SCIENTIFIC ABSTRACT KAPLAN, S.A. - KAPLAN, S.I.

Introduction to Space (Cont.) SOV/1235 PART III. RELATIVISTIC GA$-DYNAMICS Ch. T. Relativistic Gas Dynamics Of An Ideal Gas 1. Basic thermodynamic relationships 2. Continuous motion of a gas *3. One-dimensional-inotions of a gas Ch. TI. Relativistic Magnetogaodynami .as Elements of relativistic magnetogaadynamics 5. One-dimensional notion of a conducting medium 6. Elements of the shock-wave theory Ch. III. Problems Of Motion Of A Medium In The Relativistic Camp '? Dispersion of a gas Sound waves References AVAILABLE: Library of Congress IS/nah Card 9/9 2-25-59 351 351 35T 363 376 3 6 3~ 396 410 410 421 424 --F q q aw 'p  AUTHORo Kaplang S*A~ SOY/115-58-1-2/50 TITLE: on the Planning of Measuring Laboratories for Linear Measure- ments (0 proyektirovanii izmeritellnykh laboratoriy dlya lineynykh izaaroniy) PERIODICALt lzmeriteltnaya tokhnika, 1958, Nr 1, Pp 5-7 (USSR) ABSTRACTs The article contains detailed information on the basic stand- ard layout for measurement laboratories of non-mass produo- tion machine-building plants, worked out by the Department of Measures and Measuring Devices of Vptistroydormash (former- ly the Ministry of Construction and Road Machine-Building). The information includes a building layout, a basic minimum list of required laboratory equipment, and a distribution plan for this equipment within the building. Equations to be used for estimating the required quantities of instruments and the number of workers are given. There are 2 tables and 1 diagram. I. Laboratories--Design 2. Laborttary equipment 3. Laboratories --Organization 4. lAboratories--Instrumentation 5. Mathematics Card 1/1  soV169-59-4-W68 - Translation frcini Referativnyy zhurnal, Geofizika, 1959, Nr 4, p 127 (USSR) AUTHOR% KaDlan.-S.A. TIME- Mwetio Gas Dynamlos_and the Problems of Cosmogony PERIODICALt V ab.i Vopr. koamogonil. Vol 6, Moscow, AS USSR, 1958, pp 238- 264 (Engl. Rea.) ABSTRACT: The basic principles and the general results obtained in the magnetic gas dynamics are discussedt 1) the existence of the 4idheslon" integral; 2) the description of the "entanglement" -and the "disentanglement" of the magnetic force lines; 3) the increase of the density of magnetic energy in gas dynamic shook waves; 4) the notion of the gas magnetic turbulence. Certain coamogonic hypotheses are discussed, in wh1ch the methods and results of magnetic gas dynamics are used to some degree: a) the hypothesis of the connection between spiral &me and the regular magnetic field; b) the hypothesis of the formation of terstellar gas clouds as individual vortices - nuclei of the Card 1/2 ~4nnterstellar magnetic turbulence; c) the hypothesis of the  KAPIAN, SA-. 'k .-- Miu-StIon of the motlez of artlfi~W earth sateUites and the control of observations, Astron. tair. no*189:1-3 P 158. (MIRA 11: 8) 1,Llvovelmys stantelys sablyndonly Iskumstv,-unop Sputniks Zoult, (ArtIfIcial satellites)  ,%~N, 8*A* Approximate, calculation of ephemerides and the determination Of orbits of artificial earth satellites. Astron.teir. mo.1920-6 NY 158. (KTU 11:10) 1,10yovelays stantelya nablyudenly Iskusetvannykh Sputnikov Zemli. (Artificial vatellitea)  KAPLM- 2. A. I 'Ibook Wsv" In Stoller InteriMs." raw to be submItted for the 9th Intl. Iftown Imp Belglan Inst. of Astropbystes., MOSS, Belgian" " julY l"9.  AV retsenzent; SANSOKMO, IY. David AllbertovIchl KAPLAML L.Top redo; YXI"OTA, Ye.A., t-51175,red, [IntervAl physical processoa in stars] FixichasIde protsessy vantri svead. Koskva, Gom,,Isd-vo fislko-notem.lit-ry, 1959. 543 p. (Astrophyslos) (NIRA 13t3)  UPLAN, S*A.; IiDGYINMMO. A.A. Clegvymenko, 0.0.1; PODSTRIGACH, T.S. (Pideti7bach, Togo] 42cuUtlox of gasomagnotle shook wave parameterse Ukroftso shur. 4 uo.4:436-W? JI-4 159o (XIU 13:4) 1. LIvovskly gosudaretvaur4y uMverattet lu.lv.]Pranko. (Shock waves)  30) AUTHORS% Klimiohin# I.A. SOV/33-36-2-21/27 TITLE% On the Correlation Between the Observed Differences of the Degree of Interstellar Polarization and the Angular Distance of the Corresponding Points on the Celestial Sphere PERIODICALs Astronomicheskiy zhurnal,1959,vol 36pNr 2,pp 370-371 (USSR) ABSTRACTs By evaluating the data of Hiltner Z-Ref 2-7 the authors ob- tain approximatively the relation 15 (P1 P2) 2 'Zi 5t2ac Og24 P where (PI - P2)- 2 Is the mean quadratic difference ok the de- grees of interstellar polarization (in per cents) in two points of the firmament, and or. the angular distance of these points from each other. It is reservedly conjectured that this cor- relation can be explained by thi turbulent character of the interstellar magnetic fields, Card 1/2  SOT/33-36-2-21/27 On the Correlation Between the observed Differences of the Degree of Inter- stellar Polarization and the Angular Distance of the Corresponding Points on the Celestial Sphere There are 2 references, I of which is Soviet, and I American. ASSOCIATION Lfvovskaya astronomicheskays. obaervatoriya (L'vov Astronomical Observatory) SUBXITUDs June 21 1958 Card 2/2  30),100) AUTHORS t 33-36-3-3/29 Kaplan,S.A., and Klimishin,I.A. SOV/ TITM Shook Waves in Stellar Envelopes PERIODICAL& Astronoxiobeekly zhurnal,1959,Vol 36,Nr 3,pp 410-421 (USSR) ABSTRAM The authors considor physical properties of stellar shock 4aves, the possibility of separation of the envelopes etc. The shock waves are assumed to by stationary, at the other hand, the inter- action with the radiation is considered. �1 contains the derivation of the formula for the Hugoniot-adiabatic curves and other general relations. Because of the complicatedness of the obtainAd system in the following paragraphs, the authors restrict themselves to especially interesting speoial cases. �2 is devoted to the so-called dotonation-recombination shock waves in a gas- radiation-mixture (these waves move due to the energy liberated during the recombination of ions in the wave front). The waves are described by the equations 2 #2-1) ' X' X4(6r -3r2 [3r2'(2-A,) + 6r2(P2-#j) + 8-3p, + + Lq!l 2] Card 1/3 p1_T2+1) + r2(r2+8-392) . 