JPRS ID: 9579 WEST EUROPE REPORT

APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000300094401-8 FOR OFFICIAL USE ONLY JPRS L/9579 2 March 1981 - : ~ : ~ ' : West E u ro e Re o rt p p tFOUO 12/81) Fg~$ FOREIGN BROADCAST INFORMATION SERVICE FOR OFFICIAL [JSE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000300094401-8 NOTE JPRS publications contain informatian nrimarily from foreign newspapers, periodicals and books, but also from news agency transmissions and broadcasts. Materials from foreign-language sources are translated; thcse from English-language sources are transcribed or reprinted, with the original phrasing and other characteristics retained. _ Headlines, editorial reports, and material enclosed in brackets are supplied bv JPRS. Processing indicaters such as [Text] or [Excerpt] in the first line of each item, or following the last line of a brief, indicate how the original information was processed. 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C. 20013 26 February 1981 ;VOTE FROAi THE DIRECTOR, FBIS: ' Forty years ago, the U.S. Government inaugurated a new service to monitor foreign public broadcas~s. A few years later ' a similar group was established to exploit tlte foreign press. ; Frori the merger of~these organizations evolved the present-day ~ ; FBIS. Our constant goal tlirougisout has been to provide our readers with rapid, accurate, and compreliensive reporting from tlie p~blic media worldwide. On behalf of all of us in FBIS I wish to express appreciation to our read~rs wlio liave guided our efforts throughout the years. i I ~ _i _ ~ APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000300094401-8 - FOR OFFICIAL USE ONLY JPRS L/9579 2 March 1981 , . WEST EUROPE REPORT cFOUO ia/si~ CONTENTS THEATER FORCES ~ FRANCE 'Nuclear Ma,~inat Line' Concept Criticized, Defended , (Jean-Baptiste Margeric'Q; STRATEGIQUE, No 8, 1980)...........o0 1 - COUNTI~ SECTION FRANCE Poss.ible PS-RPR Collaboration in 1981 Election (Claude Jacquemart; VALEURS ACTLTELLES, 8 Dec 80)...0.......,.. 25 , , . ITALY Possible International Connections of Terrorism Analyzed (IL CORRIERE DELLA SERA, 22 Jan 81) ..............o.....o....... 29 Investigative Report on PCI's Internal Problems (Frane Barbieri; LA STAMPA, various dates) 42 ~ - a - ~III - WE - 150.FOU0] i APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 ' FOR OFFICIAL USE ONLY ~iEATER FORCES FRANCE 'NUCLEAR MAGINOT LINE' COrTCEPT CRITICIZED, DEFENDED Paris STRATEGIQUE in French ~Oct-Dec~ No 3, 1980 pp 89-122 ~Article by Jean-Baptiste Margeride*; passages enclosed in slantlines in italics~ ~Excerpts~ In ever increasing numbers since the mid-1970's, Western military specia~ists have been addressing the grave issue of adequation of 1?ATO defense plans and means to meet a potential aggression by the Warsaw Pact forces. These specialists estimate that the unflaggin over-arming effort being deployed ' by the East European nations, in conventional~l~ as t~ell as tactical and thea~er nuclear weapons, and in chemical warfare weapoms, has�given them an overwhelmirig superiority. Added to this superiority of forces is their degree of immediate ~ availability, which is constantly being in~creased, thus incr.easing the potential for a surprise attack. In th~ face of this constantly growing threat, Western defensive capabilities are, ~ in the view of these specialists, decidedly inf~rior; and as for SVestern plans, these have hardly changed in 20 years or more and have not been updatec3 in accord- ance with the many technological changes.~2~ More recently, and to remedy this situation, certain authors, led by American - Physicist Samuel T. Cohen, have proposed the creation of a kind of "Maginot line" that, equipped with nuclnar strike and interdiction weapons, would reduce to impotence the formidablE; war machine being built by the USSR.~3~ : - The intent of this article is: --to explain the "nuclear Maginot line" con~ept, and --to examine the technical criticisms that can be advanced in regard to this ~ concept. ; I * The author has already published two articles: "Technical Factors in the 'Counterforces' Strategy" in STRATEGIQUE No 1, and "The Enhanced-Radiation Weapon" in STRATEGIQUE Nos 3,4,5,6 and 7. ~ .i ' 1 i FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 FOR OFFICIAL USE O1VLY The ~Tuclear I'ortified Line ('The City Walls' ) - We will analyze as simply as possible th~ nuclear Maginot line concept th.at - S.T. Cohen likens to "the city walis" of long ago, but will endeavor throughout to respect the intent of its advocates.