SOVIET BLOC INTERNATIONAL GEOPHYSICAL YEAR INFORMATION

 F,,-Approved For Release 1999/09/08 : CIA-RDP82-00141 R0002001ROQQIga2-17 SOVIET DL,OC INTERNATIONJU, GEOPEIYSZCAL YEAR ZNFORMRJIION June 6, 1958 U. S. DEPARTMENT OF COMMERCE Office of Technical Services Washington 25, D. C. Published Weekly from February 14, 1958, to January 2, 1959 Subscription Price $10.00 for the Series Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 PLEASE NOTE This report presents unevaluated information on Soviet Bloc Internationa]. Geophysical Year activities selected from foreign-, language publications as indicated in parentheses. It is pub- lished as an aid to United. States Government research. SOVIET BLOC INTERNATIONAL GEOPHYSICAL YEAR INFORMATION Table of Contents I. Details on Sputnik III Page 1 Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 I. Di-Yl'AILS OPI SPUL'NIK ii:[ Intro(luc'. 1 on The V3 ivtty issue of Pravda devotas two full pages to a description Ot' Sputni.i in: and the experJ.mentrs which are being conducted by it. S.--pttrate sections are devoted to the "Satellite Orbit and Observation of Its Movement"; "S;)utntk III i qu:;.pmeiit"; "Study of the Ionosphere," includin "Measurement of the Concentration of Charged Particles;," "Inve-,tigation of the Co'~position of the ionosphere," and "Invcstlgation of Eler,trosta,t:i.c "Mcasu..?ement of the Earth's Ma.;;T:retic Field's; "Stu(Iy of Cosmic Rays;" "Inve,3tilJat:Lon of Corpuscular Radiation of the Sw d). "Measurement of Pressure and Den'.aity of The Atmosphere's; "Investiga- tion of MI rometeors "; and "Source, of Equipment Power Supply." The Pravda article is accompanied by a photograph showing an external v.it?w of Sputnik III and two schematic diagrams. One diagram, on pane 3, shows the external disposition of some of the scientific equipment carried by the satellite. (1) magnetometer, (2) photomuitipliers for register- in,~ corpuscular radiation of the Sun, (3) solax batteries, (4) instru- ment for registering photons in cosmic rays, (5) magnetic and ionization manometers, (6) ion traps, (j) electrostatic fluxmeters, (8) mass- spectrometer tube, (9) instrument for registering heavy nuclei in cosmic rays, (10) instrument for measuring the intensity of primary cosmic radiation, and (11) tr.ansduce...s for registration of micrometeors. The electronic units of scientific equipment, radio-measuring systems, the programing-timing device and the electrochemical power supplies, which are located inside the satellite body, are not shown in the schematic. The second diagram, on page 11, is a sketch of the satellite being separated from the carrier-rocket showing (1) the satellite, (2) the carrier-rocket, (3) the separating protective cone, and (1i) the shields being separated from the satellite. The following is the full text of the 18 May Pravda article. Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  `Chi- Ii,,ilrchim1 of the third Coviet artificial Earth satellite was ac- com;~ on 15 May 1.91;;3. Sputnik III was placed in orbit with the aid of cti ir~~r~rf'u1. rocl;et??carrier. When the rocket-carrier with the satellite 1h0&.l, /0,tc1Li.TlQd in the op!ei.fi,ed trajectory a flli;ht velocity of more than 6, OOO meta c:; pry r? second, the satellite was separated from the rocket- c,arv:an' by :ipec.l.al d,:?vicec and began to move in an elliptical orbit around tli,2 Enuring the separation of the satellite from the rocket carrier, the protective cone and protective shields were discarded. The rocket- c::. - ?:i ear w. i h -k'.hc protective shields and the protective cone move in an orbit close to the satellite orbit. Accnx?d:' ng to its specifications, Sputnik III by for surpasses the f.trs'; un Lficia l arch satellites. Thtt wei;rht of Sputnik III is equal to 1,327 kilograms, and the total vci 1i1; of the scientific and measuring equipment, together with power sup- plies rhich are mounted in the satellite, is 968 kilograms. The satellite has a form wYdch is approximate to a cone. The length of the satellite is ;.57 meters, and its largest diameter is 1.73 meters not con.3iderint; the protruding antennas. A large number of systems for conducting eotplex scientific experiments are installed in the satellite. The experiments Ohre intended basically for studying phenomena occurring in the upper L years of the atmosphere and the effect of cosmic factors on processes in the upper atmosphere. Sputnik III is eq ped with improved measuring radio engineering ap- r atu::, .prrn idling exact measurement of its orbital movement, and a radio te! l_emetc-~.ri. ';z, apparatus which continuously records the results of scientific mee.niir. emk,nts, "stores" them during the entire time of the sutellite's flight and then transmits them to Earth during the satellite's flight o?-;'nr ooeo.i,3 . stations situated in the t SR which receive the accumulated info::-nation. There is a programing device on the satellite which ensures automatic functioning of its scientific and ahes,si ring apparatus. This pf:oi,,rnaing device is made entirely of semiconductors. In addition, all measuring, scientific, and radio engineering devices-are made with the :ride usage of new s?fticonductor elefents. The total number of semiconduc- tor elements sin boArd the satellite is several thousand. The power supply of the apparatus is provided by the best improved electrochemical sources of cu:rrer?t and by sftdconductor silicon batteries which convert the energy of solar rays into electrical energy. The great weight of Sputnik III testifies to the high qualities of the rocket-carrier which carried it itito orbit. The weight of the Sputnik I was equal to 83.6 kilograms. The weight of scientific measur- ing equipment of Sputnik II was 508.3 kilograms. sputnik III weighs 1,327 kilograms. The total weight of equipment for scientific research and radiosmeasur.ing equipment, together with power supplies of Sputnik III, is 968 kilograms. CPYRGHT Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Al proved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 The continuous; increase i n Lh weight of' the s;o~ Let satellites testi- f' to th(r future r)oso.i Lil.i ties of ear rocket, engineer. intr. Already t,od'.ay, there i:; '_c possibility of launching a rocket into the cosmos be- yond t,lie HAT11 Lof the I':arLir'u gr.avitatIon. Lo that this would have sci.- rnt,ific signI.fIcance and would be a real stride in accomplishing inter- pl_ane',ary flights, it, is necessary that such a cosmic rocket is suf'f'iciently equipped wDAi scientific and measuring apparatus and, as a result of its launching, obtains new information on physical phenomena of the Universe arid on conditions of cosmic flight. The scientific equipment on Sputnik III makes it possible to study a wide circle of geophysical and physical problems. The structure of the ionosphere will be studied by means of observations of the propagation of radio waves which are emitted from the satellite by a high-powered radio transmitter. In this connection, an apparatus for direct measurement of the concentration of positive ions along the satellite orbit has been in- stalled. A special apparatus will permit the measurement of the natural electrical charge of the satellite and the electrostatic field in the layers of the atmosphere through which the satellite passes. Measurements of dens- ity and pressure in the upper layers of the atmosphere are being conducted. A mass spectrometer mounted in the satellite makes it possible to determine the spectra of ions which characterize the chemical composition of the at- mosphere. For studying the Earth's magnetic field at high altitudes, a self- orienting magnetometer which measures the full intensity of the magnetic field has been installed. A number of experiments are devoted to the study of various radiations falling to Earth and having an effect on important processes in the upper lavers of' the atmosphere. The study of cosmic rays in corpuscular radia- tion of the Sun is being conducted by the satellite. Registration of the intensity of cosmic rays, being conducted almost over the entire surface of the Earth, will. give new information on cosmic radiation and on the Earth's magnetic field at high altitudes. Experiments for determining the number of heavy nuclei in cosmic radiation are being conducted. Ex- periments in corpuscular radiation of the sun will throw a new light on the nature of the ionosphere, aurora, and other phenomena in the atmosphere. ''everal transducers will record micrometeor impacts. A new experiment on registering photons in the composition of cosmic radiation is very important and will make it possible to obtain information on short-wave electromagnetic radiation in the cosmos. This is the first experiment permitting the study of cosmic radiation absorbed by the atmo- ;,nhere and the first step in opening a new stage in astronomy -- study of :ienomcna in the universe according to short-wave radiation of luminary Bodies. A number of experiments have been set up for investigating flight onditions in cosmic space. Included in these experiments is the stud; of he heat regimen, in a satellite, orientation of a satellite in space, and Cher experiments. CPYRGHT Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  of ~c:ie~ct;Lf.Ti: :1.'n'vr~ :t 1tzatiou; on Spui?nik III charac- trr'L ea 1.!: ti., .:i p;c;ri,,z_tr;,e :ornnic A.cnt.Lf'i.c ._'';atiors. The creation of such a o", ail Ll,1 JrLTi'r?r~ ,:c h.,;._! . ~1 'Le rc: a_ a,-Ad the placement of so broad a uom'T~lr r of o: pcI1,:u--:'rUy; o:?. i`; ':f crl.rric: por r,:1'ble tharke to the fact that a sateiiL of large dLnetl, 1.0~'. , w,!