0  3 Shock Waves in Stellar Envelopes SOV/33-36--3-3/20, P2 x2+1 92 (r2+1)x2 v1 Tj_ 1_+ Ti r 71710Lx 2 2(x2+1) 1 r. ~+ 4~4-3e)2 ; 6'- 5/3 3A+24(1-P) The indices 1 and 2 denote the values before and after the passage of the wave. A - "g/P is the ratio of the gas pressure to the full pressure; q is the set of nascent energy, v is the gas velocity with respect to the front of the wave, 9 is the density. The system is solved by successive approximationg where the fact, ttat the detonation-recombination waves are weak, facilitates the solution. In �3 the conditions are found under which a separation of the outer part of the envelope of a red giant taking place with a small velocity is possible. An undisturbed separation of an envelope mass amounting ca. 10-3 * 10-5 solar masses is possible e.g. if the radius of the giant is 80 - 100 times greater than the solar radius, the mass of the giant nearly M equals the solar mass and its absolute magnitude is -4 .5 or Card 2/3 -5m-8. The velocity of the separating part is 50 km/seo, the  Shock Waves in Stellar Envelopes SOV/33-36-3-3/29 velocity of the shook wave 110 km/soc. The place of the separation lies naarly in the center of the radius. �4 treats the influenoe of radiative cooling on the parameters of a shook wave. It is stated that this influence is essential even at optical depths of "30 and that it leads to a 10 - 100-fold diminution of the temperature behind the wave. �5 is devoted to the properties of shook waves in a degenerated gas. There are 15 references# 12 of which are Soviet, I American# I English, and I German. ASSOCIATIONsL'vovskaya astronomicheakaya observatoriya (Llvov Astronomical Observatory) SUBMITTED: June 2, 1958 Card 3/3  24 (5)p 21 (7) AUTHOR: Kaplan# So A. 30V/56-36-6-44/66 TITLE: On the "Larmoron" Theory of the Plasma (0 *larmoronnoy* toorii plazzy) - - PERIODICAL: Zhurnal eksperimenW 'noy i toorstichookoy fisiki, 1959P V0136# Nr 6, pp 1927 - 1926 (USSR) ABSTRACT: The wide-spread use of introducing quasipartioles into the mod- ern quantum theory gave rise to the introduction of effective particle@ into the plasma theory. In this case they are calls& "larmorons"I they are effective particles with the magnetic mo- ment p# which are in the leading center of the Larmor motion of real partioles. p a av 2/2H (m is the particle mass and v - the X I velocity component which is perpendicular to H). The energy of the larzoron is equal'to the total energy of the real particle. Spitear, Belyayev et al, (Refs It2) already used the conception of larmorons, withoutg however# defining it so rigorously. The author of the present "Letter to the Editor" gives a number of equations, which represent the components of the progressive notion velocity of larsorons (the components U, T, W zhere w Card 1/2 is in the R directiong and u and v are perpendicular it) as  On the "Larmoron" Theory of the Plans& BOV/56-36-6-44/66 functions of the velocity components of the real particle*, the larzor frequency and larmoron life timeg and further also expressions for the total energy of the larmoronag the Telo- city distributiong the equation of motion and its solution, The results obtained are discussed. The author thanks A. Yo. Glaubernan for discusaing the subject. There are 2 Soviet ref- erences* ASSOCIATION: Livoyokiy gosudarstvonnyy universitet (L'vov State University) SUBMITTED: January 309 1959 Card 2/2  9 KAPLAN, S. A. (LIvav) "The Structure of a Shock Wave in Plasma." report presented at the Firot All-Union Congress on Theoretical and Applied Mechanics, Moscow) 27 Jan - 3 Feb 1960.  t. KAPLAN q Sa=ll Aronovich, doktor fis.-matem.nauk; CEMMIMM, V.I.. oty.red.; MMONXIKO# TN,,, red, [Now date an cosmic spoon; results of the Interwtional Geophyelcal Year] Navy% dounp a koemichaskon prostronstve; ltogl NGG. Kiev, 1960. 37 p. (Obshoh*stvo po raisprostranonliu politichiskikh I usuchalkh susall. Gor.50 no.16). (Cosmography) (KiRA 14:2)  KAPWI. S.A.; KLI14DYM)TA. A.I. Nquation oi thn notion of an artificial &%rth satellite In horisontal coordinates, Blul.staeoptnable-I.-Ak.sput*Zetg* noml: 10-12 160. (Mlu 13 15 ) 1. Llvovnk~Wa stantalya nab4udenly tak-unntvenvkh mputnIkm Z~011. (Lrtificial satellites)  J-fj0 "OV/- -3 AUTEORS., Kaplan, S. A., Kliml3hln, I. A., LLverv, V. N. TITT,d-',: A Theory of' LIght Scattering In a ModLurn With fi Moving Botindary PERIODICAL: AtitronomicheuMy zhurnal, 1950, Vol -T() Nr 1, PI) 9-15 (USSR) ABSTRACT: Card 1/11 When the motion of a gas under cosmical c-onditions Is considered, It Is frequently necessiry to take Into account Its interaction with radiation. Usually, the problem is studied by combining the equations of motion with the equations of radiative transfer; moreover, only the case of a steady boundary is considered, while actually the scattering occurs either bei:ore or after the light quantum passes through a moving boundary. Consequently, before any modern theory of lIght scattg_:r- Ing Is applied to hydrodynamic problems It I.; necessary to develop a theory of scatterIng In a medium with moving boundaries. ThUj is the problem of ths~, present authors. The following notations are used: k, the  A Theoi,y of Light Scattering In a Medium 7"000 With a Moving Boundary OV/33-)l 2/31 S Card 2/4 aboorption coefficient per atom; n, the number of particles In a unit volume; x, a geometric-al coordlnati~; 'r = knx, the optical depth; t1j, the average time a quantum Is In a state of absorption; t 2' the time spent by the quantum before two successive scatterlrigs. Th(~n T may also be written as T - X/ct 2 whern, c 1:3 the velocity of light. Two case3 are considered: t 1 > t 2,1 and t2 > t11 In the first case, let u = t/t 1 be a dimensionless time, v the velocity of the mo%ine, boundary, and p( T U~, the probability that a quanti-m of light absorbed at the depth 'r will leave the medium in time t. Then if P( T) Is the probability of a quantum leaving the medium at any time, %-.,e have: 00 on P P (111; Z (T):~- P (T. U) Uda; DP (.r. 11) 117(bi.  