~9~ The latter argue from the following basic premise: Until the advent of the nuclear era, the penetration of all fortified lines has been possible because the attacker could concentrate, on a limited front, a volume of weapons capable of overwhelming the defenders. This fact of military history has changed radically _ with the advent of the nuclear weapon, because the latter makes it possible to interdict such concentrations. R Fortified Zone They propose therefore the establishment of a fortified zone extendinq the entire length of the border to be defended--a zone made up of an array of basic strong- points distributed in length and depth along five successive lines, each line approximately 5 km (the order of magnitude of ~he range of the future third- generation antitank missiles) distant from the preceding ~ine. The ~otal depth of the fortified zone would thus be approximately 20 km. Along Each line, the basic strongpoints would be spaced approximately 500 meters (machine-gun range) apart. These strongpoints would be reinforced concrete bunkers, buried under a thick enouyh layer of earth to shelter the personnel from the radioactivity released by low-altitude nuclear-warhead bursts,~l~~ including - those of enhanced-radiation weapons. The crew manniiig each strongpoint-~-10-12 men--would operate, by remote control, an array of weapons mounted on retractable turrets: automatic-loading antitank rifles; Shillelagh-type missile-launching antitank canon; machine guns and anti- personnel machine-rifles. The detection, vision, identification and aiming equipment would be periscopic devices utilizing the diverse frequency spectra-- visible, infrared and millimetric--to provide an equally effective day and night all-weather surveillance and combat capability, despite:smoke generators, etc. The terrain would also be sown with conventional obstacles--barbed wire, antitank ~ ditches, mines, etc--designed to delay the enemy's advance and to augment the time duri.ug which the enemy tanks and foot soldiers would be pinned down by fire from thE strongpoints and exposed to alarm sensors of all types. Infantrymen on foot, outside their armored transport vehicles, would be subjected to fire from 3 or 4 strongpoints if within range of the machine guns, from 6 or 7 if covered by the small-caliber automatic rifles, and from 15 to 20 strongpoints in the case of the heavy mortars. .2. FOR OFF'ICIAL USE OIYLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 i FOR OFF[CIAL USE ONLY ~ Nuclear Weapons Should the enemy attack exceed a certain level of power--not in~~i~ted, but the order of magnitude of which might be one or two tank companies, possibly rein- forced by armored infantry--the authors of this proposal deem that the defense by - conventional means should be replaced by enhanced-radiation nuclear-weapons fire. And, as we know, a 1-kt warhead covers substantially a circle whose radius is 0.85 km, that is, an area of 2 km2, ' The advocates of this defense system estimate at around 5,000, or one weapon per 10 enemy tan~s and 10 VCI's ~Infantry Combat Vehicles~, the number of neutron warhea3s needed along the Iron Cu~tain front. They wou18 be delivered by limited- rar~ge--a few tens of kilometers~12~--but highly accurate launchers. Accuracy would = be obtained thr~agh data furnished by the strongpaints, but perhaps also through the missile's own texminal guidance system, which would still be dependent upon the strongpoint for laser illumination of the target's ~~P:~ter of gravity. This, - it seems, would mean using nuc.lear~~M:s (Precision Guided Munitions) such as Copperhead warheads or smart bombs , or radar, laser or xnfrared homing _ missiles. As has already been indicated, the ~ersonnel manning a strongpoint would be fully sheltered from the radiation, even if the neutron �-~.rhead exploded directly over the strongpoint, as the latter would be protected by several meters of concrete and earth. Radioactive Obstacles _ To this system of obstacles and fireoower, the authors add an innovative scheme: The natural and artificial obstacles would be supplemented by zones of intensive radioactivity that would interdict the advance of foot troops --infantrymen, ~ sappers toward strongpoints, slowly but without excessive risk against the strongpoint's conventional weapons, by way of approaches defiladed from view and low-angle fire. These radioactive zones could be created as needed, usinq the properties of acrivated sodium~14~. Two methods of 4ctivation can be used simultaneously. ~ - The first consists of a priori peacetime sowing of carefully worked out mandatory - cr.ossing points and zones with sodium carbonate, and of activating the latter as the need arises, by means of neutrons released by an enhanced-radiation weapon. These zones would then become too radioactive for the enemy to consider sending foot troops through them or stationing armored units in them. If, after a certain time, the radioactivity of the zone is found to have diminished below a certain point, the original level can be restored by exploding another neutron warhead. It will be seen later, however, that in proportion to the quantities of sodium deployed, the fraction rendered radioactive is infinitesimal. _ 3 FOR OFFIC[AL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 