-.a created. 1.'hc :.1t ~l.l_t.L:t?a;fy;:t?ory w'.l1 7,as over all. roints of the globe e.a. Thin increases even of ex )er7me'nt8 beLng co'adtcted by the satel- lite. Thy,: paramctc.)' of the aatellii,e's orbit were selected in a man- ner that. L^IG'.~._:: J/~I,~r:,,r';).';a.ee Gt"i.('. ,:0.1:ti;:,';1;, of Fc.Lentific investigations in the TnoFi Sp;;?,-,:1k 1II wa.; place.,] into a??. elliptical or3:,it with an apogee altLtw.t'3e the h:i.jh~~.~c i:oi.ct of the orbit from the s;arface of the Earth) of l" 880 k.lomet'e:, After iv:'L.roductioan :Lcto orbit, the satellite was ael;arat:'3 from the ruekob-carrier. The period of its rotation around the Earth at t'.t_e cegln7:ing of movement was 105.95 minutes. In a day, the satellite completes arou,v. d 14 orbital revolu:tiors. Later on, the rota- tion per.Lcd and the apogee altit,:.de of the orbit will gradually decrease be';aurye of decceleratio::L of the satellite in the upper layers of the atmos- phere.. An-;or. di.:lfz to preliminary estimates o the movement of Sputnik III in orbit will br lo::+ger than the movement of the first two Soviet Earth satellites. The plane of the ai?bit J,-I. .ncclined to the equatorial plane at a 650 angle. The :Imme:liately after placing the satellite in orbit, to or'-.it close to the satellite orbit at a rromparatively Dt . Icg the coure3e of time, the distance between the sEuGelt..," i;e acid the 'r Jeket?~cal?Y ter will be changed conatantly in con- -W-1-1h 'she di.ft'erent degree of its deeele,~ation In the atmosphere. The of c?eeelerat.ioo oc' ur because lifetime of the roc&et- carrier w:tl.l he le.s;~ thar, the., time of existence of the satellite. T1i:?.g dai;a e.cccwzmalated during launchings of the first Soviet arti- ficial sa.tc.Llites, the l'Lfecime: may be predicted exactly after processing or the f ir. s, c of mean :r?ements of the parameters of the orbit of Sputnik Ill. The movement of the Sputnik III in relation to the Earth is similar to the movement of the first Soviet artificial satellites. In the middle latitudes, each successive revolution over the Earth's rotation and the prece3s i.on of the orbit occurs approximately 1, 500 kilometers west of the CPYRGHT 4. - Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  I precedlctl rrevolution. The rate of precession of the orbit is around 14? d,Lily. Observations of satellite movement are conducted by radio engineer int.; and optical methods. The equipment and methods of observation have bue n sl-nificaritly improved for Sputnik III. The satellite Is equipped with several radio transmitting devices which make it possible to conduct nte.asurements of its coordinates during movement in orbit. These measure- ments are made by a series of specially created scientific stations equipped with a large number of radio engineering devices. Data on satellite coordinates, which are measured by radar equipment, are automatically recorded simultaneously with unified astronomical time. Then, these data are transmitted along special communication lines to the general coordination-computation center. In the coordination-computation center, measurement data, received from various stations, is automatically fed into high speed electronic computers, which perform joint processing and compute the basic parameters of the orbit. On the basis of these cal- culations, the future movement of the satellite is predicted, and its ephemerides are given. Such a complex of measuring equipment, which in- cludes a great number of electronic, radio engineering and other devices, ensures the measurement of satellite coordinates and the rapid determi- nation of the parameters of its orbit with an accuracy which exceeds by far the accuracy of measurements of the movement of the first satellites. Dosaaf [Volunteer Society for Cooperation With the Army, Air Force, and Navyl, clubs, radio direction-finding stations, and a large number of individual radio amateurs are taking part in radio observations of the satellite at the same time. A radio transmitter operating on a frequency of 20,005 megacycles and continuously transmitting radio signals in tele- graphic form with a duration of 150-300 milliseconds is installed on the satellite. The radiating power of the transmitter provides sure reception of its signals at great distances with the use of the usual amateur re- ceivers. Systematic recording of these signals, especially recording on magnetic tape, which is easily done by radio amateurs, will have great scientific significance. Radio observations of the movement of the satellite based on the use of the Doppler effect is of considerable interest. As the observa- tions of the first Soviet satellites demonstrated, this method is very effective and under conditions of good tying in of results of measurements to astronomical time, it will be possible to obtain precise data on satel- lite movement.. In the organization of optical observations of the movement of Sput- nik III, the experience obtained in observing the first satellites is also taken into consideration. The network of ground stations for optical observations has been expanded, and a number of foreign observation posts have been added to it. Photographic methods of observation have been significantly improved. CPYRGHT Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Approvea :Cite ..: e of in c_l.cctron-ot~tic;.~]. converter in photographing the catel- iLte in_1.l:cr, pouiil,ie a :Aharp photographic image at very great dis- t;:n n ',pre c;ia7. :I ur ere:; t, . Models of the apparatus for photographing with the use of the electron-optical converters were success- fu?.i.y In obs(:r?vution:; of Sputnik II, 'wl:~~1'I.1 _i1?12.I.Et1J1Si~1~.. ]pi,triii,, III In the full sense of the word is an automatic scientific stution is r cor.iv.)s. Its equipment and design are considerably more iinnrrt e :rL i can, t;al; i n2; i srto aecount the effect of the uatc' Ll i to (.,it th ,~ value of ion Current of the trap. The device nu1ceu i.L pc)rj;iLblce to rrt )a,rure the lcn cone errtra?i;lofts in the range front 10,000 L,I ''') ml.11 iCnt ioriu 'Lit it citb.Lc centimeter. 't'he metv:;urerncrj-t of 'che pors:iti.ve ion concentration makes it pos- s Lble for the .1.' L.rst time to obtain data about the full concentration of charged parti clefs in the ionosphere over vat ious geographical regions of the earth, for various altitudes, its well as its changes during the tran- si.tlons from the regi.oris illuminated by the Sun into the region of shade and vice versa. These data are rather important for understan:iing the processes of the interactiron of the Suit's radiation with the Earth's atmosphere. Cornpo.r.i.sso.ri of the measurements conducted in the region located below the so-called. main ion:Lzation maximum, which is located at an al- titude of 300 to 350 kilometers,,; with the reoidts of ground ionosphere stations has made it possible to draw a series of conclusions about the concentration of negative ions at such altitudes and about the ioniza- tion of the air caused by the motion of the satellite itself. It can be expected that the measured concentration of positive Ions will provide new data on the structure of the outer region of the ionosphere, which will. provide additional information about this region as previously obtained from rocket launchings and the first two artificial earth satellites. It can also be expected that the magnitudes of the ionosphere inhomogeneities will also be measured. 2. Investigation of the Composition of the Ionosphere The earth's atmosphere consists of a great variety of gases. Its composition at the earth's surface has been studied sufficiently well. The data on the composition of the upper layer of the atmosphere are at present rather contrathctory. One of the important gas char- acteristics entering the earth's atmosphere, as well as of all the exist- ing elements, is their atomic and molecular weight, which are expressed in empirical units, so-called atomic mass units. For the atomic mass unit, a value equal to 1/16 of the atomic weight of oxygen is taken. The molecular weight of oxygen, composed of two atoms, ins equal to 32. The atomic weight of nitrogen is 14, and the molecular weight is 28. Analyzing the molecular and atomic weights of various canpounds and mixtures, It is possible to straw conclusions about their chemical com- position. For the determination of atomic and molecular weights of el- ements and their compounds comprising a mixture, so-called mass- spectrometers are used. The mass-spectrometer installed on Sputnik III is intended for determination of mass spectrum. of the positive ions that exist in the earth's ionosphere. Knowing the mass number of the ions it is possible to draw conclusions about the chemical composition of the ionosphere. CPYRGHT Approved For Release 1999/09/08: CIA-RDP82-00141 R000200180001-3  Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 'I%(-- mn:r;;- ;1;_ c:tromc.tri e tube, the 3eIu :i.ng :!1(mieIrt of the instru- ment, to coruic c ted with its open-entrance aperture directly to Surround- ing space. it cc7ntainn a series of thin-4r_irc grid-electrodes placed at fixed dI3tances from each other. Behind the grids are collectors in the form of m..Aa1.l.ic plates 'rhtch collect ions entering the mass-:;pcctrometer tube after passing throuirh all the grids. The tube electrodes are fed various direct and alternating cur- rent voltages generated in the electronic unit of the mass-spectrometer. These voltages are selected in such a manner that only those ions can reach the collector which have passed the tube with optimum vector veloe- :tty. The ions passing the tube with vector velocity greater or smaller than the optimum, will not be admitted to the collector. The velocity with which the ions pass through the mass-spectrometer tube, are deter- mined, on one hand, by their mass and, on the other hand, by the accelerat- ing potential applied to certain grids of the tube. The accelerating potential periodically changes from zero to its maximum value. Therefore, the optimum velocity is imparted, alternately to the ions with various mass numbers. When the ions reach the collector, a current pulse is generated in its circuit which is amplified and is' transmitted by a radio telemetering system to Earth. Simultaneously, the accelerating potential, available at a given moment on the tube grids of the mass-spectrometer, is also transmitted. If the ionosphere has ions of only one mass, then the receiving stations will register one pulse of ion current for each cycle of change in accelerating potential. In case of a more complex composition of the ionosphere, two or more pulses are registered for each cycle. The ion mass number, correspond- ing to each pulse, can be determined by means of comparison of the mass spectrum records with the records of the mass-spectrometer accelerating potential. 