SCIENTIFIC ABSTRACT BAGARYATSKIY, B. A. - BAGARYATSKIY, Y. A.

/V AUTHOR: Bagaryatskiy, B.A. 49-4-18/23 TITLE: Certain data on the distribution of energy in the infrared spectrum of the Aurorae Borealio (NekotorNe dannyye o raspredelenii energii v infrakrasnom spektre Polyarnykh Giyaniy). PERIODICAL: Izvestiya Akademii Nauk SSSR, Seriya Geofizi3heskaya, 1957, No.4, pp.540-542 (USSR) ABSTRACT: The results are described of measurements of the relative intensities of infrared emissions in the 8000 to 10 000 range in two spectra of the Aurora Borealis which were obtained in March, 1956 by means of a diffraction spectro- graph for an exposure time of four hours. The calculation of the intensities was carried out for the band of the first negative nitrogen system, X = 3914 R and X = 4278 which were photographed simultaneously with second order infrared emissions. The aim of the measurements was to obtain approximate information on the intensity ratios. Therefore, as a photographic standard the spectrum of the Moon was used since during the period of the measurements the Lloon was full. The results are entered in a table, p.542 and in the graphs, Fig.l. The results permit a Card 1/2 rough evaluation of the integral intensity of the infrared  U [A K -S K AU!.r!HOR, Bagaryatskiy, B. A. 49-11-11/12 TITLE: Work of Soviet Scientists Relating to the Illumination of the Night Sky and the Aurora Borealis. (Raboty Sovetskikh uchenykh po ovetimosti nochnogo neba i Polyarnykh Siyaniy). PERIODICAL: Izvestiya Akademii Nauk SSSR, Seriya Geofizicheskayz, 1957, No.11, pp.1410-1417 (USSR) ABSTRACT: This is a very brief review of pre-war as well as post-war work in this field and the author limits himself predominant- ly to outlining the subject matter of the individual work concerned and giving the respective references. At the end of the review the author also mentions work relating to instrumentation in this field. A. I. Lebedinskiy, . . designed in 1948 the first photo-camera with a spherical mirror which was described in a paper in 1955 (Ref 116); at present improved versions of this camera (C-1806) are fitted in the stations of the Chief Directorate of the Hydrometeorological Services (Glavnogo Upravleniya GidrometsluzhbA of the Chief Directorate for the -Iqovthern Sea Passage (Glavnogo Upravleniya Severnogo Morskogo'puti) and other establishments which, from July 1, 1957 onwards, Card 1/2 coxried out work in accordance with the I.G.Y. programme.  49-11-11/.12 Work of. Soviet Scientists Relating to the Illumination of the Night Ski and the Aurora Borealis. The State Optical Institute (GoBudarstvennyy Opticheskiy Institut) is perfecting apparatus for spectroscopic investigations; they developed not only terrestrial spectrographs (Ref.117) but also diffraction spectrographs which are unique as regards dispersion and resolution abilit These spectrographs (Series cn -48, ch -49, ";~o cn-50 are beginning to be used for regular service in work scheduled for the International Geophysical Year. The author emphasizes the enormous organizational effort which was necessary for preparing the investigations scheduled for the I.G.Y.; observations on the emission of the upper atmosphere are carried out at individual stations and in a whole network of stations. The network encompasses in longitude the most interesting points relating to the Aurora Borealis, namely, from Murmansk up to the Mysa Shmidta and in the meridional direction from Murmansk down to astronomical observatories in the Card 2/2 South. There are 118 references, Ill of which are Slavic. ASSOCIATION: Ac.Sc. U.S.S.R. Institute of Physics of the Atmosphere. (Akademiya Nauk SSSR, Institut Fizikl Atmosfery). AVAILABLE: Library of Congress.  .BAGARYATSKIY, B.A. Ametion of the surorial proton disiribution on zenIth angles, .Astron, shur. 35 uo'3:493 NY-Je 158, ~(XIU- lIt6) ZL;0ras) (cosmic physics)  A4THOR- Bagaryatakiy, B. A. SOV/53-65-4-4/13 --------------- TITLE: Hydrogen Emission in the Spectra of the Polar Lights (Vodorod- naya emissiya v spektrakh polyarnykh siyaniy) PERIODICAL: Uspekhi fizicheskikh nauk, 1958, Vol 65, Nr 4, pp 631 - 664 (USSR) ABSTRACT: The discovery of the double displacement of the hydrogen lines in the spectra of the polar lights is a first class event for geophysics, heliophysics, and astronomy. It proves the presence of a corpuscular stream moving towards the earth which predominantly consists of electrorBand protons. The investigation of the spectra of the polar lights gives in- formation about the interaction of this corpuscular stream with the outer terrestrial atmosphere. In the present paper the author first discusses some spectrograms (Figs 1,2) and gives a comprehensive list of the known data on hydrogen lines from various observations of polar lights. Mainly non- Soviet sources are considered (Meinal(Meynel), Vegard, Petrie et al.) Among the Russian research Nvorkers above all the work and the experimental data by Gallperin (Murmansk, USSR, 1956/58) Card 1/3 and isayev (Murmansk, 1956) are discussed in great detail.  