FOR OFFICIAL USE ONLY The second method, which is even more innovative, consists of burying, at rela- tively great depths not specified by the authors of the proposal, "Dumbos": large metallic vessels built to withstand tne /internal/ blast of a 0.1-kt(15~ nuclear- fusion warhead. These vessels would contain sodium carbonate, apparently in ~ aqueous solution. In case of necessity, the nuclear-fusion warhead would be detonated, the neutrons produoed would activate the sodium, forming radioactive Na-24. The radioactive water ot this solution wou7.d be.pumped up to and spread _ over the terrain. in the zones that are to be denied to the enemy. A Conventional Forces Complement Optimistic though they are about the effectiveness of their fortified line, its authors nevertheless assume the possibiZity of enemy penetrations, though on a very limited scale. The need continues, therefore, for conventional fprces to deal wi~h this eventuality--forces essentially built, it would seem, around tank- destroyer-type missiles, that is, relatively light, very mobile missiles armed ~ with a powerful antitank warhead. ' The need for g~ound forces is also assumed by them to deal with air- or helicop- ter-borne attacks deep inside friendly territory. The entire array--fortified zone, conventional units, rear territorial zone-- must be covered and supported by sizeable air forces. Location of the Fortified.Zone ~ This question is at best only briefly addressed by the authors of the proposal. According to t4-iPm, it would be highly desirable that the NATO defense zone be established in the FRG, along the entire Iron Curtain, a length of about 1,000 km. International agreementso however, prohibit the FRG from producing and freely deploying nuclear weapons of any type whatever. S. T.Cohen has suggested in various articles that, in the alternative, this defense system could be installed - - by France along its northeastern border, without specifying, however, whether it ~ should be loc~ted exclusively on French territory or whether it should be extended beyond the Ardennes along the Benelux borders with the FRG.~16) Critical Analysis Expropriation of the Fortified Zone Strictly speaking, and since the "nuclear Maginot line" concept is premised on the enemy's strategic posture and the peremptory hypothesis of a surprise offensive by the Warsaw Pact forces, there could be no question of permitting civilian popula- tians to remain in the fortified zone, since the Allied neutron weapon must be able to be deployed anywhere within the zones without advance warning and in large ~ numbers, to deal with any surprise attack. This concept therefore presupposes a civilian "no man's land" some 25 km deep along the entir.e border to be defended. If, by way of example, we examine the situati~n in the FRG, such a measure would involve the definitive and permanent evacuation, during peacetime, of numerous -4~ FOflt O~'FICIAL USE ONLY - APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 APPROVED FOR RELEASE: 2007/02148: CIA-RDP82-00850R040340090001-8 FOR OFFICIAL USE ONLY localities, indeed of large cities such as Lubeck, Wolfsburg, Salzgitter, Gottingen, Cobourg, Hof. This praspect being.unaoceptable, the remaining alter- natives would be either to abandon these densely. pogula~ed.regions to the invader or to de~end them by other means. If we examine the situation in France, where consideration has been given to defense by means of such a system as an adjunct to our strategic deterrent, the problem posed by the expropriation of a fortified zone is analogous mutatis mutandis. Moreover, the deterrent effect of a nuclear Maginot line established - on French soil, against a potential attack by the Eastern European countries on the FRG, would be oFen to some question: Tn other words, the "tactical deterrent" value (if indeed these two terms can be so combined) would--at best--be of no benefit.to any but the country having established it alonq its entire border; and certainly not to t~ those of its allies wr,ose territory is situated beyond this border, which, with respect to France, would be the case of the FRG and, possibly of the Benelux nations, Italy... Actually, as was demonstrated by the 1940 invasion, the defense of a border by means of a fortified zone can prove illusory, since the enemy can bypass that zone by simply qoing through a neutral country. In the case of the FRG, that uncer= - tainty would require that it extend its defenses along the Austrian border, beyond the Bohmerwald to the region opposite Salzburg; that is, 200 km and 5,000 km2 more to be expropriated. ~ In the case of France, the fortified line, beginning at the North Sea, would (in the event it were not extended across the Benelux nations) have to run along the entire Swiss border as far as Geneva. Dunkirk, Tourcoing e.t Roubaix, Sedan, Thionville, Strasbourg, Colmar, :iulhouse, and Pontarlier et Gex, all situated