A Theory of Light Scattering in a Mediwn 78002 With a Moving Boundary SOV/33-37-~-2/31 This integral equation Is rewritten as: I e-T.1, 1- x 1 11 W) dil, + -2(T + (T T- CO e v 0 2 (1 + or p 0 - A-.,) k, Here Xis an.arbitrary constant. In the secondcam we haves JL P + p (v'- v It - t'j) and (t) - I I - k (I + r)] e-Al, k - V4 (1 -44 IX- (2 (20) Card 3/4  A Theory of Light Scattering In a MedILLM With a Moving Boundary ASSOCIATION: UBMITTED: 78002 SOV/33-37-1-2/31 Equations (16) and (20) give the solutions for the two cases. There are 5 Soviet references. Lvov Astronomical Observatory (Llvov,3kaya astronomiches- kaya observatorlya) JulY 1, 1959 Card 4/4  60829 3/033/60/037/02/006/013 1,5-,3 0 E032/E914 AUTHORS: Kaplan_._.S. A,j Klimishin, I.A. TITLE: Some Y6-tes -on-the Emission of Light under Cosmic Conditions PERIODICAL: Astronomicheskiy zhurnal', Vol 37, Nr 2, pp 281-283 (USSR) '%09 ABSTRACT: Ths'present authors have previously pointed out (Refs 1 and 2) that radiation, which is one of the basic properties of shook waves in cosmic conditions I has an important effect on the structure of a shook wave, its motion, and the possi- bility of its observation. The present paper reports two new resulto in the theory of interaction of shock waves with radiation under cosmic conditions. It is well-known that the gas behind the front of a shock wave is heated to a high temperature and this leads to a strong emissicn. of radiation by-the front itself. Part of this radiation is emitted in the directiori of motion and penetrates into the undisturbed region of the gas is absorbed, and heats the gas, before it is reached by 1he shock wave-front. The Cardl/5  80829 8/033/60/037/0.v/006/013 E032/3914 Some Notes on the Emission of Light under Cosmic Conditions heating of the gas before the front of a shook wave can be calculated us3ng the theory of light scattering in a medium with a moving boundary which was developed in Ref 5. In the one dimensional case, the intensity of radiation at an optical distance z, from the wave front is given by Eq (1), where r,-knx, v - Vkntl 9 k is the absorption coefficient per particle, n is the number of particles per cc, x is the distance from the wave front', V is the velocity of the wave front, X is the ratio of the scattering coefficient to the total absorption coefficient (i.e. the sum of the true absorption and scatter- ing coefficients) and t is the mean lifetime of a quantum in the absorbed state. iq (1) is subject to the conditions 11 - X1 4.1 -0-101 which correspond to strong shock waves under cosmic"conditions. The amount of radiant energy absorbed per unit volume and transformed into thermal Card2/5 energy is given by Eq (2). As the volume element in the gas moves towards the shook wave-front, the energy 41  80829 S/033/60/037/02/006/013 E032/E914 Some Notes on the Emission of Light under Cosmic Conditions accumulated in it is given by Eq (3). since dt/dx = --!/V. In a steady-state wave P and 1-h rei..A.1-a uaalter,,d. It then follows from Eq (~) Vthat the energy ,~ 4.8 given" by Eq (4), where t = 1/kne and is the meax, I-fetime of a quantum between iio scattering gvents. In -',-hl', first approximation one may put F --dT in accorden-e with sh the Stefan-Boltzmann law where T., is the temperRture on the front of the shook wave and is given by Tsh ~-RI16R where R is the gas constant. For 14 the approximate relation is card3/5 q1  80829 8/033/60/037/02/C%06/013 E032/E914 Some Notes on the Emission of Light under Gusmic Conditione 14 - exp(-hWh), where 17 is the mean frequency of scattered radiation. A solution of the energy, mass and momentum conservation equations, which are given by Bq (5) with E given by Eq (4), determines the detailed struct- ure of the heated region. It is however, at once clear that the width of the ~Pated region is approximately given by Eq (6). In stellar'atmospheres this quantity is small and is of the or-a-e-F-oT a few centimeters or meters. In the chromosphere the corona, or the interstellar gas the width of the heated region is considerably greater a maj become observable. Owing to the scattering of light'in the higher-lying layers the radiation of the snock wave will penetrate into the outer layers before the shook wave reaches the surface. As a result, the intensity of radiat- ion at the point of exit of the wave will begin to increase Card4/5 before the wave actually reaches this point. It is shown e  80829 8/033/60/037/02/006/013 E032/E914 Some Notes on the Emission of Light under Cosmic Conditions that although in the stellar and solar atmospheres the time during which this increase in intensity due to the penetration effect takes place is relatively small (of the order of a few seconds) in chromospheric flares it is considerably greater anA may be of the order of minutes or tens of minutes. There are 6 Soviet raferences. ASSOCIATION; Llvovskiy gosudarstvennyy universitet (L'vov State University) SUBMITTED: October 11, 1959. Card 5/5  Swhro MISE I DOM EEPLOTPATI03 Akadmdya nwk SSSR. AstrowmichaskLy sovet Byulleten tantaiy opticbeakogo nalblyWisniya iskaostrenaykh spatnikoy Zemll. Ill I no. I ( ) (Acamw of sciences of the USSR. Astronomical Council. billetin of the Stations for Optical Observation of Artificial Earth Satellites. No. 1 (11)) lJoscow, 1960. 22 p. 500 copies printed. Sponsoring Agencys Astronoulchaskil tow t AkAdazdi nauk SSSR. Rasp. Ed.: Ye. Z. Gindinj Ed.s D. Yo. Shchegoley; Secretary: O.A. Severnaya. PJLIIME-. This bulletin Is intended for scientists and engineers concerned vith optical tracking of artificial satellites. COMAM. This bulletin contains abaft articles an optical equlp=at, techniques, and results of obaervaticas of artificial earth sateM a. Also covered are the precision of satellite pb*tography and the equation# of motion of satellites. No personalities are mentioned. There am no references. Card 1/4  Aca&wj of Sciences (Cont.) SOV/5570 Wrkuohar V A. (Novosibirsk Artificial Satellite Observation 'Stit-r-0--n-Tt ProiZetive Cup for the Xirror of the AT-I Theodolite Map, B.A., an& D. Ye. Shchogolev. (Xaln Astronocdcal Observatory, Pulkovo]. On the ProcIslon of Standard Processing of Photographs of Artificial Sarth Satellites Upl-w B A., =4 A.I. Klimwskaya (L'Yov Artificial Satellite -;;fee-rVLM;-n'StatIon). On the Equation of Xotion of an Artificial Earth Satellite in Norlsontal. Coordinates Panalotar, L.A. (XaIn Antronoodcal Observatory). Observations of Artificial Earth Satellites in the Polish People a Reyablic Remdts of Photographic Observations of Artificial Earth Satellites% Dronkalla, V. Berlin-Babelaberg Observatory b A. laspikars eftaff Kesbers al Chaprina, A.I., and L of the Astroncedcal Council,.AS UWQ. Odessa Astronosdeal Observatory Card 3/4  S/033/60/037/03/017/027 1032/E514 AUTHORS: Kaplan, S.A. and Kurt, V.G. TITLE: On the Expansion of a Sodium Cloud in the Interstellar Space %4-e PERIODICAL: Astronomicheskiy zhurnal, 1960, Vol 37, Nr 3, PP 536-542 (USSR) ABSTRACT: Shklovskiy et al. (Refs I and 2) have described a method for the observation of the sodlum cloud ejected from the