Hydrogen Emission in the Spectra of the Polar Lights SOV/53-65-4-4/13 Some results are as follows (velocities in km/sea): Gallperin 1956 H a 7A 300 40A 1850 51, 250 8R 350 431 1050 81' 350 0 400 451 2050 71 300 Gallperin 1957 Ha 9R 400 36R 1700 7R 300 H 6,5K 400 33R 2000 5R 300 HP 35 1 250 23R 1600 7R 500 1 The values of the first column concern the displacement of the maximum and the proton velocity in the maximum; the values of the second column concern the greatest widening in the violet part and the highest velocity of approximation; the values of the third column give the greatest widening in the red range and the highest withdrawal velocity. Further- more papers and results by I.S.Shklovskiy (in great detail), Pikellner, Mitra, Dzhordfto, Bagaryatskiy and Mustell are discussed. (all of them from the USSR). Finally the author expresses his opinion that in the plasma moving towards the earth not only protons and electrons but also helium Card 2/3 ions are to be found; the most important problem in new  llydrogen Emission in the Spectra of the Polar Lights SOV153-65-4-4113 research workAs to find He-lines in the spectrum of the polar lights. To this in a footnote is added that a helium resonance line was found (X - 10830 1) in the spectrum of the latitudinal aurora on February 10 - 11, 1958. The discovery was made by Mironov, Prokudina and Shefov at the Stantsiya Institute, fiziki atmosfery (Station of the Institute of Atmospheric Physics )(Ref 39). The station is situated at Zvenigorod. There are 22 figures, 5 tables, and 39 references, 11 of which are Soviet. Card 3/3  SOV/49-59-6-7/2-1 AUTHOR: Bagaryatskiyj B. A. TITILE: On. the Doppler Contours and Curves of the Distribiition of Luminosity of Hydrogen in Aurora Borealis 0 PERIODICAL: Izvestiya Akademii nauk SSSR, Seriya geofizicheskaya, 1959, Nr 6, pp 858-864 (USSR) ABSTRACT: A homogeneous atmosphere is considered, the top of iv"'-ich receives a stream of protons, having a velocity u 0 . The function N(Q, T) describes the stream at a point in space (G - angle of zenith, 9 - azimuth) i.e. it represents the number of protons falling on 1 c~~ durin- 1 see. The 0 U path of a proton in the airl so I is described by the normal conditions if the initial velocity is u 0 . Then the lower limit of proton penetration into the atmosDhere at 9 =;O is ~ 0 = S0 . If r =-s 0 - s is the distance to the end of the proton's path and u(r) - its velocity at a given point, then Eqs (1) and (2) are obtained. If the Card 1/3  SOV/49-59-6-7/21 On the Doppler Contours and Curves of the Distribution of Luminos- Auivra Bor a-is ity of Hydrogen in Z function Q*(r) Q(~, 9) is introduced, which represents the number of protons H., (or H, I H Y etc) then H a emitted by one proton can be calculated from Ea (a) for the vertical thickness and the stream of Protons on the horizon- tal level can be determined from Eq (b). The number of pro- tons in a given layer is calculated from Eq (3) and the dis- tribution of luminosity at height h from Eq (4). If the C~ argument r is considered instead of u . the formulae (5) to (?) can be derived and Eq (3) writte'n as Eq or the luminosity of emission defined from Eq (9). The protons in the trajectory can be considered as the source of emiss- ion. Then for y, 'Ol +-N" a;z~~ 10- cm (4) The coefficient oLl has been calculated theoretically by Bates (Ref 5) and its order of mai~nitude is not subject to doubt. The coefficient u~ could, upvto now, be estimated only very approxima ely, The alue of CX3 is consistent %Ath that given by Faire et al.. (Ref 7). In the first approximation the set of reactions given by EqS (1) to (4) is consiAered as a closed sys-11-em which sets up the ion balance. In this casel the equilibrium concen- tration of the ionic components may be written in the form given by Eqs (5) to (8), in which the concentration of the corresponding component is given in the square brackets and J is the rate of ionization at a given level in the atmosphere. For a given ionized component X the Card 2/5 quantity J can, in principle, be determ-1-ted from the Ll(  6 6 5 7 7 On the Effective Recombination Coefficient in the Ionosphere relation given by Ea (9), where cr is the effective photoion-ization crogs-section for pho-,~ons with energy h;v and S is the flux of these photons at the Si,.7e.n 11--vel in the atmosphere. In practice, all the t-hree in Eq (9) are not kno%-n sufficiently accurately and J is usually determined from ionos-Dheric data. The coefficient J describes the loss of electrons associated with pro- cesses (2)-(4). It should not be identified with the recombination coefficient. The quantity J is related to the effective recombination coefficien-~ lrxeff by Eq (10). The coefficient K is not proportional e and,, conse- uently, the effective recombination t.