Towards the end of the War we sat in our cellars and whispered after each bomb that dropped nearby, “Can you smell gas?” We didn’t know what it smelt like, but we sniffed apprehensively and hoped there would be no strange smell. What if we had smelt gas? We should have died like rats in a sewer. We should have been merely part of the dead incidental to war. And not even the useless consolation of a place on a Roll of Honour. The war-dead, whether they are civilians or civilian soldiers, are victims of a predatory anarchy, which exists between nations by virtue of the profit system. They are not even romantic victims. They die terror-stricken, in mud and filth. They crouch in holes, waiting for high-explosive and asphyxiating and excoriating gases to put a period to their lives. Their monument is an interim dividend.
What is the answer of capitalism to this? Aeroplanes, more aeroplanes, and yet more aeroplanes, with bombers in the ratio of two to one.
Let me give you another little picture, this time drawn by Major Endries, in his book, “Gift Gaskreig.” This is an English raid on the German manufacturing town of Dusseldorf: —
Light bombing squadrons arrive quickly in the darkness. They drop on the largest and most important factories, now working on night shift, bombs filled with white phosphorus. A torrent of inextinguishable flames overwhelm the buildings. Workmen attempt panic-stricken escapes to the cellars—the population, more panic-stricken, flies underground. The raiding party wireless to H.Q. “successful raid,” and calls for a second raiding party. These arrive with light gas bombs, spreading first an irritant gas that can pierce masks, followed by a second, stronger and more lethal gas, which kills the populace as they flee from underground cellars made uninhabitable by the first gas. Every two or three hours similar attacks are repeated on different parts of the town until everything is enveloped in flames, and clouds of poison gas mark the place where before hundreds of thousands of human beings lived and moved.
It has been suggested that an electric ray or system of electrical power projection might be used against hostile aircraft. Apart from widely scattered articles in the sensational press, there has been no evidence that such a ray or power projection is contemplated or possible, but presumably it would operate by interfering with the ignition, either magneto or coil, and—a remoter possibility—by exploding the fuel tank. It is a matter of fact, however, that intensive experiments have been in progress during the last few years with the application of the compression ignition engine (the Diesel) to aircraft, and the engine will be available for use in heavy aircraft within a matter of months. A ray of the type suggested would, therefore, be quite useless, since the Diesel has no electrical machinery to be affected, and the crude oil fuel is practically non-inflammable.
It is not difficult under a regime of unrestricted development to contemplate bomb and container designs which would release poison gas to dissipate uniformly in a low-lying cloud or death blanket not higher than our tallest buildings. But assume a blanket one hundred yards high, which gives a big margin of error, and we find that less than half a ton of chemical is sufficient to produce effective saturation over a square mile. Even if you multiply this by a thousand to allow largely for wind losses, barriers and higher concentrations, you are still far within the limits of practicable gas attack from the air.—“Scientific Disarmament,” Victor Lefebure.
Mustard gas, which, with Lewisite, is the gas best adapted for the destruction of civilian populations, is known technically as diclorethyl-sulphide. With Lewisite and chlorpicrin it is classified as a vesicant gas because it attacks not only the respiratory organs, but also the eyes, skin and surface tissue of the body. The mask, therefore, is not an efficient or a complete protection. Ordinary clothing will protect against mustard or Lewisite for two or three minutes, after which the gas, which is an easily vapourising liquid, penetrates to the skin. A complete suit of oilskin, so constructed as to be airtight, is a protection, but as such suits could not be worn for more than an hour or two without collapse, it is a matter of Hobson’s choice. As an emergency protection against low concentrations, motor grease smeared thickly on the exposed parts of the body, and especially between the fingers, in the elbow joints, and the parts of the head uncovered by the mask, is said to be effective. The manufacture of oilskin suits in useful quantities is impossible, and the cost would necessarily prohibit wide distribution among the class of people most in need of them—the workers.