within the fortified zone, would therefore have to be excluded from the defense system if they could not be evacuated... Vulnerabilities of the Fortified 2one The authors of the plan, assume that this 5ortified system, like any other, can 6e pierced locally. S.T. Cohen estimates that around 150,000 men would suffice to - seal up any breaks of "limited size and respond to rear-area air- or helicopter- - borne enem~ actions--even though the USSR currently has 8 airborne divisions. The reasoning may be summarized as follows: --the firepower of each strongpoint would be amply sufficient to enable it to withstand, by its owri means, any loose-formation attacks; , --any large enemy concentration would be dealt with by enhanced-radiation weapons , fire; --any attempts at secret infiltration by foot traops--infantry or sappers--would be doomed to failure in zones rendered artificially radioactive; .5. _ FOR OFFIC[AL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 FOR OFFIC[AL USE ONLY ~ --and l.astly, a knockout breach by means of massive nuclear fire is inconceivable, since, to destroy the buried strongpoints, the enemy would have to resort to ground bursts that would produce, around the craters, an intensive radoactivity that would prevent entirely the passage of his armor and, even more so, that of his foot troops. But tr.is reasoning, based on the attacker's nuclear capabilities, takes no account of. his conventional capabilities in the forrn ot highly e��ecti:ve, even though - not nuclear, conventional missiles in his arsenal. Actually, the stopping power of the strongpoints depends not only on the nature of their.weapons, but also on their ability to use them. As has been mentioned above, the deeply buried p~sition of the strongpaint crews requires, at the surface, means of surveillance, observation and aiming that must be operational at all times and under all conditions (day, night, fog, etc) and that must use all imaginable techniques: visible light, infrared, electromagnetic detection (radars), etc. All of these systems have in common their fragility. The enemy could thus breach the fortified zone by means of nan-nuclear bombardments designed to destroy these sensors. Blinded, the defensive strongpoints would be depriv~ed of their combat capability, hence neutralized. The sensors could be destroyed in several ways. In fact, the use of explosive aerosol cloud missiles by the enemy against inher- ently fragilA targets cannot be ~xcluded from consider ation.~l~~ It appears, therefore, that the attacker, provided he commits weapons in sufEi- cient number and suited to the breaching of fortified zones, could create large gaps in it without having to resort to nuclear weapons.~18~ - These breaches accomplished, the invader could then commit his armored units in , accordance with nuclear dispersion levels. The disappearance of the local ground observation system would render much more difficult for the defender the use of his neutron weagons against the attacking units (with spy satellites destroyed or blinded and the defender's manifest air inferiority leaving the latter hopelessly deprived of ineans of reconnaissance... Iz any case, the time delays involved in analysis of the data furnished by orbiting or airborne systems appear hardly compatible with the zccuracy demanded, in terms of time and space, by the effective range of enhanced-radiation weapons~. At this point, according to S.T. Cohen's plan, the defender could resort to his tank-destroyer units to try to stem the enemy advance. The evaluation of the number of units required to stop the thousands of enemy tanks and VCI's that would exploit the breach seems very low, however, considering that the total strength of this conventi~nal component, charged also with figh ting against potential air- borne rear-area operations, would not exceed around 150,000 men.~l9) , g . FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000300094401-8 ~ FOR OF'FICIAL USE ONLY Artificial Radioactive Zones This brings us to the most innovative of the plan's concepts, that of infil- tration zones interdicted by the presence of activated sodium irradiated with neutron warheads. We must confess from the outset that this idea leaves us some- what perplexed, since elementary calculations seem to indicate that this system of defense can be but very limitedly effective. We must assume, of course, that the sodium carbona~.e will :,ave been put in place during peacetime, since the basis of the fortified zon~ concept is the response to . a surprise attack. The presence of sodium-23 is in~ended to substantially enhance _ the activation of the ground's component substances under irradiation by the neutrons released by nuclear explosions. Thi~ effect is labeled under the acronym NIGA (Neutron Induced Ground Activation)~20) by the Anglo-Saxons. Very roughly speaking, two methods of activation may be used: --either a low-altitude