second Soviet cosmic rocket on September 13, 1959# The results obtained by this method were also reported. The present paper gives a quantitative doscrivtion of the expansion of the sodium cloud. It in shown that the expansion con be divided into two stages, namely, adiabatic expansion accompanied by a fall in the temperature and a free expansion during which the atoms preserve their thermal velocities corresponding to the temperature reached at the and of the adiabatic expansion, If one assumes spherical symmetry, then the expansion of the gas in described by Eq (3), wher e Card 1/4 in the free expansion stage the term ap/Or can be V/C  S/033/60/037/03/017/027 9032/Z514 On the Expansion of a Sodium Cloud in the Interstellar Space omitted. In the adiabatic stage the pressure gradient is also much smaller than the first two terms and the solution of Zq (3) is of the form given by Eq (4), where A in a constant and f(v) is an arbitrary function which in determined by the boundary and initial conditions. Certain hypothetical expressions for f(v) have been suggested by Stanyukovich (Ref 3). Under certain simplifying assumptions it can be shown that the relation between the velocity of adiabatic expansion a and the thermal velocity of the second stage c k are related by Zq (7) in the case of spherical symmetry and by Eq (8) in the came of cylindrical symmetry. Assuming a Maxwell distribution of velocities (Eq 9), it in shown that the density distribution in given by Zq (12). Fig 1 shown the theoretical density distribution in the free expansion stage for various values of a which in proportional to the ratio a/c k* Card 2/4 The dotted curve represents the density distribution /C  2/033/60/037/03/017/027 Z032/Z514 On the Expansion of a Sodium Cloud in the Interstellar Space when the adiabatic stage in absent. Fig 2 shows the theoretical distribution of surface brightness for similar values of a. These theoretical calculations are then compared with photographs obtained by Yesipov at Stalinabad with the aid of an image converter telescope. The observed distributiom of surface brightness at different instants of time are shown in Fig 3 (1 - 93 see, 2 - 103 see, 3 - 146 see, 4 - 178 see after ejection). The experimental data are also summarized in Table 1. According to these data a -, 1.63 km/sec and 1, - 0.87 ka/sece The correspond- ing theoretical value Ck = 0.90 km/sec if it in aasumed that a - 1.63 km/sec. It also follows that during the adiabatic stage the temperature falls by 350 to 6oo*. The observational material suggests the presence of an adiabatic stage. It in also possible that droplets of sodium are ejected fromoj~etevaporator, the dimensions of these droplets being I o 10-Z cme Card 3/4 In interstellar space these droplets will evaporate and  3/033/60/037/03/017/027 2032/9514 On the Expansion of a Sodium Cloud in the Interstellar Space form a new gas cloud which will expand with a lower velocity* The presence of such a secondary cloud may lead to a loam of definition of the central part of the main sodium cloud and to a slower fall off of the surface brightness. It is shown that this effect does not contributs appreciably to the outer structure of the main sodium cloud. Acknowledgment is made to Lo M. Lukhovitskaya for assistance in the numerical computations. There are 3 figures, I table and 4 references, 3 of which are Soviet and I Dutch. ASSOCIATION: Llvoyakaya astronomicheskaya observatoriya Goa. astronomicheskiy in-t imeni P. K. Shternberga (L'Yov Astronomical Observatory, State Astronomical IrGtitufe Imeni-Pa -&,- 5hternbergi SUBMITTED: January 16, 196o Card 4/4 V/C-'  S/033/60/037/005/005/024 2032/2514 AUTHORS: Kaplan, 3.A. and Sivers, V,N. TITLEi TX-e-Yenerol Problem of &ixht Scattering n a One- Dimensional Medium with a Moving Boundary PERIODICAL: Antronomicheakiy zhurnal, 1960, Vol-37, No.5, pp. 824-827 TEXT: in a previous paper (Rof.1 the authors investigated 1 the problem of the scattering of ligh n a one-dimensional medium 3 i with a moving boundary in the two spec al cases tl>> t and t2~~ t1' where t 1 in the lifetime of alight quantum in th2 absorbed state and t2 Is the mean lifetime' of the quantum between successive scatters. The present paper is concerned sftth the general solution of this problem and given a solution of the general equation for the probability that a scattered light quantum will leave the medium with a moving boundary for any values 0, t I and t 2~ As assumed before, the medium is taken ' to be one-dimensional and semi-infinite. The scattering is equally probable in both direztions and the probability of scattering is independent of the optizal depth. The derivation is not given and Card 1/2  S/033/60/037/005/005/024 9032/9514 The General Problem of Light Scattering in a One-Dimensional Medium with a Moving Boundary only the final formula* obtained are quoted. There are 2 Soviet references. ASSOCIATION: Llvovskaya astronomicheakaya observatoriya (L'voV Astronomical Observatory) SUBMITTED: January 22, 1960 Card 2/2  KAPIAN, Sammil Aronovich; KUIJKOV) G.S... red.; PLAKSHE, L.Yu*,q ~-re ~.- [Pbyslco of staral Fizika avezd. 'Hoakvaj, Goo. izd-vo fiziko- matem. lit-ry,, 1961. 151 p. (141U 15:2) (Co=ic pbYsics)  KAPLAN, S.A. 0:;-~ Effect of anisotr;:~pic conductivity in a maenetic field on the structure of a shcA ~' in nagnetic gas dyncmics. Zhur. ekep. i teor. fis. 38 no,ii952-233 Jan 160. (MIRA 14:9) 1. Llvovskiy sudaretvannyy univer8itet. rmagnetio fields) (Shock waves)  UnANs SA. OAptromon in the U.B.A.R.. forty ywa; colloot#4 U4101". leviewd by SA, . Astron.shur. 39 no.ltl7O- 171 Ja-F 162, (AstromW) (KMA 15t2)  KRAVTSOVo A.F.;_KAPLAN, SoA. Efficient oyeten for selecting identical seismic receiving units. Goofis. rasved. no.6s89-92 161. (MIRA 15:4) (Seismic prompecting-Equipment w-A supplies) -  :;/702/62/OOQ/009/001/002 1046/1246 AUTHO?: Uplan, j.A. TITLE: 'The dtornination of the optimal excitation jonditions of elastic vibrations SOMCI;: W:;H. Glavnoye upravIr-fiiye geologii i o~hrwW nedr. G*ofizicheakaya razvodka, no. 9, 1q,2o 28-36 73=1: Ahe conditions of excitation are assessed from the amplitudes of the reflected waves Cenerated in microneianotor7io-doing. This method cannot be used unless A) discon- tinuitie3 with hi& reflection corIfficients exist within the eeismogeological cross section, and b) the reflected bode waves are known to *require identical or similar excitation conditions. There are 3 fieurea. 