Low concentrations of mustard do not kill if the respiratory organs are properly protected, although Lewisite, so far as effective concentration is concerned, is largely an unknown quantity. It causes painful lesions of the skin and tissue, and ulcers and sores, which may lead to prolonged invalidism. The ulcers may be gangrenous and, in the case of Lewisite, will, unless dealt with rapidly, be arsenically poisoned.
The injuries are very difficult of healing. A resultant tendency to despondency and lowering of morale in the patient is often seen. The combating of this must be made a special point in nursing these cases.—“First Aid in Defence Against Chemical Warfare” (Collins & Blackmore).
Both mustard and Lewisite are known as persistent gases, i.e., they persist in the place where dropped for periods varying between seven and fourteen days. The contaminated areas must be treated immediately with “ bleach ” (chloride of lime in powder form) if they are to be moderately safe for use. These gases also persist on the clothing of persons who have been in contact with them, and, if they entered a warm room or gas-shelter, unless their clothing was removed, they would injure the persons in the shelter. Mustard does not affect the skin immediately, the period of delay being from three to twenty-four hours. It is therefore quite possible for such persons to transmit the gas unknowingly for a considerable time. Used against disciplined troops, with proper respiratory protection, the proportion of deaths to casualties from mustard gas is very low, but it cannot be too greatly emphasised that the population of our large cities have not the necessary discipline and knowledge to protect itself.
On cold nights mustard is liable to lay in liquid form on the ground, becoming a dangerous vapour when the temperature rises in the morning.
Food contaminated by mustard gas is uneatable. Mustard burns are as painful inside as out— and fatal. It is certain that docks and wharves would be heavily bombed with mustard to contaminate essential food supplies.
Water is easily contaminated, and boiling is not a protection. To drink affected water might easily be fatal. Reservoirs are easily bombed, and cannot be covered, because water depends upon contact with air to keep it fresh.
Chloride of lime is an efficient neutralising agent, but it is doubtful (to say the least) if enough could be manufactured to supply the civilian population and the forces actively engaged, and since very large supplies of this chemical would be a tactical necessity for the armed forces, the amount available for civilian defence would be inadequate. It is not an exaggeration to say that adequate supplies of chloride of lime will be the deciding factor in any future European war. Lewisite has the definite disadvantage of being efficiently neutralised by water, large supplies of which are usually available. Mustard, on the other hand, can be used to infect large areas for several days, and during this time no troops could use the areas in question. To gain contact with the opposing forces it would be necessary to make “neutral” lanes through the gas by spreading large quantities of chloride of lime.
The most usual type of mustard gas bomb weighs 50 lbs. and contaminates about 600 square yards; the average load of a bombing aeroplane would, therefore, be 90 bombs capable of infecting an area of 54,000 square yards. In practice, of course, there would be a great deal of overlapping, and the figure given cannot be regarded as accurate. Even if we reduce the area by 50 per cent., however, we are left with 27,000 square yards, or 15 square miles, and, although the population of such an area would not necessarily be killed in its entirety, the total of fatal and non-fatal casualties would be extremely high, and it would be dangerous in the extreme for the survivors to move until the gas had been neutralised. There is, too, the additional problem of dealing with injured persons, which, at the present time, seems impossible of solution.
When, during the late War, it was proposed to use mustard gas in shells, it was discovered that the use of liquid presented serious problems in ballistics, which had to be overcome before it could be used. Although these technical difficulties were overcome, gas shells will always remain complicated and expensive things to make. The gas bomb, on the other hand, is not fired by percussion, but dropped. The difficulty, therefore, does not arise. A certain amount of streamlining is used for greater accuracy, but, quite apart from the fact that a gas bomb does not require to be very accurate, even petrol-tins filled with liquid gas and dropped, almost without discrimination, would be effective.
The practice of spraying gas from containers has not yet been used against civilians, but, given reasonable weather conditions, there is no reason why it should not be effective.