3. Investigation of Electrostatic Fields As a result of a series of processes occurring in interplanetary space, as well as in the atmosphere, the earth, with its atmosphere as a whole, acquires a certain electrical charge. The electrical field caused by such a charge will act on the velocity and the direction of the charged particles traveling in interplanetary space. It can have an ef- fect on a number of geophysical phenomena (aurorae, etc). Data on the electrical fields in the upper atmosphere might greatly help in determin- ing the causes for the existence of the earth's negative charge and the positive charge of the atmosphere, which create between the earth and the ionosphere a potential difference of several thousand volts. CPYRGHT Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 Although a number of theories explaining the origin of aurora anal corpuscular flows allow for the existence of electrical fields in the upper layers of the atmosphere, the direct measurement or their in- direct determination has never been conducted. The fact remains that the favorable conducting layer of the ionosphere prevents the pentration of electrical fields into the lower layers of the atmosphere in the same manner that a giant metallic shield would do if it were substituted for the ionosphere. For the same reason, it is impossible to measure, with the aid of instruments located below the ionosphere, the electrical fields in interplanetary space. The measurement of the electrical fields with the aid of the satellites is complicated by the fact that any body in the upper layers of the atmosphere will acquire an electric charge, the field of which, if not taken into account, will add up with the measured field and will distort the measurements. This charge appears as a result of the inequality of electron and positive ion velocities entering the surface of the satellite, as well as the result of phenomena such as photoeffect, i.e., the ejection of electrons from the satellite surface by light and by other radiations. Use of satellites for studies of such characteristics of the ionosphere as the concentration of ions and their mass spectra requires accounting for such disturbances which the satellite brings to the sur- rounding space. Therefore, the measurement of the electric charge of the satellite, which causes the redistribution of the charged particles in its vicinity, is also desirable to improve the results of these experi- ments. On the other hand, the information on the electric charge in conjunction with the data on the ion concentration will make it possible in a number of cases to determine such a difficult-to-measure ionosphere characteristic as temperature. The equipment used on the satellite consists of two sensing electrostatic flux meters having co=On control circuits. It is made in the form of two transducers mounted symmetrically on the side sur- face of the satellite, and a unit with amplifiers. The essential part of each transducer is the measuring electrode, a ten-sector plate con- nected to the body of the satellite through a resistor. The surface of the plate becomes, in a way, the surface of the satellite. This plate is periodically shielded by another plate, a shield, which is rotated by an electric motor. Since the measuring plate is a part of the satel- lite surface when it is exposed, it contains some part of the satellite's charge, as well as the charge induced by the exterior electrostatic field. When this plate is covered by the shield, the charge is removed. CPYRGHT - 13 - Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 During the rotation of the shield, the charge from the measur- :Lng plate is periodically removed through the resistor forming an alternat- :Lng current potential across it which is proportional to the magnitude of the plate charge. This potential is amplified, rectified, and fed to the input of the radio telemetering system. This system of measurement makes it possible to determine the magnitude of the electrostatic field, and the use of two symmetrically placed transducers of the electrostatic flux meter makes it possible to determine not only the satellite's own charge, but also the exterior electrostatic field. During the operation of the apparatus, a special system of con- trol makes it possible to check the reliability and accuracy of measure- ments. Measurement of the Earth's Magnetic Field The action of the Earth's magnetic field is revealed both during observations of artificial indicators of the type of magnetic needles rotating coils, etc,, inserted in it, as well as during observations of a whole aeries of geophysical phenomena: deflections in the polar regions of charged particles emanating from the Sun, the deflection of cosmic rays, and the polarization of radio waves. The distribution of the magnetic field according to size and inten- sity was studied in enough detail only over the continents in the direct vicinity of the Earth's surface. These data were widely used in the prac- tice of prospecting for useful minerals, ship navigation, aeronavigation, etc. The nature of the Earth's magnetic field up to now is unknown. As a result of prolonged measurements of the intensity of the Earth's mag- netic field in special observatories, it was established that it changes with time. The most intensive changes of the magnetic field are called magnetic storms. Analysis of observations showed that the principal part of the Earth's magnetic field and its secular variations are caused by sources occurring inside the Earth. On the other hand, the chief sources of short period variations of the Earth'a magnetic field and magnetic disturbances are outside the Earth in the upper layers of the atmosphere. The magnetic field of the Earth in the first approximation coincides with the field of a magnetized globe or of a strong magnet, the distance between the poles of which is extremely small, and on which the north pole of this magnet is located in the southern hemisphere of the Earth, and the south vole in the northern hemisphere. The axis forms an angle CPYRGHT - 14 - Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 of 11.5 degrees i?r.th the ax!:; ()1' rc,tati.on ()i' the; Larth. This simple icp- rcr. cntation Is complicated by the locat on of f i.eldu of continental, re- ,.i_ona,l, and local anornaJJ.ec,. Aar exarnp.1c: of the first :i.s the ';act Siberian maLncttc anomaly, occupyiXIg a cono:i.derable .part of the continent. Sources of local magnetic anomalies, for example the Kursk, lie in the uppermost layer of the 'Earth's crust, lout these anomal:Leo quickly decrease with altitude. Contradictory opinions exist concerning the localization of continental. anomalies. Mathematical methods permit the calculation of the field at high altitudes if the distribution of the field near the surface is known. Observations on the intensity of cosmic rays at different latitudes gave definite information concerning the structure of the Earth's magnetic field at high altitudes. The most puzzling thing is that maps of the dt:atributl on of the magnetic field at high altitudes, according to ter- restrial magnotometr:Lc data and according to observations of cosmic rays, are not in agreement. Direct mea:urements of the intensity of the mag- netic field at high altitudes using magnetometers mounted in artificial earth satell:i.tes, permit shedding light on the cause of the observed dis- crepancy. The placement of a magnetometer in a satellite permits conducting a magnetic survey of the whole of the Earth in a short period of time. Quite exceptional possibilities for the investigation of the variable part of the magnetic field are presented. According to contemporary notions, magnetic perturbations are caused by strong currents flowing in the ionized layers of the atmosphere. Up to now, only one direct experiment was known, accomplished with the aid of a magnetometer installed in a rocket, which attested to the actual existence of such current systems. The satellite moving along its orbit will repeatedly cross the ions zed layers of the atmosphere. Thus, the existence of the current system can be noted according to jumps in the intensity of the magnetic field. Separation of