 16 in., and the driving wheels, which were placed in front under the funnel, were 4 ft. 8 in. in diameter. The engine weighed 4 tons; the tender following it, 3 tons 4cwt.; and the two loaded carriages drawn by it on the trial, 9 tons 11 cwt.: thus the weight drawn was 12 tons, and the gross total of the train 17 tons. The boiler evaporated 184 cub. ft., or 114 gals., of water an hour, and the steam pressure was 50 lb per square inch. The engine drew a train weighing 13 tons 35 m. in 48 minutes, the rate being thus nearly 44 m. an hour; subsequently it drew an average gross load of 40 tons behind the tender at 13.3 m. an hour. The Rocket possessed the three elements of efficiency of the modern locomotive-the internal water-surrounded fire-box and the multitubular flue in the boiler; the blast-pipe, by which the steam after doing its work in the cylinders was exhausted up the chimney, and thus served to increase the draught and promote the rapid combustion of the fuel; and the direct connexion of the steam cylinders, one on each side of the engine, with the two driving wheels mounted on one axle. Of these features, the blast-pipe had been employed by Trevithick on his engine of 1804, and direct driving, without intermediate gearing, had been adopted in several previous engines; but the use of a number (25) of small tubes in place of one or two large flues was an innovation which in conjunction with the blast-pipe contributed greatly to the efficiency of the engine. After the success of the Rocket, the Stephensons received orders to build seven more engines, which were of very similar design, though rather larger, being four-wheeled engines, with the two driving wheels in front and the cylinders behind; and in October 1830 they constructed a ninth engine, the Planet, also for the Liverpool & Manchester railway, which still more closely resembled the modern type, since the driving wheels were placed at the fire-box end, while the two cylinders were arranged under the smoke-box, inside the frames. The main features of the steam locomotive were thus established, and its subsequent development is chiefly a history of gradual increase in size and power, and of improvements in design, in material and in mechanical construction, tending to increased efficiency and economy of operation. In America the development of the locomotive dates from almost the same time as in England. The earliest examples used in that country, apart from a small experimental model constructed by Peter Cooper, came from England. In 1828, on behalf of the Delaware & Hudson Canal Company, which had determined to build a line, 16 m. long, from Carbondale to Honesdale, Pennsylvania, Horatio Allen ordered three locomotives from Messrs Foster & Rastrick, of Stourbridge, and one from George Stephenson. The latter, named the America, was the first to be delivered, reaching New York in January 1829, but one of the others, the Stourbridge Lion, was actually the first practical steam locomotive to run in America, which it did on the 9th of August 1829. The first American-built locomotive, the Best Friend, of Charleston, was made at the West Point Foundry, New York, in 1830, and was put to work on the South Carolina railroad in that year. It had a vertical boiler, and was carried on four wheels all coupled, the two cylinders being placed in an inclined position and having a bore of about 6 in, with a stroke of 16 in. It The Liverpool & Manchester line achieved a success which surpassed the anticipations even of its promoters, and in consequence numerous projects were started for the construction of railways in various parts of Great Britain. In the decade following its opening nearly 2000 m. of railway were sanctioned by parliament, including the beginnings of most of the existing trunk-lines, and in 1840 the actual mileage reached 1331 m.. The next decade saw the "railway mania." The amount of capital which parliament authorized railway companies to raise was about 4 millions on the average of the two years 1842-1843, 17 millions in 1844, 60 millions in 1845, and 132 millions in 1846, though this last sum was less than a quarter of the capital proposed in the schemes submitted to the Board of Trade; and the wild speculation which occurred in railway shares in 1845 contributed largely to the financial crisis of 1847. In 1850 the mileage was 6635, in 1860 it was 10,410, and in 1870 it was 15,310. The increase in the decade 1860-1870 was thus nearly 50%, but subsequently the rate of increase slackened, and the mileages in 1880, 1890 and 1900 were 17,935, 20,073 and 21,855. In the United States progress was more rapid, for, beginning at 2816 in 1840, the mileage reached 9015 in 1850, 30,600 in 1860, 87,801 in 1880, and 198,964 in 1900. Canada had no railway till 1853, and in South America construction did not begin till about the same time. France and Austria opened their first lines in 1828; Belgium, Germany, Russia, Italy and Holland in the succeeding decade; Switzerland and Denmark in 1844, Spain in 1848, Sweden in 1851, Norway in 1853, and Portugal in 1854; while Turkey and Greece delayed till 1860 and 1869. In Africa Egypt opened her first line (between Alexandria and Cairo) in 1856, and Cape Colony followed in 1860. In Asia the first line was that between Bombay and Tannah, opened in 1853, and in Australia Victoria began her railway system in 1854 (see also the articles on the various countries for further details about their railways). Transcontinental Railways.