burst, at around 100-150 .i, to produce strong irradiation intensities at ground zero and its immediate vicinity, --or raise the altitude and "power" of the explosion--for example, to some ` 300-400 m--to obtain an activation whose decay would be less rapid with increasing distance from ground zero, but which at ground zero itself would be :~~eaker than in the first alterna~ive unless a xelatively more pawer�ul warhead is used. Which are we to chc~ose? We know that the fast neutron flux diminishes with dis- tance in accordance With a law in terms o� 1/R2 x exp(�-R/235). If, all other thinqs being equal, we compare the activations produced at ground zero by a war- head exploding at an altitude of 100 m with those by an explosion at 300 m, we find that the ratio of possible activations at ground zero is 21 to 1 in favor of the low-altitude explosion, The issue thus appears settled in favor of inedium- altitude 10Q-150m bursts, since the energy o� the neutron wazhead would have to be increased considerably to obtain effects analogous to those of high-altitude 300-400 m bursts. (21) Figure 5 refers to a warhead burst at a height of 100 m. The activation is plotted as a function of distance, /in terms of rel~tive values/ with respect to its value at ground zero, since its absolute values would depend on the composi- tion of the terrain: various natural terrains or terrains doped by irrigation with sodium carbonate. We note that activation drops to 1/10 of ~round zero width at 140 m f.rom ground zero, and to 1/100 at around 310 m. FOR OFFICIAL l1SE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 I FOR OFFICIAL USE ONLY i~~lr.nsilb rclative ~ d'activ~tion ~ ~ -~~1~ . U~J ~ ' ~ Key : ~ o~~ - 1. Relative imtensity of e,os activation. 2. Ground-zero width. o,oz 3. Distance from ground zero o,oo:; o,ooz 0,001 ' - 0 100 200 300 di^tance L..PJ. au P.Z. ~2~ Fig.S ~3~ A first objection to the concept seems to arise immediately. Sodium carbonate is a water-solubl.e substance.~22~ One might think, therefore, that if put in place during peacetime, it would be diluted rapidly by rain. In fact, if the quantity distributed is sufficient and if the t~rrain is not extremely impermeable, a sub- stantial fraction of the carbonate dissolved by rainwater will settle into the upper layers of the surface soil. The chances are, however, that little by little ~ it will be further diluted and carried down to such depth as will require new - distributions, the periodicity of which, to be determined by soil analys~s, must be evaluated in terms of months at least, and more probably in terms of years. We note, nevertheless, that the solubility of sodium carbonate constitutes a factor in its �avor for the proposed purpose. Actually, the cross section of Na-23 is 0.56 barn for thermal nputrons, that is, neutrons slowed to an energy level corresponding to the ambient temperature. But, for 14-MeV fusion-neutrons, this cross section is less than 0.001 barn. Consequently, if ::he Na2C03 remains at the surface, each sodium atom would have but an infinitesimally low probability of being activated: The neutrons would pass through the carbonate layer practi- cally without producing activata.on. (We will encounter this problem again with regard to the Dumbos). The soi~.'s water~content thermalizes the neutrons, thus tending to augment the cross section and to favor the process sought by the advocates of the defense system. Let us now examine the quantity of. radioactive so~ium that could be produced. FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 - FOR OFF[CIAL USE ONLY We ~now that a 1-kt ~usion reaction releases 1.42 x 1024 neutrons. I� each o� these neutrons were to activate one atom of Na-23, the mass of Na-24 produced would be 24 x 1.42 x 1024 ~~6.6 grams ~2~~ . 6.02 x 1023 This quantity might seem sm~24f but it repsesents an initial radioactivity of close to 50Q,000,000 curies . Actually, the quantity of P~a-24 created is much - less, for the following reasons: : --It may be assumed that the warhead includea a neutron reflector that directs the neutrons earthwards. We know that no perfect reflector exists. Nevertheless, if one can obtain that 70 or 80 percent of the neutrons bP well directed earthwards, this cause of loss of yield may be considered negligible in proportion to the others; --During their transit between the point of explosion and earth, a suwstantial number of neutrons is captured by the air (exp d/235 law), with emission of 6-MeV gamma rays that will not take part in the activation. This phenomenon was taken _ into acoount in plotting the curve of Figure 5. = Lastly, and abflve a11, the aodium is "diluted" among the ground's constituent substances. Generally speaking, it wi~l capture�only a very small propoxtion o� the neutrons: The vast majority of the latter will be absorbed by these natural components of the terrain, gince they are present in vastly greater proportion