0 CWM VI  - UnO, S.A. Theas7 of light soatterivi In a nowtsay.-state mwdi= Astron.zhur. 39 no*4&702,,-709 J1-Ag 162, (KWA 15:7) (ught'-soatterim)  .'---W-W,-S.A"-Aoktor fis.-mat, nauk, red.; KIRKO, I.M., doktor fiz.- mat. nauk. red.; STAMYUKOVICH., X.P... doktor fiz.--mat. nauk, red.; SHIROXOTp M.F.,, doktor fiz.-mt. nauk, red.; FPJJM- KAKMSK379 D.A., doktor fiz.-mat, nauk, red.; V1XGPJU4'OVICJ1,A., red.; UMMO., A.j. tekba. red. (Problems of magnetobydrodynamics and pla=u dyn=ics; reports) Voprosy magnitnoi gidrodinnmiki i diDamiki plawW; doklady. Hign, Izd-vo Akad. nauk Iatviiskoi SSR. Vol.2. 1962. 660 p. (MM 15:12) 1. Sovoshchaniye po teoreticheekoy i prikladnay magnitnoy gidro- dinamiko. 2d,, ligal 1960. (Magnotolwdrodynamica) (Plamaa (Ionized gases))  --S/124 3/000/003/007/065 34YD6308 D 2 -'Kt I TW mi ios; ~'n e~ 21 ___~ Us- s- Ound--Dy- Ej:s- Aquau -author D01- asseri- the ves the problem-of-thefidw past a body moving with AlfvenFs-velocity along the magnetic field. duce The basic equations',re- to Ozeen's Z-tranalit. 7 equation whose solution is well known. Energy dissipation due to vIBOOSity and finite electrical conduc- tion is determined. ~_Abstraaterls note: Complete tranalation-.2 Card 1/1  sA24/63/000/001/008/080 D234/008 AMMOR: 'hTLE: Simple waves and fomation of shock waves in stars PERIODICAL: Referativnyy zhurnal, Hekhanika, no. 1,1963, 12, abstract IB69 (Tairkulyar. Astron. observ.. L'vovsk. un-ta, 1962,-no. 37-38,.3-8) TUT: -The 'authar--investigates the problem of conversion of ".a simple travellind wave into a shock wave inside of a star., It is 'assumed that the wave is plane and that'the gravitational acceler- ation is constant' The time of formation of the shock wave, as well as'the orcssure oi this instant for isent'ropic and nonisentropie mo- tion are calculated. fAbstracter's note: Complete translation 7 Card VI 4L  MordVinov- .-4 1' d.  S/058,163/000/003/02EV104 A062/A101 AUTHMs.- KOY "0.- KorOUshin, V. M., iov 7' on n r#1 64atria aorAudtivity and diffusi i ittiviAto ohe-OOMP6641h. 0] AMU 6' 3, 19;~ -'~;4betitat"' 3113-~,;71 0 ..4 F or", z-V _~ ~" -m ~ rii no 110 2~1 T" Aho-coeffloiehU of difftsion eleetric-conductivity it! a relativistic-one-component plasma In the preseno of- electric and magnetic fields. Expressions for the components of the "four- dimensional velocity" of the particles are averaged, for the cases of parallel I and perpendicular-electric and magnetic fields, by means of the distribution function in the zero approximation. Transfer coefficient is obtained in the presence of an electric field and the gradient of concentration of the particle*',':- For a relativistic plasma, at a power exponent of the particle spect'rvm 2, the diffusion coefficient is Inversely proportional to the intensity of the i,!9. miasnetic field. t YU. Mordvinoir ~Abstvoter s notat Complete translation] ard I  Acennom mRs Ap4oo?673 3/0214/63/000/006/0053M59 AuTHoRS3 Kaplan, 3, A.1 0strow"s L. A. TITLEs Theory of shock ways fontation in chromosphere and Ocr0n& MOM Soln"hMV* damMe, no. 6, 3$63, 53-59 TOPIC TAGSs sacmAgtical theory# gowd wave,* sound velocity# magnotic force tubst energy dissipation,, shock ways, coronal shock waves supersonic flow# gas flow, coronas chromospherej, wave formation ABSTRAM The authors have examined the conditions for converting sound waves to shock waves in an inhomogensous atmosphere within a gravitational field. This consideration in associated with determination of magnetic turbulence. The authors describe the application of a method that permits investigation of conditions for converting sound waves to shock waves in any distribution of density and toWera- ture,, under conditions that the wave length of the sound is much lose than the equivalent, height and that oaf-excitation Is smalle The mothod has been discussed elsewhere by K. Yoo Gubkin (3b. NVokotoary prohlwr* matematiki, 1, mokhmikiP AN SSSR,p Novosibirsk, 1961, stre 69) &M 09 Be F~ (Zhe prikle mkh. i tokhe fisep Cmd 1/2  Accmuom xR, A&Mu nos 2# 15p 1961). The authors consider velocity of the gass the effect of gravity, and energy. flux* p~mu the relationship that shock waves form when the steepness of the sound-wave front approaches infini j they 0 oc~s (Qnd expressions f or the distance a sound wave must travel before ruptur t is,, befRre & shock wave is generated). This distance it found to be on the order of 107 cm, The distance a sour4 wave will travel bef6re half its energy is dissipated is on the order of 291W cm, It is concluded that a substantial part of the kinetic energy of the wave is dissipated in a very short distance as corfared with the dimensions of the chromosphere. It is possible that this circunstarxe explains the sharp rise in temperature at the inner boundary of the oorona, Further dissipation of energy $p_ ccurs in the corona, but this extends over a great distance,, and does not load to y a high temperature gradient@ Orige art, bast 30 foraulast AS=IATIONs Gorikovskly nauchno-issledavatel'sk1y raftofisicheskly institut (Gorkiy Scientific Research Radio PkWalos Institute) SUBKETT TED t 00 DAIS AGO 22Jan64 ZKOLS 00 SUB CMIs AS WO 1UW awe .02=1 006 Coed 2/2  UM MOMMATICE -K Mlm# Samil Ar w. chi PlIcellwArs Oblomm Borlsovich Interstellar medivis (Mashs"sdnan szv&)s, YAsoowg Pismtgisg 196)v 5.U pe illus,,, biblio, Errata'alip insertsO. 3.5c* copies printed. ,t6PId TAGSs Interstellar medim, interstoollar-gas.-Anterstellar br&ftmo 7 'interstellar dust, irterstonar imagnstio fleld, interstellar gas 4mmdoxv galaotic evolution, radio trumedesion -TABLE OF COMM labridgedle 'Forevord - 9 Ch. Is Interstellar h7drorn - 21 :Ch, II. Physical sUte of Interstellar gas 105 Ch. III, Interstellm dust Ch., IV, Interstellar magratio fields and radio tranudesion 277 Ch. V. rnterstellar gam drummics and evolution of the Interstellar *Wim 372 Appeadees - 480 Bibliograpby - 510 cwd-],/  AN4036%7 ;MB COM ?No A Bgmuxwaus 190003 Im mw WTI 2n ~O=s 261 AOQI 06AP94k  A~:CFS,SION Nil, AT5013792 wMA P6 f ALMIOR ~1714E- nwf! hiferohnoLirv rporti!IIII '01"ky. f ik:1 7 Int(qTlaneLany space. curnulauvf, ttno~-K %,av- ABSTRACT: This thre-c-part paper dcaIE; with 1) interst(flar radiition A~,hose ~roonQiiv iq -alculated using a method do-scribc-d I n n -:t or -i; t i - i - in , Z~ Pikol'nez, fvIc7.hzvozerkaya srF-rb, M Iv,, '01111gan (Ap .1 , 137 D62- 1/2 ---  T 01 ~: --l" k:Tt AT5013792 -essum iner-eas el"X4'aa~ -Oxxt of Be ed Oxe m~ in 15, of S. A.