the intensities of the field measured by a mag- netometer, frequently related to the supposed current system, can be ac- complished only by special methods of observation and processing of the data. According to the reason given, programs for the investigation of the spatial distribution of the Earth's permanent and variable magnetic fields cannot be fulfilled in one experiment. The principal problcrr of the experiment by the artificial earth satellite is the investigation of the spatial distribution of the perma- nent magnetic field of the Earth at the highest altitudes in comparison with the spatial distribution of lines of similar intensity of the magnetic field and lines of similar intensity of cosmic rays. CPYRGHT - 15 - Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 Measurement of the magnetic field with satellites Is connected with consLderable difficulties, which use determined by the fact that the lo- cation of the satellite relative to the vector of the Earth's magnetic field changes continuously. The magnetometer should possess high sensi- tivity over a large range of measurements. The influence of the magnetic arts of other Inboard equ.tpment is exerted on the transducers of the mag-rictometer. A magnetometer which eliminates these difficulties is installed on board the satellite. This magnetometer is an instrument, the measuring transducer of which is automatically oriented in the direction of the fall vector of the Earth's magnetic field in any orientation of the sat- ellite. The size of the magnetic field and its variations serve as a compensating current passing through a coil, mounted on a measuring trans- ducer, Ln such a direction that it fully compensates the spatial field of the earth occupied by the transducer. Two potentiometric transducers, installed at the junction of orienta- tion, makes it possible to determine the position of the satellite body relative to the Earth and the rate of rotation of the satellite around its own axis. CPYRGHT 16 Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 ~c;~c1y w~a_C;;~antl.c FirLy, Invor,i,.L~ tr t:Lon of cosrn:Lc radiation is making it possible to obtain in- f'oi~tt on he procC'.::ses concerned in the formation of particles in the depth, of outer space which possess very great energy. Moving about the un i ver e, these particles are acted on by the effect of the medium t-hrouich w iic'i Lituy pass. Effect on cosmic radiation is caused by processes occur- J.n,_r on the Sun and, in particular, by streams of corpuscles ejected from within he Sun.. The intensity of cosmic radiation changes under the c.ction of electrical and magnetic fields present in these flows. Changes in.. the composition of interplanetary medium surrounding the rr,rth also lead:, to change in the character of the movement of particles of cosmic rays iJh:ich originated in the furthermost regions of the universe and are moving t.n tiLe direction of the ar.~th- Sometimes powerful explosive proc- esscVs occur on the Sun, resulting in the appearance of cosmic rays. These prccesse: have been little studied so far, and their investigation is of grer.-tt i.rnpurtance . Ai, thth result of deflection of cosmic rays in the magnetic field of the Earth., only particles with energy greater than 14 million electronic volts can e tci; the equatorial regions of the i arth. Particles with very small energy can reach the high latitudes. Moving about its orbit, the satellite maker it possible to register cosmic radiation of different energy. The cosmic rays counter installed on the satellite will make it possi- ble to obtain information on the intensity variations and the enemy spec- truzn of cosmic radiation. Of particular significanec_ is the research on the smallest particles of ligi_t in the composition of cosmic rays, the photons. Photons possess- inF; considerable energyr, as the so-called. gamma rays, can reveal to us where ti,is radiation is generated better than any other component of cosmic radiation. Gz ma rays shou].d propagate themselves practically l:iilearil.y in univer:sul spc.c.c. Therefore., having detected in which direction the gam.1a rays :re moving, it is possible to designate where their source is located. 1r; cc~i rasa to this, particles of cosmic rays having electrical charges are tro:iL;]_y deflected. in the maLmeti c fields existing in the cosmos and lose their .initial. direction of movement. Ue',ect1orr of g"urana rays in the composition of cosmic radiation is con- nectoc'_ W.I.L. great difficu3_111-ies, and all the more so, since at present, it is not possible to predict the-'_r intensity. The satellite existing for a long tune outs le the '1,rth ? s atmosphere presents an unusual possibility for detecting this new component of cosmic rays. CPYRGHT -1j- Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 An in trumont Installed in the oa,tellitte makes it Possible for the C i ra t time to realize un experi;;torrttti. attempt to detect g;aminL -ray3 in the compos]tti.on of primary cosmic radiation. If this attempt is crowned frith ::,ucceso, then it will be possible to speak of a new method for I.nvestiga- tlon of the universe. It is knowli that about 70 percent of be pr:iuaLry flog of cosmic rays entering into the upper layers of the atmosphere concint of protons -- t1LJ :IurIleus of the ].J.t;lrtest clement, hydrogen. In addition to protons, there are also other nuclei of other elements in the primary flow of cos- mic rays . Nuclei of helium (alpha pLL:cticle ,) tare present in a quantity less than 20 percent and nuclei of heavier elements make up about one percent in all. Even though the nuunbcr of such particles is small, the energy which they bear consists of about 16 percent of the energy of the entire flow of cosmic rays. It is important to know the composition of the primary flow in more detail. Information on the composition of cosmic rags in particular is of considerable significance in r:tnswer to the problem as to how and where particles with such great energies are created. A considerable amount of information on the composition of primary cosmic rays has been obtained as the result of instruments carried into the stratosphere on sounding balloons. However, it was not possible to obtain a complete series, of clata of primary composition while conducting; measurements in tha stratosphere, as there is still a small layer of sub- stance which is always present above the instruments and changes the com- position of cosmic rays. Up to now, it is not kno4rn whether there is an observable number of nuclei heavier than the nucleus of iron in cosmic rays. Installation of an instrument for registration of nuclei of heavy elements will make it possible to reply to this important scientific question. The basic element of this instrument is a so-called Cherenkov particle counter. Operation of this counter is based on the use of Cherenkov radiation, which is formed in such a case when a chang=ed particle moves in a substance with a speed which exceeds the speed of lig=ht in that- medium. An important property of Cherenkov radiation is the fact that the in- tensity of the light flash which appears in the substance during the tran- sit of a particle through it is proportional to the square of the charge of the particle. Therefore, particles moving with a speed smaller than the speed of 1!F;ht in the substance do not radiate light. This property of Cherenkov radiation males it possible to use it for the registration of charged particles, determination of their charge, and the separation from the entire flow of particles of only those which possess sufficiently great speed. - 18 - UPYRGHT Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 The Cherenkov counter consists of a plexiglass cylinder-detector, to the end of which is attached a photoelectron multiplier. On passage of a cosmic ray particle with a speed of about 300,000 kilometers per second through the detector, Cherenkov radiation is formed in it. The rate of propagation of light in plexiglass is equal to approximately 200,000 kilometers per second and, therefore, has the necessary condition for forming Cherenkov radiation. The light which appeared -in the detector is received by the photo multiplier, which transforms -t.t into an electric signal and amplifies It to a value which is necessary for operation of the instrument. The instrument sorts all of the signals into two groups, corresponding to the passage of particles through the detector with a charge greater than 30 and those greater than 17. On each passage of a particle through the Cherenkov counter, a signal is given as to which group the entering nucleus belongs. Investigation of Corpuscular Radiation of the Sun Solar electromagnetic radiation includes the infrared, visible, ultraviolet, and X-ray regions of the spectrum. At times, an erruption of ionized gases consisting of electrons and ions from the Sun shoots into interplanetary space. According to the extent of emission from the Sun, part of the ions are neutralized, that is, transformed into ordinary atoms. The emission of these particles from the Sun has come to be called corpuscular radiation of the Sun. Together with the corpuscular streams, accompanying magnetic fields are given off. According to various estimates, the corpuscles have a speed, near the earth, on the order.of several thousand kilometers per second. During the passage of the corpuscular streams close to the earth, mag- netic disturbances develop, the most intensive of which are called magnetic storms. At the same time, aurorae occur. As the corpuscles