than the carbonate. ~ By way of example, let us suppose that sufficient sodium carbonate has been spread to ensure a concentration of 100 grams per m2 thro~~ghout the first 30 cm of soil (that is, 100 tons per kmz). � _ These 100 g of Na2C03 correspond to 43 g of sodium-23 (sole stable isotope). Now, - these same 30 cm of depth per m2, a volume of 0.3 m3 represent ~ mass of the order of 450 kg of earth, which is approximately 10,000 times the weight of sodium. Let us assume a clayey-type terrain (of the kaolin type). Its chemical formula will be very close to Si2A1205 (OH)4 (pure kaolinite). A simple calculation shows that this soil contains some 2,000 atoms o~ silicon and the same amount again of aluminum for each atom of sodium. It should now be taken into account that natural silicon is composed of several isotopes of which only one, Si-30, whose isotopic abundance is 3.1 percent, pro- duces a radioactive isotape, Si-3I, through neutronic irradiation. Based on the common-capture cxoss sections of the proportionate amounts of the different substances, it is clear that far each atom oE sodium Na-24 activated, 750 of A1-28 and 12 of Si-31 will also be activated. Moreover, 380 atoms of Si-28 and 6i-29 will absorb one neutron, but witk?out producing an activated subs-: stance.~25~ The question then arises: Will the activated aluminum and silicon add significant effects to those of the soc7ium? _ ~9 FOR OFEICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000300094401-8 FOR OFF[CIAL USE ONLY The period of activated aluminum (A1-28) is only 2.3 minutes, meaning it drops to 1/1,000 of its initial value in 23 minutes and to 1/1,000,000 in 46 minutes; it is therefore negligible. At each disintegration, A1-28 emits one 2.86-I4eV beta ray and one 1.78-MeV gamma ray. For silicon, the period of Si-31 is 2.7 hours. It emi*s a 1.48-MeV beta ray and a 1.26-MeV gamma ray, but, for the latter, only in the proportion of 0.07 per- cen t(7/ ~0,000) of the disintegrations. Now, emitted /in the soil/, the beta rays are absorbed by it, and only the ~~ery scarcely emi,tted gamma rays need ~be taken into account for the calculation of the irradiation o� troops crossing the acti- vated zone. Of course, the beta rays emitted by the sodium must also be disre- garded for this purpose. Thus, and a~ter some tens o� minutes, the dangerous radiations are the only gammas being emitted, in their relative initial r~tios of --2 for the sodium (2 gamm3s per disintegration) --and 12 x 0.07 _ 0.0084 for the silicon, 100 oc 240 times less for the silicon. Moreover, the periods of these two substances being respectively 15 houcs (Na-24) and 2.7 hours (Si-31), the very weak concen- tration of the latter diminishes rapidly. In sum, the irradiation of combatants crossing the zone unaer consideration will be owing essentially to the sodium-24 coming from its isotope 23 activated by the _ neu tzons. The values indicated above show that this would still be the case ii ` the quan tity of carbonate distributed over the terrain had been 100 times less than the one we assumed, that is, if it had been only 1 g per m2 (1 ton per km2). Kao lin-type clay is, however, far from being the only kind of terrain one is lik ely to encounter. One might well question whether the foregoing conclusions would still hold regardless of type of soil. Actually, rather than seek to examinE what the combiriation of sodium carbonate - with all the other imaginable types of terrain would produce--which would be a _ prodigious effort of painstaking scholarship--it is simpler to examine what the neu tronic bombardment of the principal components of the various soils would give. This examinatiAn is summarized in the tabulation that follows, in which: --we have.eliminated th~~:elements that: appear only rarely and solely in the foxm of traces--gold, titanium, tellurium, etc--which eLiminates the vast majority of the 92 natural elements, inso�ar as conGerns the soils found in Europe; --for each of the ~lements studied, we have included only the natural isotopes - which, by neutronic irradiation, produce a radioactive isotope; _ lp . FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000300094401-8 FOR OFF[CIAL USE ONLY --tihe indicated cross section is that relative to the thermal neutrons (0.025 eV~ (26) ~ --We have not includad elements such as hydrogen, oxygen, nitrogen, and carbon, either because their cross section is extremely small (0-16), or because their gamma emissiori is immediate (N-14), ~r because the isotope formed is not radioactive. ( ) ~ ( ' (4 ( I 6 nriies ~~�i�a ~S~'l~Cf7': i ~'i~ C72~3 j i~''.C~~fl ~ ~~lUl~' I ~CI'IO~~o I( ) ~ n;~:~irol clf:mrnt ; c�t!ir,aco ~~sotope du radio- I Enerc~io ~ �/o p.if ~ naturcl d~ ! form~3 isUtopo (h1ev.) d~:-inlb- ' I c~~turo i ~ (7) ~ yr~tion ~ i(barns} ; ~ I ~ (8) t 2~{ I i a_~ i 1.a~ ~ 1r.o t~~ I 100 �/o i 0,.`.6 ~ ~ia 14,~J5 h ?,7.