-A railway line across North America was first completed in 1869, when the Union Pacific, building from the Missouri river at Omaha (1400 m. west of New York), met the Central Pacific, which built from San Francisco eastwards, making a line 1848 m. long through a country then for the most part uninhabited. This was followed by the Southern Pacific in 1881, from San Francisco to New Orleans, 2489 miles; the Northern Pacific, from St Paul to Portland, Ore., in 1883; the Atchison, Topeka & Santa Fé, from Kansas City to San Diego; and the Great Northern from St Paul to Seattle and New Westminster in 1893. Meanwhile the Canadian Pacific, a true transcontinental line, was built from Montreal, on Atlantic tide-water, to the Pacific at Vancouver, 2906 m. But these lines have been dwarfed since 1891 by the Siberian railway, built by the GENERAL STATISTICS Mileage. At the close of 1907 there were approximately 601,808 miles of railway in the world, excluding tramways. On the whole, the best statistical source for this information is the annual computation published by the Archiv für Eisenbahnwesen, the official organ of the Prussian Ministry of Public Works; but the figure quoted above utilizes the Board of Trade returns for the United Kingdom and the report of the Interstate Commerce Commission for the United States. In the United States and in certain other countries, a fiscal year, ending on the 30th of June or at some other irregular period, is substituted for the calendar year. railways, connecting the Pacific coast of the United States with the central portions of the country, and thus with the group of railways the borders of the United States, and one in Canada. In Canada reaching the Atlantic seaboard, consisted of five railways within the Canadian Pacific was the only transcontinental line, extending from St John, on the bay of Fundy, and from Quebec, on the river St Lawrence, to Vancouver, on the strait of Georgia, the distance from St John to Vancouver being approximately 3379 m. Within the boundaries of the United States the northernmost of the transcontinental lines was the Great Northern railway, extending from a point opposite Vancouver, B.C., and from Seattle, Wash., to Duluth, on Lake Superior, and to St Paul and Minneapolis, Minn., where connexion through to Chicago was made over an allied line, the Chicago, Burlington & Quincy, owned jointly by the Great Northern and the Northern Pacific. Next, south of the Great Northern, lay the Northern Pacific railway, starting on the west from Portland, Ore., and from Seattle and Tacoma, Wash., and extending east to Duluth, St Paul and Minneapolis by way of Helena, Mont. The Central Pacific-Union Pacific route to the coast, with its important affiliated companies, the Oregon Short Line and the Oregon Railroad & Navigation Company, extended from San Francisco, Cal., and Portland, Ore., to Omaha, Neb., by way of Salt Lake City; the Atchison, Topeka & Santa Fé extended from San Francisco and Los Angeles, Cal., to Chicago and to Galveston, Tex.; while the Southern Pacific had its line from San Francisco and Los Angeles to Galveston and New Orleans, running for the greater part of the distance just north of the Mexican border. The partition of this total between the principal geographical before, were showing great increases in earnings. In 1903 the divisions of the world is given in Table I. Europe Asia TABLE I.-Mileage of the World Miles. 18,516 17,766 Table II., classifying the mileage of Europe, shows that Russia has taken the lead, instead of Germany, as in former years. If the Asiatic portions of the Russian Empire were given in the same table, the total Russian mileage would appear nearly as large as that of Germany and Italy together. Spain 9,228 Total coast-Seattle and Tacoma, Wash., Portland, Ore., and San Francisco Miles. 68 Recent American railway development, viewed in its larger aspects, has thus been characterized by what may be described as the rediscovery of the Pacific coast. How far this movement will extend it is impossible to say; it is certain, however, that it will be enormously important in re-aligning trade conditions in the United States, Canada and Mexico. Table III. illustrates the railway mileage in the continent of America at the close of 1907. TABLE III.-RAILWAYS OF AMERICA IN 1907 199.371 In the United States railway mileage now tends to increase at the rate of slightly over 5000 miles a year, which is about 2% on the present main line mileage. In the eighties, the country passed through a period of competitive building, which was productive of much financial disaster. Thus, in 1882, 11,569 m. were built an addition equivalent to more than 11% of mileage then existing-and in 1887, 12,876 m. were built. Unjustifiable railway expansion had much to do with the American commercial panics of 1884 and 1893. After the reconstruction period of the 1893 panic, however, the tendency for a number of years was to spend larger sums in bettering existing railways rather than in new extensions. The decade from 1896 until 1905, inclusive, saw huge sums spent