penetrate the atmosphere, their ionization increases in the upper, as well as in the lower, layers. An increase in ionization in the lower more dense regions leads to a disturbance of radio communications, since an intensive absorption of radio waves occurs. Corpuscular outbreaks are accompanied by a disturbance in the thermal condition of the upper atmosphere. A majority of the solar corpuscles is composed of charged particles. Such corpuscles most often penetrate the atmosphere near the earth's geomagnetic poles, in the polar regions. Because of the curvature of the trajectory of movement in the magnetic fields, the charge particles also penetrate on the night side of the earth in the vicinity of the polar zones. Corpuscular invasion also occurs in the middle latitudes, but here it is less intensive.. Neutral corpuscles are free to penetrate at any place on the earth's surface. CPYRGHT - 19 - Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 LiCr,.rinL,.LIor, on ~:_spY.i::culeer radiation of the Sun io very poor, and little i.,3 knc. am of l t:3 nat!.ire and properties. Until very recently, -encral infor- in'.t ton on corpuscular radiation has been obtained from observations of the u.urorae . Artificial earth r.!tell.ites are an effective means of studying cor- pu::cular rud:iut.ion. The p:!'c;,ent time L especially favorable since this r,!.diat:i_on ha:i intensified TWCLLUse of the increase in solar activity. Two particle detectors are located in. Sputnik IIT_. These, indicators are fluorescent screens covered with aluminum foil of various thicknesses. In this manner, a rough classification is obtained of the corpuscles accord- in` to their penetration capabilities. In front of the fluorescent screens, diaphraL=s tare placed which re- strict the solid angle of capture of the corpuscle,. Because of the action of the corpuscles, the fluorescent screens glow; similar to the process in the picture tube of a television receiver of illumination of the screen by the electron beam. Radiation from the screen is received by a photoelectric multiplier tube. Its signal is "stored" by a special devi^e and is then transmitted to earth by a radiotelemetering system. With the help of this apparatus, it will be possible to obtain valua- ble material on the geogrsrh.i.^_, altitude, and diurnal distribution of cor- puscular streams. For investigating the direction of approach of the par- ticles, a rotation of the satellite is used. The Earth's mfa,imetic field is capable of repelling the charged particles and :forcing them to follow a pi.ral path along the lines of mogmetic force. The neutral particles may -travel along a straight trajectory. Such observations will provide addi- tional. (data f~r cletermining the nature of corpuscles. Together with the registration of corpuscular radiation of the Sun, the apparatu, makes it possible to obtain suppl.eme-ritary material on X-ray radiation which will also be recorded by the corpuscle indicators. This radiation may differ from corpuscitla,r radiation in its direction of approach and by the absence of repulsion. from the earth's atmosphere. In addition, it may be registered during the time of appearance since corpuscular radia- tion is propagated more slowly than electrornagmetic radiation. Measurement of Pressure and Density of the Atmosphere The study of how the pressure and density varies with altitude belongs to the number of most important geophysical investigations of the upper atmosphere. Knowing these two parameters. it is possible to determine the temperature of the atmosphere at high altitudes. Until. recently, this study was restricted to comparatively low alti- tudes and only high-altitude rockets made possible measurements of the pres- sure and density in the upper layers of the atmosphere. At an altitude of CPYRGHT Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 100 kilometers, the pressure and density are approximately 10 million times less than on the surface of the Earth. Higher than 100 kilometers, there are single rocket measurements which agree poorly with indirect data. The essential shortcoming of rocket measurements is their short duration and the fact that they are conducted only above 'Individual points of the Earth's surface. For geophysics, it it.. extremely important to have data on the density and pressure of the upper layers of the atmosphere at all longitudes and latitudes by taking measurements over a long period of time. The use of satellites makes possible more precise and expanded in:- formation concerning the structure of the atmosphere. The prolonged stay of an instrument at an altitude, and comparison of the results of the measurement from one revolution to another, permits detailed analysis of experimental data to be made and to exclude the possibility of ex- perimental error. Given a sufficiently accurate experiment, it will also be possible to estimate diurnal and latitudinal variations of the density and.pres- sure at altitudes at which the satellite is orbiting. Manometers y1-.ce;i on the outside of the satellite are coupled with a measuring apparatus inside the satellite. A magnetic manometer measures pressures on the satellite within the limits of l0-5 to lo-7 millimeters of iercury, and ionization manometers make measurements in the range of 10' to 10-9 millimeters of mercury. Investigation of Mtcrometeors It is known that tiny solids. particles, micrometeors, move about in interplanetary space. When they enter into the earth's atmosphere, they burn up. During this luminous occurrence, which can be observed with the naked eye or with the telescope, only relatively coarse particles are pro- duced. The very fine, and presumably very numerous, particles, which are only a few microns in diameter, produce such-a faint light that they can not be observed with optical instruments, nor with any other facilities of ground observation. By means of radar observations; it has been established that the micrometeors which plunge into the earth's atmosphere at a speed of 70 kilometers perc:second produce an ionization of the molecules of the air. Around the flying particles, charged particles, electrons, acid ions, form a trail which is observable by means of radar. Even this method, however, is not able to detect the very finest micrometeors. At present, these particles can be studied only with the aid of apparatus contained in rockets and, especially, in artificial Earth satellites. CPYRGHT Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 The study ci' L:1!.erpl.ani~tary matter is of great significance to the a:ct,rcnomer, the t;eoph.y's:i c.1 st. and the astronaut, and al.^o for the solution of prot:l_era of evolution and on in cif planetary systemr and for the c ari- ficat.ion of a number of Important quest,iono in regard to modern theories rJ c O~TflO _~Ony I t i s %Iso very important tc know accurately the average amount of me';eorlc mutter which fa11r- to the earth during a given irtterual of time. It is necessary to tzlce into account. the. influence of impacts of meteoric bodies on the out.r;r .hell of a rocket and an artificial satellite and also on tn,t.rament-c t urrted. on them (for. example., or. the e,urfac:e of optical i u~,tnun(snts, which may be turned from t ran@purent to opaque as a resul+ of rollisiona with micromet.eors), cn the active surface of solar batteries) Another thing to be taken into account i~ the danger of the collision of rwt.ificial Earth satellites, and e;-:pec:l.a.l1.y interplanetary rockets. with larger meteorites., Although the probability of such a collision is not great, -it does exist. and it is important to be able to estimate it accu- rately. Several methods mny be used to record the collisions of micrometeors with th,a outer shells of interplanetary rockets and artificial earth sat- ellites. One simple, and; at the some time. very sensitive, method is the use of piezoelectric transducers, which convert the mechanical energy of the collisions with particles into electrical energy. Th,~ ma.gnitude of the electrical impulse produced in such a. transmit- t1 n, ; element, depends on the velocity and mass of the impinging particles, and rl,unlUer of impulses is equal. to the number of particles which collide with the surface of the transducer. The electrical impulses c,:)min~; from the transducers are fed, to an electronic device which counts the .tmpu1res and. records their magnitudes n. Sources of Equipment Power Supply The power supply for, scientific and measuring instruments in Sputnik III is based on silver-zinc batteries and mercuric oxide elements. The various elements and batteries of this type developed by Soviet scientists have high specific electrical characteristics- per unit of weight, and volume and are suitable for use in the satellite. CPYRGHT Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 CPYRGHT In addition to the chemical batteries, Sputnik III also has a series of solar batteries. These batteries convert the energy of solar radiation r1:Li:'ectly Into electrical energy. Solar batteries consist of a series of elements, thin sheets of pure monocrystalline silicon, with predetermined electrical conductivity. Each of the silicon elements produces about 0.5 volt, and the coefficient of transformation of the solar energy amounts to 9-11 percent. The correct combination of elements provides the required voltage and current. The mounting of solar batteries on Sputnik III affords he possi- bility of a detailed investigation of its operation under the conditions of cosmic flight. The launching of the third