�i ~ 1(10 11 ~ ~ i 11 ! ( j ~ -i - -26 ----~-----I--- ' 27 t I 12PAg 11,~ �/o i 0,05 I 1?.FAg 9,45 mn I~,015 I 3U --I----' -i - 27 ~ ' 'j %4 AI , 100 ~ i 0,?_ 1 ! AI I?,3 mn 1,78 ~ 100 13 j I I 13 ~ i ~ 3 J j ~ 31 - - ~ i ~ r:;i ~ 3.12 �io ~ 0.11 I Si I 7_,GS h i 12G ~ 0,07 1~. ~ ~ I 14 ~ --A~-----~-------i----- I---I---- f: i G,`.? �/n I 1 ' K ' 17.~i7 h ~ 1,51 i 1~ i`+ ~ ; ~ 1`~ ~ ~ i - i ~ - - - -j -q~ ~ I 4D ~ j 3.10 ~ Fl~ Ca i 0,1~35�r'n I 1,1 i Ga I 8,J mn i ^.~7'> I 1a ~p i 20 ~ ~ ~t.~r- ! SR i----- --I ~G i- ~---~,1~ i 7.,8 FO 0..~.1 �;o ( 0,9 j Pn 45j I i,i0 ~ 57 7.~, I ~ i?.6 ~ 1.2J I ~3 Key : ~ ~ l. Na+:ural isotope. 2. Percent in natural element. 3. Cross section (barns). 4. Radioisotape formed. 5. Period of radioisotope. 6. Gamma rays. 7. Energy (MeV), 8. Percent per disintegration. The above table easily explains why the induced activity is par~icularly higher in terrains that contain sodium, present either as a natural component o~ its rock~27~, or purposely. distributed, for example in the form ot carbonate as propcsed by the authors of the syster.i: ii FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000300094401-8 FOR OFFICIAL USE ONLY --magnesium has very little effect, owing to its low percentage o� isotope 2C~, its small cross section and short peri~d; -~~luminum has a very short period; --silicon-30 is present only in the proportion of 3 percent and produces a gamma ray only in 7 disintegrations per 1.0,000. --potassium-41 is present only in the praportion ~f 6.9 percent; less than 1 dis- integration in 5 produces a gamma ray; --isotope 48 of calcium is present anly to the extent of less than 0.2 percent and the period of the Ca-49 formed is very brief; --lastly, isotope 58 of iron represents only 0.3 percent of the element present and its period is relatively very long (radioactivity persistent, but weak). Gf course, there are elements in existence that, for this purpose, would yield an induced activity far superior to that obtainable trom sodium. Unfortunately, they are very rare substances in nature, whose prices are such as to preclude any . thought of using them. Gold, for example, would be far more "viable" than sodium. Its natural isotope, Au-197, is unique (100 percent isotopic abundance); its cross section is 100 barns; and it forms Au-198, whose period is 2.7 days, and which emits a 0.41-MeV gamma ray at every disinteqration. Although the choice of sodium carbonate thus seems justified, a question of ~ capi~al importance now arises: Ta what irradiation would troops crossing a zone in which this induced activity of sodium had been produced be subjected? The res- ponse to this ques~ion must enable an assessment of the /military value/ of the system being proposed by S.T.Cohen. With this in mind,. we return to the case of a terrain containing in its upper layers 100 g of sodium carbonate per m2, subjec- ted to the effects of a 1-kt fusion-neutron warhead exploded at a height of 100 m. We have assumed this warhead to be equipped with a re�lector and that the absorp- tion by the materials comprising the warhead is low, the overall assembly permit- ting SO percent of the neutrons formed to be directed to earth. Figure 6-- which is merely a transposition of Figure 5-- gives the initial dosage yield as a function of distance from ground zero. It will be noted that dosage yields are large in the immediate vicinity of ground zero, but over a very limited area. Calculation easily shows that personnel cir- culating on foot, at a speed of 4.5 km/hr and passing directly over ground zero, would receive a dosage of onZy 4.8 rads. In tanks, with a protection coefficient of 5 and at a speed of ~20 km/hr, the dosage received drops to less than 0.2 rads. These figures are valid immediately ~ollowing the activating explosion, but, let = us recall, they diminish by half 15 hours after the explosion, by three quarters 30 hours ~fter, etc. FOR OFF'~CIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 APPROVED FOR RELEASE: 2007/02/48: CIA-RDP82-44850R000300094401-8 ; FOR OFF[CIAL USE ONLY i ; ; ; ` ' ~:~.i~~,,~ ~o~ ; ~1~. Key: 1. Initial yield in rads/hr . ~ . 2. Ground zero. jn . ' 3. Distance from ground ' _ zero ~ o - , ~ - ~ \ 1 ~ . O,J ' 0,2 I-- r" 100 ^r,p 300 rn dis~;:ncr , (f'.7_.) ,ttt ('.7_. (2) ~3~ ~ /The dosages involved would thus be to low to interdict attacking forces, even on ; foot, from crossiny the activated zones/. A substantially higher level of radio- activity could be obtained, however, in two ways, since this radioactivity is ' practically proportional : i , --to the quantity of sodium present per m2; ~ i --to the energy of the neutron warhead used to produce the activation. Theoretically, the first way ia easy: We have p~esupposed a minimum net distribution within the soil ot 100 g o� sodium carbonate per m2, which, allowinq for the quantity washed away by rain, could represent an initial distribution of around 500 g per m2. A tenfold increase in the activity we