--'- _erae - i Kaplart, Ntezhzvo&itya-pkodinaiftiko~i.-M.- Flzma4ftg 10.181; arid 3) the trawfer of -radlau" -W symmetricarar -17-- `lhe- blim-i"oTyed- th*- kWec ispade,l pit Wt th6- ile ffrom.. the cmteer) as I/A In a e~ibsequent paper, these calcuUtions will be applied tD of Lck In ,he night glow spectrum. Orig. art. tw6 2.5 if-r-muias. 2 figurt-3. Card 2 -P  Y KAPLAN,,S.A.; ZAYISEV, V.V.1 KISLYAKOV, A.G.; KOPRIM, M.M.; TSZY7LIN, N.M. Fourth All-Union Conference on Radio Astronomy. Izv. vys. ucheb. zav.; radiofiz. 6 no.4t86l-" 163. (MM 16:12)  Spectrum of magnotohydrodynamic turbulent convection. A3tron. . zhurs 40 no.631047-1054 N-D 1639 (KRA 16:12) Lb Radiof'Azichaskiy institut Gortkovskogo gasudarstvennogo unl- voroitstao  KAPLM S A -, KATYUSHINA. V. V.; EM, V. G.; Okeasurements of scattered U. V. radi&tion (1216A and 1300A) in the upper atmosphere! (USSR) Report subsitted for the COSPAR Fifth International Space Science SMosjux, Florews, Italy, 8-20 May 190,  KAPLAN, S.A. Coments on 1. M. Knpylov's and V. r. Karpman's Tapers. Vopv kosm, 10s58-60 4,4- (MIRA 17110)  Ar4o15565 3/0089/64/016/002/0149/0150 ;AUTHOR: Zaytsevo V. V.; Kaplan, S. A. TITLE: Concerning the theory of the nonstItionary multiple Compton scattering of gamma photons ~.SOURCE: Atomnaya energiyas v& 16, no. 20 1964, 149-150 TOPIC TAGS: multiple Compton scattering,, 4mall angle, photon, gamma photon, Compton scattering ABSTRACT: This paper presents a simple solution of the problem of thel nonstationary scattering of gamma photons for small angles. The approximation* 7 T has been used.,,, The transfer equation is given for the photon flux for a plane unidirectional source of monochromatic gamma photons. A more detailed analysis for a point-source in a homogeneous medium -1/2 Cwd   KAPLAN, S.A.; KLIHISHIN, I.A. Methods of analysis of interstellar turbulence. Astron.zhur. 41 no.2t274-281 Mr-Ap 164. (MIRA 17:4) 1. Llvovskaya astronomicheskaya observatoriya i Radlofizicheskiy institut Gortkovsk9go gosudarstvannogo universiteta.  ACCESSION NR: AP~043953 S/0033/64/041/004/0652/0656 AUTHOR: May, E. A., Kaplan. S. A. TITLE: Cumulative shovk waves in interstellar space SOURCE: Astronomicheskiy zhurnal, v. 41, no. 4, 1964, 652-656 TOPIC TAGS: astrophysics, interstellar space, shock wave, cumulative shock wave, interstellar gas, globule, star, nebula, Stromgren zone ABSTRACT: Dense circular dust nebulae (globules) are frequently observed within H II qmission regions. As a result of the sharp temperature difference between the globule and the surrounding Ionized medium it to possible to expect its compression by a shock wave developing at the discontinuity. If the configuration of the globule is close to spher- ical the shock wave will have a cumulative character, that is, there will be focussing of the wave toward the center. If a dark nebula in a H Il zone is greatly elongated It Is also possible to have cylindrical cumulation. At the time of development of a type 0 star, causing the Ionization of a surrounding nebula, a StrlJmgren zone Is formed around it. If there are such dense fluctuations within the nebula that it cannot be penetrated by Ionizing radiation, the H II zone will "bond around" isuch formations. The time required for establishment of the StrUmgren zone is of the order of the time required for recombination Card 1/3  ACCESSION NR: AP4043953 of the Ionizing gas, that is, about 104 years at typical density values. Since the dimensions of globules are much less than the radius of a StrBmgrcn zone, the time required for establishment of more or less Identical temperature and pressure jumps along the entire surface of a globule is also correspondingly less. This pressure jump leads to a shock wave moving in the direction of lesser pressures, that Is, into the center of the globule. Ills pressure wave should be characterized by the gas pressure In the H 11 zone (temperature T and density/2 ) and the state of the gas in the globule. If the density distribution In go globule Is uJorm (j0, = const), the problem of movement of the shock wave can be cons' Idered by applying the biaory of similarity. lbo following example is considered. Temperature in the H Il region Is T = 10 OOOC, the gas temperature behind the shock wave front to T1= 1, 000CP 1A ti 111. The temperature In the globule in comparison with T2 is neglected. If is assumed t at P2 = 1/2 Po and Poo 10. Isothermal speed of sound in the H II zone is 7 13 km/sec. Applying I o 2 formulas cited in the text, the author obtains the following parameters of converging and -reflected waves for a spherical case; C,,d 2/3  ACCESSION NR: AP4043953 Density jump at front Us 2. 1G 10 Converging wave Gas velocity behind 0.24 0.67 Ditto V8 front Shock wave velocity 0.45 0.75 Ditto Density Uc 10 103 Attains center Gas velocity Vc 1.05 2.36 Ditto Density Ud 220 105 Reflected shock wave Shock wave velocity Ild 1.1 2.4 Ditto no real values of the parameters apparently lie somewhere between the values cited above. Similar results can be obtained for a cylindrical cumulative wave. Orig. .-rt.- has: 25 formulas. ASSOCIATION: Gosudarstvenny*y astronomicheskiy institut imeni P. X. Shternberga (State Astronomical Institute); Radlofizichosidy Institut Gorlkovskogo gosudarstvennogo universiteta (Radlophysics Institute of GurIldy State University) * I SUBMITTED: 22Jan64 ENCL: 00 SUB CODE: AA NO PLEF SOV: 004 OTHER: 002 Card 3/3  ---- ------ -------- t re-vu-I t S O-F - the -titto-er- ight -4 cat te r Urt-- tin, with movfng boundaries obtained aarli~ir bv the authors (Astronc.- -hurnel, 37, 9, 19S0; Ukrainpktv fizichv-~ ZhUrnal , V The stationary one-dinansiotial. motion of ;-n tOOAI Faf sv the emission flow F is consilercd, ;r , -n ~ " - ~ "i i t i ou n fnr conaervation of mesa, onargy, and momentum, under t tie a -z l~ kimp t !on r pri-4gitra and internal anarry vf the Ond i [4 fu r b c d -q  ACCESSION NRI AP4043954 itial v-eLoclty of the emission front, n w oo/v where o, is eoentiit,? of Elie flowing gas and a is the density of the noncitsturbed gts, ~ is ~~-P !mentro7ic exponent, 2 to an Ideal ;as constant, and uirth-- nolac- vlar Weight, On Lhe basis of light scattaiing Lheory, diffei-ential ttkionurw- b*h1n4--the--# hock- WAIVOL-f ran 0--9ft'4 "e &ertved. To detarmt-atr~ knowng T. and T-, expressions dertved eArlier fo- T anI F 'or eq behind and ahead of th- q, ~r~ wnv~- r lc-ur e-,uations in clerive-d fr~m P lt~t;lnre r o mrp I er 0 Rt 'R oh i of shock wbves in OtelLar enveiopvs. 