Soviet artificial r',arth satellite is now evidence of the success of rocket engineering in the Soviet Union. The broad complex of mutually related investigations being undertaken by the satellite will make a great contribution to the development of science. The launching of Sputnik III is one of the most remarkable events of the IGY. The great size of the satellite and its high degree of automation brings Soviet science and engineering closer to the creation of space (Moscow, Pravda, 18 May 58, pp 3-4) - 23 - CPYRGHT Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 :Auv:ie is i'ub L:iL;h Compilation of omc I{~sults 01' Sputniks I and 1,1 full-page article in the 27 April Pravda presents a compilation of some ul' the rc~ults u1' tho rxp:rin:~n_s conducted by means of :sputniks I and II. The r'ollowin;, is a swruuury of the article. '1'hc launchinj's of ~putnil: I and II, on 4 October and 3 November, re- sj_p: ctiveiy, marked the beCinrrin' -; of man's penetration into cosmic space. such artificial rtellites open the way for the realization of a whole series of the most important scientific investigations. The study of the ionosphere and the mechanism of its formation, the effects of the Sun's radiation and cosmic rays on the Earth's atmosphere, the study of the density, temperature, and magnetic and electrostatic fields at high al- titudes, and many other problems are of great scientific and practical interest. The solution of these problems requires the conduct of direct ex- periments at altitudes of hundreds and thousands of kilometers above the surface of the Earth. The possibility of accomplishing such experiments appeared w*th tiie creation of artificial earth satellites which permit mal;irg the necessary scientific measurements at great altitudes over dif- ferent parts of the Earth's globe over long periods of time. 4llthou6h the value of sputniks for scientific observations had been known for a long time, their launching had remained an unsolved problem. The principle difficulty was the Duch of a rocket capable of imparting a spEreJ in _:h_? urder of 1.3,000 meters per second to them. It was only after the creation of the intercontinental ballistic mis s.Lles ill the Soviet Union thatthe launching of the first sputnik was real- ized. The ?xcellent qualities of design of this rocket enabled putting sputniks into orbit with heavy loads of scientific apparatus. `me weight o` the first Soviet artificial earth satellite was 83.6 kilograms, but the sc iontific and measuring apparatus with power packs in the second Soviet s,rtelli to weighed 50t"J . 3 kilograms . The launching of artificial earth satellites with such a large weight ut' apparatus makes it possible simultaneously to conduct a whole complex uf' scientific investigations which increases their scientific value. Only by launching such large artificial satellites can the problems of building cuut.Luuousiy operating cosmic laboratories and of making interplanetary flights be solved. CPYRGHT Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 CPYRGHT Cho first :soviet artificial earth catell.Lte was put into an orbit with a perigee of 225 kilometers and an apogee of 94'( kilometers; the with a perigee of 225 kilometers and an apogee of 1,6'(1 kilurneteru. 'Lhe initial orbital period of the first sputnik was 96.1'( rninute~., and. of Clio second, 103.75 minutes. During the artificial satellites' movement along the orbital altitudes mentioned above it was possible to conduct a number of experiments for the Ludy of the upper atmosphere (determining the density of the atmosphere, t:he study of the propagation of radio waves, etc.). On the other hand, at these altitudes the density of the atmosphere is low enough so that it does not distort measurements of the primary components of cosmic radiation, the spectrum of the short-wave radiation of the Sun, etc. Scientific problems also determined the selection of the orbit's angle of inclination to the Earth's equator, equal to approximately 65 degrees. The advantage of such an orbit is that during the sputnik's flight its Jcientific apparatus can conduct measurements over different latitudes. It should be noted that placing an artificial satellite into an orbit with a greater angle of inclination to the plane of the equator is a far more complex task than-'to place it into an orbit similar to an equatorial orbit. During the period of its existence from 4 October 1957 to 4 January 1958, the first Soviet satellite completed about 1,400 revolutions around the Earth. The second satellite, from 3 November to 14 April 1958, com- pleted about 2,370 revolutions. With the aid of the first Soviet artificial earth satellites the projected program of scientific investigations was successfully accomplished. Some of the preliminary results of these in- vestigations follow. On the whole, the material accumulated is very ex- tensive, and work on it continues. 1. Radio and Optical Observations of Artificial Earth Satellites Inasmuch as analysis of the change of the orbit of a satellite with time makes it possible to evaluate the density of the upper layers of the atmosphere, investigations of the motion of artificial satellites are very important. Orbital elements of such satellites can be determined by observations made by radiotechnical and optical methods. Among the radiotechnical methods used were radio position finding and the observation of the Doppler effect during reception of radio signals from the sputniks. During radio observati^n of the signals from the first and second Soviet sputniks the frequency of the radio signals received was measured. A special radio apparatus and recording chronograph were used for this purpose. - 25 - Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 t'ci l..l.;/ use' 1 r,rJ d~ t;~ rul i 11:1 wadt_~ show that the Doppler ot'fect can be cuccesr - th'! orbital p {t .'amfi~ters of sputniks. The value of t,ftL:; n;t. tho~d is itr s Lnlpl is 1 ty and the reliability of the apparatus. With ran .irlcrer,c^e In t,ht- fre(jucuncy of it transmitter and with the use of' a system all Lomntically m,~;c;;urint; the frugluency, the error of the method can be sub- ;I,fttlt;ially r?'dUCCU.. For it more accurate determination of the coordinates special photo- Modernized aerial pho'to- grrcr~hac thcuilolite (fotokl.nc teodol.lty) were used. t;ral,h.:rc survey cLLmeras for obtcainln,; photo ,raphs with the sputniks' trails were cued. Timing durln(; photography was done with the aid of a number of consecutive opening-, and closings of the shutter with the registration of the time of these operations by it photoelectric method. Thus a broken trail of the sputnik was obtained on the photograph. During the observations of the artificial earth satellites a method of photographing them using highly sensitive means was developed. Among tlicse, the use of an electronic optical converter showed special promise. Thu new method permits making observations for sputniks without using large optical systems. Thar; will graatly simplify the means of observations. Determination of Density of Atmosphere. The density and temperature of the air are the most importa!t; characteristics of the atmosphere. The determination of their principal altitudes down to the boundaries of the atmosphere is essential for under- stand:Ln+e a number of geophysical phenomena. :;von bet'ore the launching of the first artificial satellites the possibility of determining the temperature and density of the atmosphere from observations of their motion was noted. During their movement in the at- mosphere the sputniks meet resistance. The strength of the resistance is pruportiuna.1 to the density of the atmosphere. As a result of the braking action of the atmosphere there Is a gradual. reduction of the altitude of the orbit. This continues up to the time the sputnik enters the dense layers of the atmosphere and ceases to exist. The farther away from the Earth's surface, the quicker the density the atmosphere falls. Therefore, the force of the resistance in the different parts of the orbit is not equal. In an orbit of sufficient size, the main braking force is in the perigee. This reduces the height of the apogee at a quicker rate than that of the perigee. In its evolution, the r;atel].ite's orbit thus gradually approaches a circular form. CPYRGHT Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 On the basis at' a theoretical analysis of the results of the ob- sr:rvattona it was possible to determine the values of the evolution of the croits as the product of the atmospheric density times the square root of altitude of a homogeneous atmosphere at the perigee altitudes of 225- 22R kilometers of the first satellites. The value of the density was also calculated. As a result, it was found that values of the density obtained were 5-10 times greater than the values indicated for those heights in a number of studies of the atmosphere which were based on rocket measurements before the launching of the satellites. The Earth's atmosphere over different areas of its surface is not uniform. At one and the same altitude the density and temperature of the atmosphere change in relation to latitude and time of day. This relation- 3hip is connected with the irregular heating of the upper atmosphere by ultraviolet, Roentgen rays, and corpuscular radiation from the Sun. As a result of the fact that the gravitational field of the Earth is different from the central field, the orbits of the artificial earth satellites changed their location in space. Thus for the first Soviet satellites the angular