have thus assumed could be obtained by an initial distribution of around 5 kg of carbonate per m2. But this would represent 5,000 tons per km2, meaning that if only 1/100 of the 25,000 , km2 of forti�ied zone must be activatable, 1,250,000 tons of sodium carbonate must ! be used; this represents works and expenditures on a considerable scale, and, as ~ we have said above, would have to be renewec~ periodically. A m~nimum net concen- ~ tration of some 100 g of carbonate per m2 theretore seems a reasonable value; It ; would require the distribution of 500,000 tons to prepare for the artificial i activation of 1/50 of the �orti�ied zone. The second way seems to offer greater possibilities upon tirst analysis. Actually, if instead o~ a 1-kt fusion wathead we had assumed warheads of 2, 5 or 10 kt, the , activations would have been twice, five times, or 10 times greater, respectively. Let us note, however, that explosion at a rigorously exact height ot 100 m cannot i I j 13 ~ I I i FOR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 APPR~VED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 FOR OFFICIAL USE ONLY be taken tor granted--�ar from itl And in the event that a malfunction in the detonation system were to set off the explosion at ground level or too closp to it, the phenomenon of nuclear fallout would be inevitable. Now, we know (cf. STRATEGIQUE No 4) that 1 kt of fusion energy involves blast energy corresponding to that of a 0.5-kt fission warhead--ignition by fission plus the blast energy of fusion. Thus, the fallout from a 1-kt �usion warhead, in a sheltered area, corresponds to that from a 0.5-kt fission bomb, and that from 2-, 5- and 10-kt fusion warheads to that �rom 1-, 2.5- and 5-kt ~ission bombs, levels that are far from being negligible.~28~ We will assume that it would not be reasonable to use activation warheads of tusio~x energy exceeding 5 kt at low altitudes of 100 m.~a9) _ Under these conditions, the ordinates of the curve of Figure 6 must be multiplied by 5, as well as the dosages we have calculated. These wauld become: --24 rads for foot troops; --1 rad for tank crews. These are still small dosages that are not likely to involve physiological ~rob- lems that would prevent these troops from accomplishing their mission. /In conclusion, the artificial activation of terrain by prior placement of sodium carbonate and the explosion of a neutron warhead at the opportune time appears to us to o�fer very little of military value/, and we feel we can say that it would be far more viable to use those c~arheads.against targets, that is, directly on concentrations of forces. - The Dumbo Me~hod As we have said, the system calls for irradiating sodium carbonate by means of a very-low-energy (0.1-kt fusion) fusion warhead, the whole being placed inside a reservoir whose dimensions and ability to withstand overpressures would ensure its tightness. The irradiated carbonate in water solution is then pumped up and ~ distributed over the surface of the zones to be interdicted. Its authors provide no detailed description of the proposed system. It is possible, however, on the basis of simple reasoning, to arrive at a rough approxi- - mation of its make-up. The first fact to be noted is that the probable /direct/ action of the fusion neutrons on the sodium would }~e very mild (a cross section of less than 1 milli- barn for neutrons at 14 MeV).~30~ I'rom a practical standpoint, it would appear necessary to surround the fusion warhead with a light vessel containing the sodium carbanate in a"comman" (light water) aqueous solution that would serve as a moderator to reduce the neutron energy level to the proper value. Th~ cross section then becomes 0.56 barn for the sodium; it remains small for the other subs~tances present: oxygen, hydrogen, carbon. ~ -14 ~'OR OFFICIAL USE ONLY APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 APPROVED FOR RELEASE: 2007/02/08: CIA-RDP82-00850R000300090001-8 ; FOR OFFICIAL USE ONLY Calculation--based on ~rnne simp2ifying assumptions--gives us, for the proportion of neutrons absorbed, as a function o~ the thickness of the sodium carbonate (saturatEd solution)~ the results shown in Figure 7. The curve reaches a maximum of a little over 60 percent at theoretically infinite thickness, but a practical maxim~n is reached at a thickness of the order of ]..5 m. �/o neulrons ~ absorb6s par Na 23 , Ke~: i00 ~1~ l. Percent neutrons absorbed by the Na-23. 2. Thickness of Na2C03 in 50 � s~% solution. o 0 10 20 30 ~10 ,0 GO 70 a0 90 100 crn (2) dpaisse~ir CO,NA, en solution The Dumbo system could then take a form somewhat like the one diaqramed in Figure S, in which, for the sake of clarity, components are not drawn to scale. _ - , , , j~.~~, ; ;~rr~l~i' , . . � ~ ,i'., , ' , ~ ~ : . . . . , . , . ,,..i., < ~ , ~ ~ I I . I~ i)tJi~A[iQ I - ( ~pii~re aci^r) ~ i.~ _ ~ ~ ~ , ~I , ~ Solution ca~i,nn,~~e ~la Key: ' ~ r~~~ '~(4~.Enc~in o,t I