11 9110vu Int" r 0 a I n t f. a ts e tA t s dRace immedi it. ' v ihead of aid hahlud i~:-, wave front are of the tome order, Or I a r t. h 11 o rv-u I a s 3 2~ I ; VIA F4,1171   FED /E,a (I ),,EViP V-E-E-C-4, ae- I i-4 - 41 F Ref. 0i. Aqtronomlya. Otdol'nvv A i A WHOM Kaplan, 5, A. n=: R e I a t--rvToTrc- 0 c't ve v L in tntergatdctlc gev ,CLIO SUMCK: Aqtreiv--t.9trktt TOPIC TAGS-.1-a9trcp-KlyTS-cff -shockijave, relativfstic qhock -wrave, I r lac t I c gas, fntergalactfc 9pace, synchretre(i radiatioi, ra-lt~~ vmjs-,,nr ot rhe fertiation of rEl VA L It iv I q! ;h inrpr~:,!lactfc pacp h-ia been deT ion,; t t -i t T I r,;1 rllne t P r QR ~yi-nEmuon radtatior cir A 3C273. 1. F. SUB CODE: AA DIM: 00 Card  o',"Iteletic tuAL~ of cirruit breakcnl;  KUr TITLE: Investig-s-Ati-o-n- in the upper e=apher-c-. 100TOCE, Kosmicheskiye issledovaniy&,-V- 3, Ar, 2, 1965, 237-243 .7 i~77 -adi o- n counter m- -t:ha mrer -~zd have UF ra4lation windowz tar ::.e  L 41818-065 1ACCESSION 14R. AP5009640 a- afre cfrcilft, tra"Ista---fzel d-c pu stc~r-,- - ~4 hag figuxes. '20 -3-235 NO P=F S) VIVF 1. 002 &TD PRZSS.  ACCESSION -NR: rool/002,/0251/0256 resonance rr-diati--.n theo". upper C~11 7cocorena, L sub Alpha radlPtIon, Din c r c hydrog-cr, distribution 1~6 r Fm no III t uUt that thte vq Z. ~T f-~r, pro1#14cim in h c theory or scaccermg WLr-n a.L1crwRv9f7 j:c3T.- of gi.iphic formu!7.e. nn v -MA Ifinim tn-ttits- case Is gCe~-t tO t-1E SEeir G1ffErLL-UtL1W1-. cal ta f ac, !--~dpr -PP! rh(? ejj_qtrtb-j-  L ACCESSII~N NR: APS009643 -rc-0, stricter con.%fderatiori Cif the gcuvatrly Of 'hc' 1 P rj r, t, p i A T I T art has: f 2 li rF, ;i n-,4 o rmu a F ENCL: X. tA OTIMR.. GG6  6,; IT NP. IP50019 04 S. A. Kurt V. G TI-MYE: t t% Interpretation of' 4eLjovjjtj6nj 0 It e 6T(i 13( _U triplet in the upper -3 j no It 2, 1765 256- -7 61 P T 'L~ T A(;.S :airelov intensity, light di6persion, Ibedo, integrril rAdiation. Doppler contour. Lorentz contour BZT, RAU!, - the, chenge of airglo%flintenalty with height# -11-je -JJ7~ale atmo4phere Is- -divided -Int +v- layers. Thc lover lever. extenis up to- o 0 c... Tn this lwrer the diffuerffteff In the lover layer the fL1t,A,i- ttir T-,, b I e p. nj! fror e r int c;,ur 3A I t i b' 1/2  Acci:SSION NR: AP500964h t- ehe cmputation "multa in giver, In tht! rirlgina r~. I Vt. r e t. h I ty occurs at 180 km. Orig. art. hap fLn'! ,MO~IATION: none summiwm 23jul64 ENCL: 00 SUB CODE: - e~ NO PIET GOV, 004 (YllMR.- 004 A-7D PRms. 3237 Crd 2/2  ~ ~ 4~.' ~ ~E V'S9 KAPLAN S A. Continuous malt method for the production of syntbetle nitron fibers. Biul. tekh.-ekon. inform. Goo. nauch.-isol. inst. nauch. i tekh. inform. 18 no.3:20-21 Hr 165. (MIRA 180)  KAHAN'~ S. It. ; 1'.S. Theciry of convection In a polytropic atmoslIPere with a uniform rragretic field. Astron. zhur. 42 no.l:'Ii,-?7 Ta-F 65. (1-11RA 18:2) 1. Radlofiztchenkiy inatit,"t krlkovskago gosudaratvennogo uni- veraiteta I Urallskiy gosudarstvennvy universitet.  ~N, ;,. ". ; MIRT, V.6. Theory of the rescnanie v(,qtt,.-rlng of I.C -rrd',a,,jct) the gto- corona. Kn8m.losl. 3 no,;i:251-2":c, Mr- 365. In Wrprt!tAti on of' obpwvat. I otm of t,):,. I -- [1-let I()] ( L -~ 301; ,,~~,; In jl,~.., ~ " fi ~ thF3 itijc-r atnnniht-re. Ibid. I . . ", I -  KMAN, 3.A*j LUPANOV# G.A* Relativistic instability of po3ytropic spheres. Astron,zhur, 4.2 no*28299-304 Xr-Ap 165. (MIRA 1814) 1. Gortkovskir nauchno-iealedovatellskI7 radiofizichesk'LY institut,  64T i URI Pod3trigach, T. 3. plazi -5 shock wavggj i.1 P.17-t-~n: 17 0- 70' innminhaskly zjiurnai, v. 4.2, nc-. The author3 inva!3ttgated t1to sysl~lm j1- i1 ho -,c- of tha shock wave front in the L7wn caries, and ullian thic 15 lArKa tlxl lota in =A- I- n n rin a tvu.3 2,~ ai %et-4 a um 1 1-0 Lh ~n t 5 i~  L 6-1-646-65 AX C E'S 3 11 Ql "I IN'R: A.P5015581 "Ina" I an o tho ,!ai 01- lGnIs Ofr d. XCj ti :2. no Ti -n to 'ri-t 006 OT FfER 000 ' '4$! 1 ZS ME  L 3430-60' EWT(l)/FCC/9WA(h) G~/R~ ACCESSION NRs AT5023572 UR/00O0/65/0O0/C00/MWMU V. G. AUTHORS: KaEMn, S, A-j Burt (Vol' TITIE: Scattering of radiation in the SMr atmosa!re of the earth (7besi sy SOURCE2 Vaeso7uznan konfsrents~ya-po fizike-kosmicheskogo prostrAmptva. MsooWA-i 19650 Issledazanfya kosmicheskogo prostranstva (Space research.); trudy lennf;rentaii. Muscow, Isd-vo Nsuka, 1965, 13.1-112 TOPIC TAGSt solar radiation scattering, solar rad3Ation absorption, upper ataos- phere, atmosphere model, optic thickness ABSTRACT.- The scAttering of 0 1 1300 R) radiation in the upper atmosphere of the earth is considered, using the double layer model or tho atmosphere a great optical thickness. Scattorirg or the incident solar radiation is assumed to take place in the upper layer without absorption. Absorption by molecular oxygon occurs in the lower layer where it is assumed that the albodo por unit scattorine e7ent of A increases linearly with increaning optical thickness The solution of the shift equation vpplied to this modol of the atmosphore indi;ates that tho intensity bogina to decreaea Bharply at an altitude of about 180 km, which agrees well with observations'4-Tho original article was published in the Cord 112,   L 04244-67, -EWTW_ GW ACC NRt AR6004672 SOURCE CODE: UR/0269/65/000/010/0042/0042 _2F AUTHORSt KapIgn, So A.; Petrukhinj No So TITIZi Interpretation of the 11supersonic" propagation of disturbances in the solar photosphere SOURCE: Ref, A, Astronomlys, Abs., 10,51,311 REP SOURCEt SolnechWo danrWyel, no. lot 1964(1965)p 63-a TOPIC TAGSs solar photosphoret'solar disturbancet solar magnetic field ABSTRACT: A theoretical interpretation is given of the phenomenon observed by Go Yaaasll~w on a solar magnetograph of GAO 20 July 1961. A sharp descent of gas with a velocity up to 2 )(Watic was observed in the region of a magnetic hill. with an intensity up to 100 o9 located far from sunspots. This descent occurred follow,' iTig some decrease of the magnetic hill intensity and lasted about 14. min, after whAch the gas began to ascend at half the velocity. The descent of gas began in the central part of the magnetic hill, then the front of the region be an to propagate aiang the surface of