distance of the perigee from the midday meridian chanced approximately by 4 degrees, and the latitude of the perigee changed by 0.35 degree per day. Inasmuch as the principal influence of the atmosphere occurs in the region of the orbit's perigee, the change of its location leads to a chance of the magnitude of the braking. This makes it possible to evaluate the magnitude of the latitudinal and diurnal changes of the state of the atmosphere. On the basis of the observations, calculations were made for deter- mining the density of the atmosphere, taking into account the changes in 'the location of the perigee of the orbit. The calculations showed that the product of the density times the square root of the altitude of a homo- Ucncous atmosphere increases during the transition from the night side of the atmosphere to the day side, and reaches its maximum value at midday. Analysis of the braking also revealed a decrease of this value during the transition from the more northern region of the atmosphere to the equatorial region. It should be noted that the values of density, calculated according to the results of observations of the first and second sputniks, are in good agreement with those of the rocket carrier of the first sputnik. On the basis of the data obtained it is possible to draw the con- clusion that the temperature at altitudes of about 225 kilometers is higher, than previousl, supposed on the basis theoretical considerations. CPYRGHT - 27 - Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 Tfl,, (llscc)vl~ry o[' the high temperature of the atmosphere poses for i.;eophyuicistn the prohlQin of the sources of energy and its great heat capacity. The ].1-lcnoown ''hard" ultraviolet and Roentgen raclia- tions of file ,;in would 'n:ar,lly be sufficient for this purpose. Now it is possible only to Corm di.f1'erent hypotheses on this question. For ext.tmple, it uun be suppo:;ed that, the upper atmosphere of the polar r'~giorts i:; intensely heated by corpuscular radiations from the "';un. The whole upper atmosphere ma;; be .dditionally heated either by in- i'raiound graves arriving from the troposphere or by electrical currents arising in 1.lre electrical coiiductinl; Ionized air as a result of its motion In the Earth's magnetic field. Further study of the upper atmosphere using rockets and arti- ficial earth satellites will make it possible to obtain a definitive answer to all these interesting; and important questions. 3. Results of Investif;ations of Ionosphere The observation of radio signals received from the first arti- ficial earth satellites provided new data on the outer part of the ionosphere, that is, that part lying above 300-400 kilometers. The ionosphere is the upper part of the atmosphere containing a considerable quantity of free, charged particles -- electrons and ions. During the passage of radiowaves through the ionospheric layers the phenomena of their reflection, partial and full absorption, and the distortion of the paths of their propagation occur. Therefore, radio methods are the most effective means of investigating the upper layers of the atmosphere. One of the principal parameters characterizing the state of the ionosphere is the magnitude of the electron concentration, that is, the content of free electrons per cubic centimeter. Up to now the electron concentration was measured from the lower ionospheric layers up to an altitude of 300-400 kilometers, where the electron concentration has a so-called principal maximum. These measurements were produced mainly by ground ionospheric stations, transmitting short impulse radio signals at different frequen- cies and receiving their reflection from the separate layers of the ionosphere. As a result of systematic measurements, it was established that the altitude of the principal maximum of the ionosphere and its electron concentration changed from day to night, from season to season, dwring the transition from north to south, and from east to west. The greatest, value of electron concentration in the middle latitudes reached 2-3 million electrons per cubic centimeter. It was found that from altitudes of 100- 110 kilometers up to altitudes of 300-1E00 kilometers, the electron con- centration becomes on the average 10-15 times as great. CPYRGHT Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 It, is extremely important to know how the electron concentration au ; r +,he tnai.n maximum, that is, in the outer part of the ionosphere, This is necessary in particular to understand the interaction o!' f-. he ultraviolet radiations of the Sun with the atmosphere and to study the conditions of radiowave propagation and other processes originating La the ionosphere. Certain information on the outer ionosphere can be obtained by the study of radio emanations from the Sun and the stars and of radio signals reflected from the Moon which are received on Earth. Otservations on the porpagation of radiowaves transmitted from sputniks at different altitudes is a new method of studying the outer ionosphere. In the reception of radio signals from the first artificial earth jatellites at a frequency of 40 megacycles, it was possible in a number of cases to observe, free from distortion, the "radiorise" (radiovoskhod) and "radios etting"(radiozakhod) of the sputnik and to note the exact time of each. In contrast to the optical "rising" or "setting" of the sputnik, which are characterized by rays of light traveling in a straight line from the sputnik to the observer, during the "radiorise" and "radiosetting" the radio beams are bent by the ionosphere. Because of this, the "radiosetting" comes later than the optical "setting" and, correspondingly, the "radiorise" outstrips the optical "rise." The difference in time between the optical "rise" and the "radio- rise" (or the optical "setting" and "radiosetting") makes it possible to determine the amount of distortion of the radio beams. Inasmuch as the bending of a radio beam in the ionosphere depends .n the variation of electron concentration with altitude, it is possible to establish a def- inite rule for the change in electron concentration and to theoretically calculate its value at different altitudes. Thus the effect of the lower layers of the ionosphere can be considered on the basis of direct measure- ments conducted by a network of ground stations. The data obtained as a result of the reception of the radio signals of the first artificial earth satellites make it possible to assume that the electron concentration in the outer ionosphere (over the principal maximum) decreases with altitude at a rate of from one fifth to one sixth of the rate at which it increases below the maxtmum. Thus in the altitudes from 100 to 300 kilometers the electron concentration increased to ten times as much in the period of observation in October, while at altitudes from 300-500 kilometers it decreased by half. It should be mentioned that a similar change was recorded during the launching of Soviet high-altitude rockets. In this experiment, the electron concentration at an altitude of "473 kilometers was one million electrons per cubic centimeter. CPYRGHT - 29 - Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 of ( . HCLc Ray:; i'or th, r_ i:;t,utiorl of cosmic radiation two Instruments were instLLliect In the :;ueoud :_;putnik which recorded the number of particles of this; rc.ldi-_lt-,i,)n. Dur:intp ills motion around the Earth the satellite flew at different distunct.s from Its surface. Therefore, the measuiement of cor;mic rays by a siaut.nik m:lkcro it, possible to show the relationship of the number oi' p.lrticle:; to the altitude. Processing of the data revealed that from th'-, rl:Inimum orbit altitude of 225 kilometer:, up to an altitude oi' 700 ki_Lorn_tr r: t,hc was a 40 percent increase in the intensity of cosmic rays. This increusc~ was dependent primarily or. the reduction of the screcnin action of the Earth with the increase of altitude, which makes it po:;c;ible for the cosmic rays to reach the instrument from a greater number or different directions. The Earth's magnetic field also pr?NJerits an ob.;tuele to thu fLu.11 of cosmic radiation on the Earth. The study of cosmic rays using instruments installed in satellites can also .;ho?~ the dependence of the intensity of cosmic rays on latitude and lon(,itude. `!.'his ur_lkes it possible to obtain new information on the Earth's magnetic field. Measurement of the magnetic field on the surface of the Earth makes it possible to form a representation of the nature of terrestrial mat-net:isrn and to predict what kind of magnetic field exists at greater distances from the Earth's surface. From this the expected distribution of the intensity of cosmic rays according to the Earth's surface can be calculated. In parti.c?alar it Ls possible to indicate the lines of constant intensity of cosmic rays (I',, Vi,_, meu:;urernent of cosmic rays made during flights of sputniks showed IAhat the lines of constant intensity obtained from the experiment and those calculated in theory are substantially different. This result is in agreement with the conclusions reached by the US physicist Simpson, who or, arize1 ,a 1arSe series of flights with high-altitude airplanes in equatorial re,,,-ions. They showed that the equator found with the aid of co;rrric_ r::y',: did not coincide ,iith the geomagnetic equator. Consequently, there is a considerable divergence between the characteristic:, of the Earth's magnetic field obtained on the one hand with the aid of' cosmic rays and on the other hand by the measurement of the rnarletic field on the surface of the Earth. This discrepancy can be explained by tact that the trajectory of the motion of cosmic rays is determined by the magnetic field Lt very high altitudes, :chile the direct measurements characterize the magnetic field near the surface of the Earth. resrr. c ray make it, pn!