on yards, passing tracks, grade reduction, elimination of curves, substitution of large locomotives and cars for small ones, &c. During those ten years, the route mileage increased 34,991 m., or 17%. while the mileage of second, third, fourth and yard tracks and sidings increased 32,666 m., or nearly 57%. The number of locomotives increased 12,407, or 35%, and the number of freight Greater Antilles. cars, 545,222, or 42%. Moreover, the average tractive power per locomotive and the average capacity per freight car advanced greatly in this period, although specific figures cannot be given. Thus it may fairly be said that the railway system of the United States was reconstructed between 1896 and 1905, so far as concerns rails, sleepers, ballast and the general capacity of a given group of lines to perform work. About 1905, however, a new tendency became apparent. United States Lesser Antilles 309.974 Outside the United States and Canada, the most interesting At that time the so-called transcontinental | American developments are in Mexico and Argentina, these countries having nearly the same amount of railway mileage. In Mexico the national government is carrying out a consistent policy of developing its railway lines. It has succeeded in restoring the credit of these enterprises, and is proceeding with care and skill to form the lines into an efficient transportation system. In Argentina about 15% of the railways are owned and operated by the government, the balance being in the hands of private companies, largely controlled in England. Development of these lines has been primarily an extension from the large cities in the East to the agricultural districts in the West, but a change of great importance was brought about in 1910 by the completion of the last tunnel on the Argentine Transandine Railway, which serves to connect Santiago, Valparaiso and the other great cities of the west coast with Buenos Aires, Montevideo, Bahia, Rio de Janeiro and the other great cities of the east coast. Naturally the company named does not reach all of these points, but its line across the Andes supplies the indispensable link of communication, in the absence of which the east coast towns and the west coast towns have hitherto been as widely separated as if they had been located on different continents-indeed, far more widely separated in point of time and of freight charges than Great Britain and the United States. Table IV. shows as closely as possible the railway route mileage open in Asia at the close of 1907. TABLE IV-RAILWAYS OF ASIA IN 1907 Table VII. illustrates the mileage open to the end of 1907 per 100 sq. m. of territory and per 10,000 inhabitants. It will be observed that Belgium leads all the countries of the world in what may be called its railway density, with the United Kingdom a far-distant second in the list, and Persia last. In railway mileage per 10,000 inhabitants, however, Queensland, in the Australian group, reports a figure much greater than any other country; while at the other end of the list Persia holds the record for isolation. Denmark Malay States Siberia and Man Dutch East Indies 1,509 Sweden Ceylon Korea 688 Cochin China Greece Turkey in Europe, Bulgaria, Rumelia Malta, Jersey, Man Persia Asia Minor, Syria, Arabia Pondicherry and Cyprus 2,930 Malacca 5.1 Portuguese East Indies Although more than half of the total mileage of Asia is in British India, it is probable that the greatest proportionate gains in the near future will be in China, Siberia and Manchuria, and Central Russia in Asia. In proportion to its population China has the least railway development of any of the great countries of the world; the probability that its present commercial awakening will extend seems large, and in that case it will need a vast increase in its interior communications. In Africa, it will be seen by Table V. that the railway mileage in the British possessions amounts to almost five-sixths of the total. TABLE V-RAILWAYS OF AFRICA IN 1907 Uruguay Chile Argentina' 1.8 13.0 1,235 Congo States 399 French Provinces. 1,246 Abyssinia 192 British South Africa 7,028 German Provinces 1,148 Italian Provinces. Portuguese Provinces Asia, 1907 71 9.8 China 0.12 The so-called Cape-to-Cairo route shows occasional extensions, particularly in the opening up of new country in Central Africa by the Rhodesian railway system. The Rhodesian railway system in 1910 had penetrated north of Broken Hill, which is just above the fifteenth parallel of south latitude, while the Egyptian railway system had reached Gondokoro, located close to the fifth parallel of north latitude. The intervening distance, through country exceedingly unhealthy for white men, and therefore promising no traffic except raw materials, does not seem a likely field for rapid railway extension. In Australia the increase in railway mileage in the five years ending December 31st, 1907 was about 7% a small proportion as compared with America, Asia or Africa. The greatest increase, both relative and absolute, was in Queensland; the smallest in South Australia, which added only 24 m. during the five years. Yet the mileage open per 10,000 inhabitants in Australia, as a whole,, far surpasses that in any other of the broad geographical divisions. TABLE VI.-RAILWAYS OF AUSTRALIA IN 1907 |