It is improbable that gases of the phosgene type would be used against large centres of population, chiefly because mustard is much more effective, easier to handle and as cheap to manufacture. A large distribution of masks capable of protecting the respiratory organs, the provision of gas-shelters arid the efficient gas-proofing of rooms (a comparatively easy job) in the better-built private houses, would provide adequate protection against this gas, which is deadly enough in its effects upon the unprotected, but non-persistent and relatively easy to keep out. Stemutator gases, to stampede the people, might be used, but to assume that the enemy in time of war (whoever the enemy might be) would wish to stampede the people when they could kill them as quickly and easily is a little naive.
It seems clear, then, that we shall have to deal almost entirely with the vesicant gases, high-explosive, thermit and possibly bacteria, and I therefore proceed to a consideration of these three last factors, which, in the anxiety to provide against the major threat of gas, are too often overlooked.
High-Explosive, Thermit and Bacteria
High-explosive is chiefly valuable in air attack for cutting essential connections, such as light, power, gas, water and drainage, in the spreading of general panic by reason of the violence of its effects, and in the destruction of shelters.
There has been great development in the destructive power of high explosive since 1918, and also in the technique of its use.
As an example, the time-delayed bomb may be considered. This bomb explodes between four and 36 hours after it has been dropped, the time of explosion being under full control. In regard to this weapon, the report of the German Red Cross in 1928 to the 13th International Red Cross Conference says: —
It is obvious that all rescue and protective measures would be practically useless if such a bomb exploded in a town after several hours or days. Even the best organised rescue services could scarcely be brought into action under such conditions, and such a step would really mean useless sacrifice.
High-explosive bombs used in aeroplane attacks on London during the last War weighed about 30 lbs. Airship bombs were somewhat larger. Bombs at that time were sufficiently “delayed" to explode after passing through two or three storeys, and could destroy a large house.
It is now possible to construct bombs carrying upwards of a ton of explosive.
In the section dealing with protection I quote some figures given by General Von Haeften, and there is no reason to regard them as exaggerated. Explosive is much more dangerous and destructive than it was twenty years ago.
Thermit has not yet been used against civilians. Its use in times of peace is for welding iron and steel, particularly under-water welding, It can produce a fire-centre of 3,000 degrees Centigrade— above the melting temperature of steel. There is-no method of extinguishing it.
Thermit is a mixture of magnetic iron oxide and aluminium powder, and it can be used equally well in shells or bombs. Thermit bombs weigh approximately 2 lbs., and each bomb is capable of starting a fire centre. Aeroplanes can carry large numbers of these bombs, and it would be a simple matter to start several hundred fires, which might or might not be serious, within the space of an hour or so.
The London Fire Brigade quite recently required most of its personnel and equipment, and the assistance of several fire-floats, to put out a wharf fire, and spent five days doing it. They could not even start to mitigate. the effects of several hundred fires springing up in rapid succession.
The question of the use of bacteria is one that has often been written round, but never seriously examined, in the public Press. This is probably because the effect of this type of warfare is largely incalculable.
It has been rumoured that, at the close of the last War, preparations had been made in several countries to use bacteria, and, in particular, that glanders cultures were discovered in a German embassy for the avowed purpose of infecting Rumanian cavalry horses. Rumour, of course, is proverbially the lying jade, but the technical resources of the time permitted it, and war, after all, is the art of inflicting the maximum of destruction upon the enemy with the minimum of damage to oneself. It would be absurd to expect any considerations of humanity or ethics to temper the tortuous workings of the military mind. The recent bombing of Red Cross units in Abyssinia was quite predictable. It is merely the military mind running true to type.
L. G. Savage
Blogger's Note:
The October 1936 issue of the Socialist Standard carried the following correction in connection with this particular article.
Mr. L. G. Savage, the writer of this series of articles, asks us to point out that the instalment which appeared in the August issue contained two errors. In column one, page 123, last paragraph, "magnetic or coil" should read "magneto or coil."The figures in the last paragraph, column one, page 124, are incorrect. 27,000 square yards is not 15 square miles, but only a small part of a square mile. It will be observed, however, that 27,000 square yards is the area likely to be contaminated by liquid mustard gas, and bears no relation to the area likely to be affected by gas in vapour form.Ed. Comm.
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