~::ibl.e to probe the Earth: s magnetic field at great di tanccc from the E;.Lrth as well as the systems of electrical currents in the upper atnoophere. G-P* RGHT Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 Observations of cosmic rays by the earth satellites made it pos- sible ulao to record the oscillations (variations) of the intensity of this radiation. These variations, obviously, are connected with the state of the interplanetary space near the Earth. One case of a sharp increase, 50 percent, of the number of particles of cosmic radiation was registered. On the other hand, ground stations, at this time, did not discover any substantial increase in the intensity of cosmic radiation. At present a detailed study of this occurrence is being conducted. It is possible that it was caused by the generation on the Sun of low-energy particles of cosmic rays (strongly absorbed by the Earth's atmosphere) or by the u-utnik hitting a stream of high-energy cosmic rays (connected with the corpuscular radiation of the Sun). Such a phenomenon had not been regis- tered before, since instruments for prolonged observations of cosmic rays were located only on the Earth's surface. Artificial earth satellites for the first time make it possible to fully investigate primary cosmic radia- tion. CPYRGHT Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 in the past dcC`6de Soviet uCient:Ls is performed a large number of b.Lolu,;ical ex er.iments in the tipper layers of the atmosphere. Animals have been carried in rockets to altitudes of several hundred kilometers for direct experimental study of the biolo;;i.caa effects present in conditions approach- in(, those in comic space f1i ;lit. However, only by means of a satellite was it possible to conduct a biol.o;,icral experiment under conditions that would be present- in a: t-tual space fi.i.17ht. Specifically, the satellite enabled a study of the effects on a living or;ranism of lung--dt ration weightlerssness, primary cosmic radiation, solar crnis. ions, and other factors.. Informatior, of great value was obtained from data on the medical- biolut_ri.cal investigations on Layka in the second artificial earth satellite. Of special interest were the behavior and condition of the dog during the most adverse stage of flight, from the biological viewpoint, which consisted of the launching and entrance into orbit. The acceleration produced during launching was many times greater than gravity, so that the apparent weight of the animal increased correspondingly with the magnitude of acceleration. The animal was so positioned in its cabin that acceleration acted in the direet:Lon from i is chest. to Lts back. From the biological. viewpoint, this .^ l-.1- r,ost-. satisfactory position for withstanrlii rig over:Loadinnr due to ac- celeration. Data during the flight indicated that the animal was able to oppose the apparent increase in weight only to a certain mag- nitude of acceleration. After this point the animal appeared to be compressed to the cabin floor, and any detectable motion was not registered. Decipherint., of :iau,a received from the satellite showed that imme- diately after launching the frequency of heart contractions was three times ,realer than initially. Analysis of the cardiograms showed no ill effects. A typical picture of increase in heartbeat (so-called sinus tachycardia) was obtained. Later, as the ucceier. ation not only per. sisted but increased, the frequency of heartbeat decreased. With tha increase in the apparent weight due to increased aceelera- motion of the thorax became more difficult. Recordings ion, the breathing t'rom telemetric signals showed that the breathing frequency of the animal ?.ra3 three or four times greater than the original when the satellite entered orbit . Analysis and comparison of data obtained with results of previous laboratory experiments permit an assertion that the animal quite satisfac- torily endured the flight from the start of the satellite until it entered into orbit. Changes noted in the physiological functions were due to the strong sudden effects of acceleration, noise, and vibration during this period. 32 - CPYRGHT Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 CPYRGHT CPYRGHT After the satellite entered :Lts orbit, the animal began to experi- ?jelr"ih Liessneos . As the thorax of the animal did not experience any :c re prenaure which had previously existed under acceleration, its frequency < i' bra r,l .Ln ; decreased. After a short riod of increased heart contractions, the :. luency of heartbeat began to decrease and approach normal. However, to prcri.od for t'ie heartbeat to reach noimal proved to be approximately three k,irnec lour;cr than the period in laborato y experiments when the animal was subjected t-.o (ie same accelerations as t?ose of the satellite. This was i>robo.hly because after the effect of ace leration in the grouxld tests the animal found itself in normal conditions whereas in the satellite the animi2 exp rLenced complete weightlessness. Du ing weightlessness the sensitive nervous centers of the animal which sig position of the body were not sr.rf- f'ici.ently affected by external irritants The slight effect produced was re- 3pJ nsible for the somewhat longer period that the breathing and blood circu- 1v,tiorl functions took to return to normaJ Normalization of these functions ahoo;o that the factors present during la ching and orbiting of the satellite obviously did not cause any substantial d lasting changes in the physiolog- :.ca-, *lmctions of the animal. Insurance of normal living conditions for the animal during its f1:L !.1t in the satellite could be provide only by means of a hermatically sealed cabin. Normal atmospheric pressu was maintained in the cabin. The o:cyt~en content was kept in the range f 20-40 percent, and the carbon dioxide content did not exceed one percerL. These percentages were main- tained by highly active chemical compoun which absorbed carbon and re- leaied oxynen and absorbed other harmful axes from the living processes, such as ammonia. Analysis of data obtai d showed that the content of o:c-Len dial not decrease and that the cabi maintained its pressure. No definite idea of the effect o cosmic radiation could be formed, since no obvious physiological effect was directly observed and it would lave been necessary to observe the animal for a long period of time after t`:e fli; ,h t . This will be accomplished in future flights. The positive re- arults of t.;:e experiment make it possible o continue and expand research a:Lrned at, ensuring the safety and health o man in cosmic flight. Study of the great wealth of maters from the first earth satellites In the experiments described in this article and other experiments performed on the first satellites in continuing. S bsequent launchings of satellites in the course of the IGY will permit an i crease in the number of important scientific experiments in cosmic space an a dee r understanding ',rocesses occurri (Moscow, P muds,, f nps ` CPYRGHT Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3  Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3 S1ec1;;?1 :.u11.o St.al;ion is Lcrcc_ I ' 31)1 Ln.Lk ITT Sit'nals CPYRGHT Tnmiedi atcl, on Llle announcement. of Lhe :Grin? of Sputnik III, the En- !:oepLnr -,:tort-wave radio sLation began scanning for the satellite's signals. 71Q sec>~rc l was Cac 1.1.1. Lc.l.ted b,r Lhe announcement by radio from Moscow that t-1110 sirrna13 from Spit Lni1: ITT aa.?c si.mi.:l.ar Lo the letter "L" in the Morse code. From 1324 hours until 1332 hours, these signals were clearly intercepted in ^nkoepin,;. The oi;;nrlts were found to have a frequency of 20.005-20.006 Mc. AL 1511 hours, Lhe s i.; ;na7_ z were heard again, this time for .11 minutes. The frojuency decreased by 1,000 cycles from L11e time they were first heard until the end. ^^ , heard from 1700 to 1719 hours 1847 to nii-n,-Os were also Lo 1903 hours. (Stockholm, Svenska Dagbla(let, 16 May 53) CPYR Sovie Ls to Exhibit- S_put.nik Models in Paris GHT CPYRGHT LSR w-111 '17lc Soviet anbru y in Paris has announced that the Academy of Sciences exhibit I;xposi ti.on which opens in Paris on 30 May. (Pa.:.-is, Le Monde, 17 May 58) CPYRGHT Rocket Mail Delivery to Polar Re~-;:ion Discussed Tile main portion of an unsigned Czeck newspaper article deals with the advantage; and possibilities of rocket mail in general terms. The final para- graph jives the following specific details. CPYRGHT Li 1.1ie event of an emer; ;cricy, polar expeditions would be able to obtain packa,,es sent by rocket. A two-stage roc'.-.et could be launched in Arkhangelsk with an initial speed of 6,500 kilometers per hour, later reaching a speed of 14,000 1,ilometers per hour and an altitude of 400 kilometers. Here the first s tr,.ge of L"ne rocl.et would drop aura; r and the rocket wol.ild be automatically ::h1ided to the North Pole with the aid of wings that would push themselves out. As t!-- roe-'::et lost sreel, it would lose altitude. Near its goad. when it would . r' n > hilopinters.. the mother shir, -i-rould meet it, it up, and cr>s r; i t to land . (Prague, Obrance Vlasti, 4 Apr 53 ) CPYRGHT 34 USGOW-DC-36451 Approved For Release 1999/09/08 : CIA-RDP82-00141 R000200180001-3