the sun to the east with a velocity of 50 k7sec and to the w~st-up to 280 km/seo. The authors assume that the phenomenon began with the down- ward drift of a m W etic force tube originally located at a fixed depth zo, because of,which a zone of variable disturbance originated in this region. Sonic dilatation Card- 1/2 UDCs 523.74 L 04244-67 'ACC INC AR6004672 0 waves began to propagate to all sides from this zone. The subsequent emergence to the surface of the waves emitted at various angles to the normal led to the observed "supersonic" propagation of the gas descent zone along the surface of the sm. A calculation of the propagation time of sonic dilatation waves to the surface Of the sun is carried out; the distance along the surface from the point above the source to the point of ray emergence is also calculated as a function of the angle cpo between the ray direction and the surface normal, It is assumed for the calculation that the solar atmosphere is polytropic and that the temperature gradient JB constant with depth, It is shown that for cpa, not too close to zero, the velocity of notion of the emergence point of sonic waves to the surface is clone to the velocity of sonic waves at th depth of the source. For a propagation velocity of the gas de- scent zone front :f 50 ka/sect the source depth so = 20 000 kme The greater mWi- tude of the disturbance propagation velocity to the west is explained on the basis of the assumption that the sonic wave source is not concentrated in a m13 volume at the depth zop-but extends at this depth in the latitudinal direction at a amll angle to the horizontal. Thereby it in assumed that the magnetic force tube before descent was almest horizontal for the most part and in-the region of the original =gnetio hi-11 abruptlv emerged at the surface. The sonic ways range time from the source to the surface along the shortest distance is close to the observed period of disturb- ance development (3-4 mi~~ which confirm the proposed interpretation. B. Ioshpa granslation of abstracy SUB COEE: 03 La~rrd 2/2 I-dd_ In the magnetic field. 'Die author thanks-Go A. semnovaya and No S. Petrukhin far help with the nunierical emputations, and Vo Vo Zhetesnyakov, who allowed the author to readh)s work before It was pub I hViRS001692iD has: I figure based on 4110ther's 90g0 Me I and 19 formless L t J. Card I I I I  ~A A SOme probIGMS affectIng the PhYflicO Of Interate1jar and 1ntej- planetary matter. Trudy Astrofiz. Inst. AN Kazakh. SSR 5:296- 301 165. 041RA 18: 6)  KAPLAN, S.As; PIKELINER, S-14. - W- The Interstellar and intergalactic media. Izv. Vt SSSP.Ser.fizo 29 no.10:1830-1837 0 165. (MIRA 18.10)  NEODCVIZIY, I.N., inzh.; ALITER, V.F., inzh.1 GUTNIK, V.N., inzh.; KAPLAN, S.B., inzh.; LESHCHINSKIY, I.Z.p inzh. Adjustment and the mastering of a high-speed, uniflow draving machine. Stall 23 no.12M28-1130 D 163. (MIRA 17t2) 1. Nauchno-inaledovatellskiy institut meti2noy pronWshlennosti i Magnito- gorskiy wtiano-metallurgicheekly zavod.  000 00 00 004 to 00.3" 000 4 004 to - ------------ JAL- to :00 00 .00 1 mill I F, NO V.A. Xmigam, ad ML L VA=xwA 4J. V* s 0 CAM 16 M-741)e4bft m I hello d calbob In Ali) *ML W-~h ;611 61~-Pl -'F QOW am 00na, Q to SO VWA.M Md( )A ~ggg -1-r, goo too $00 409 goo goo Soo goo grow INOW&MV moo see a 0 9 1 Nso I A 4 7 9 T 0 0 0 0 0 0 0 0 0 4 ISO o 00000000000000  o0 00 00 00 00 00 008 00 4 13 f. 411141-SLA WALLUNSICA& 1611"alli r- 0::::40:00000010000:00 V U a a 11 v J, a 4, 'u a a 0 -00 .00 -00 doom me "jam. ac '90 e dft d A. Killsw p V. N. d CA j M. 1333-4 w Il -00 m- Oak madw arm. pre*. P. d abil. ad (1) #*YNOC ~ see A' ia 7W - IM " elbrillft lU bY or 14.7 mols. -00 wAb ykiw li lot i * Go* s "w to Iml ft "=MW fit "I sm l4s : 96 a anorest of 40.1% J'v = - 16 U . %,. ft migivow iwl &ww. :1 m s e a ON&W. aw mo~- I a P'- e im"MiMAWN wkb pnwkw c"" -1rid. A age .A. 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"aw Amomlow pmql- 00 - ' V '-"go& 1"JI-11 A41 10 1" 'A"SNA4111 qmwAql $SIM 441 00 Pw-#4 pus, sit$vl 441 P# ILOW "Nis" a 01 Lien 4" -0#3 00 i -4 rJelf soml, I-op'- "ow Aq 'Poir - ool - I 00 VI am Otto mr.t I or jt&~Sjj No I pm A's U" P- a go- w ") 1314 p I APO mu ledpa AtS 0 sw )Nv 4 so 440 n as et- s" 10'4 .1 JR6 is onto J41 pa -"4"m 046 p"'Wom-a = 00 00. Pi-ml- ar)) $*am we AP044404 low"QuIP &11114WIMISIA 441 ' , , ' ' 1 0 l".4 .oh*., JA Ukw)AAw 411 " !f"ft a V 0 00- )L coir lot Vw rqwv -r . e4eviloomm"J" -0 -V OAMIMMIM.11 1 'amm" to 110110111,10 smft 'A - 041 00 IV " It w a of " a f a a 04 n t 1 t I a IN I i q of v a  got 004 "J 004 0.1 0 J : 000 sod T 'W-F- .1. ~17 - 1 ~11. ~741TMIIMA Im 0. ~U'F I., .Ott 4640 A" -0*-*# of-# ltab= oW ?rfl!=it "Aid. 0.379. Oct. 11, 1947. Tftb. joYramOmw is fliwiv"l to wAtef I I. lbes 241ted out by (4 an W-Wli 11 It, t am Nacl' -00 . 4 'see [see --** ..' Goo 7'ree C-00 .So* 9 -400 0060900000000000000-" alisil am ~wv all All a 9 0 ft 0 x 9 1 it a 9 A a 11 1 q oo*9000000000000* 00  KAPIANI S. I. Kavlan. S. I. and Robinovichs F, E.9 A diagram of fusibility of the system pyrauddon-water and the solubility of antipyrine in certain solvents. P. 1162. The solubility of antipyrine in dichloroethansp ethyl alcohol and water is studied in a temp. interval.140 to ?20. The diagram of fusibility of the system pyramidon-vater is studied. This system forwis a eutectic mixture cortainingp 1.0170 pyramidon irith melting temp. - 0.10. In this system the region of separation is established in a concentration interval from 211o to 637o of pyramidon at 72-5 - 730- The Orshoniiddso An-Union Scientific Research Inste of Chemical Pharmacy. March 180 1948. SOz Journal of Applied Chadstry (USM) 219 No. ll (1948)o  /t. dA mf I-fl !-~ %'J. 0- - 0 6t % / 7e ~ A % v a 9 - j I AV 6. dvop ~-G eadtow I - *V*6 a 0/44vas  so 0at 0 0 0 0*1* 0 W L I w A f) c 0 v 4 a a L a a a ! I No 04 CI a, t oil .0 m ktilts 96 oft vow" ox Aq p pMOW &WPPW Aq Adwp p-PW-we -1 ROO Amu ~wijxiad vp in ANP4jA 94 U P" tft4M 'AMAJIM son, 0, ) " Alill IP "p4mm -) pw*up Pw*- "POV 0 jj~v o1 f walaw A vul -N '(1051 *,% *(A*PNM I"-WJALAU * w :11. 0 too o Slott) POW110 pom rumm - tq _ t ul"Im "m I W4 PM 1 il of so. set. of r 00  --J -- LAPIAM, S. I o'f streptomycin from solutions by Using cation-ozebeaging -1.0~ compounds@ Pladeprome 12 no*2**24-31 F 158, (Mu 11:3) le Yde~oMoyy Muchno-iseledays tell ekty tastitut antibiottkove, (OlkwNTOIN) (low KCHAWM)