-I Ueff depends on ej . If in Eqs ( 54')-(8) J9 al 9 Lx2 -and cc~; are Imown, the r -maining quantities may be f6und, namely, the coeffi- C3 cient, K and the equilibrium concentrations of 0+, NO+ and e. The electron concentration Is given by Eq (11). Solution of Eq (11) gives the general equation for the electron concentration given by Ea (1-2). It d,s shown thaz the [N21 concentration is a parauidter which deterrnine3 the Card 3/5 L  66577 SO V/4 01 -5-9, - 91 -'7/2 5 On the Effective Recombination Coefficient in the ionosphere possible change in the character of the recombination with altitude. It is suggested that there is some doubt as to whether the set of reactions given by Eas (1)-(4) is cQppkete. It is further sug6ested that'-apparently it is n,ocessary to estimate the effect of at least the following processes; 1) photoionization Of N2 with subsequent very fast dissociative recombination of N~; 2) charge exchange of 0+ with N2, 02 and N respectively; 3) exchange reaction between * and 0 (analogous to reaction (3)); 4) formation of negative ions. Although reactions between 0 neutral components do not affect directly the ion balance, they must also be taken into accoul-it in the case when they lead to an appreciable change in the concentration of some of the components. Apparently, conlrective processes (Ref 8) also play an important role in setting up the ion balance in the F2-layer. 2mie aie 8 references, 2 of which Card 4/5 are Soviet and 6 English. ,r  6657? ... SOV/49-59-9-7/25 On the Effective Recombination Coefficient in the Ionosphere ASSOCIATION: Akademiya, nauk SSSR. Institut fiziki atmosfery (AS USSP,, Institute of Physics of the Atmosphere) V~ SUBMITTED: December 20, 1958 Card 5/5  30) AUTHORS: Bagaryatskiy,B.A., and Gallperin,Yu.I. SOV/33-36-1-28/31 TITLE: On Hydrogen Line Profiles in the Spectra of Aurorae PERIODICAL: Astronomicheskiy zhurnal, 1959,V01 -',6,Nr 1,pp 192-193 (USSR) A13STPACT: In the present short note the aathors compare their theoretical calculations with the averaged hydrogen emission profile observed in aurorae. There are 7 references, 3 of which are Soviet, and 4 American. ASSOCIATION:Institut fiziki atmosfery Akademii nauk SSSR (Institute of Atmospheric Physics of the AS USSR) SUBMITTED: September 12, 1958 Card 1/1  BAGARYATSKIY, B.A., kand.fixiko-matem.neuk. otv.red.; MIDSHTM. Ya.I., 1, Te.V.. tekhn.red. [Auroral investigations; oollection of articles] Iseledovaniia poli.Amykh silanil; sbornik statel. IT razdal programmy MG (pollarn.ve ellanlis i evachanis nochnogo nebal" Moskva& No*49 1960. 77 p. (KMA 14:1) 1. Akademiya zxauk SSSR. Mezbduvedometvennyy komitat po provedenlyn Mezhdunarodnogo geofisicheekogo gode. (Auroras) (Night sky)  20983 118111) (260S/ 2.7,DS) L~t, I / 6~~ S/058/61/000/004/038/042 9, ~.300 A001/A101 AUIHOR: Bagaryatskiy, B.A, TITIE: Some results of radar studies of auroras PERIODICAL: Referativnyy zhurnal. Fizika, no 4, 1961, 419, abstract 4Zh622 ("Spektr. elektrofotometr. i radiolokats. issled. polyarn. siyaniy i svecheniya noohnogo neba!', no 2-3, Moscow, AN SSSR, 196o, 7-14, Engl. summary) TEXT: This is a survey,of the present state of aurora radar studies. The principal problems of radio echo from aurora and physical nature of.aurora are briefly discussed. It is mentioned that av-rage distance of radio echoes amounts to 600 - 900 W;' this is explained by the --Aering effect of' the magnetic field on auroral ionization in the aurora zones. Directions of incidence of radio echoes correlate better with magnetiC field characteristics at the Earthts sur- face than with the geomagnetic field of the dipole located in the Earth's center. The course of excessive auroral ionization is the same in both Earth's hemispheres, Diurnal course of radio echoes is such that very few daily echoes are observed in Card 1/2  20983 Some result$ of radar studies of auroras S/Q58/61/000/004/038/042 A001/A101 comparison with the nightly ones. There is an unquestionable general correlation between visual auroras and radio echoes, but no particular Identification was ob- served. Radio echoes originate from the great number of Ionized non-homogeneities whose dimensions are comparable with the wavelength. It is pointed out that not all observed phenomena can be at present explained, and that th%ere is as yet no complete theoty of radio echoes from aurora, There are 40 references. V, Naslednik [Abstracter's note: Complete translation.] Card 2/2  BAGARYATSKIY D kand. fiz..-matem.nank. otv. red.! FELIDSHTMI Yaj., *A. ~e .; a-UT, V.G., to-khn. red. [Auroras and airglowl Poliarriye siianiia i svechenie nochnogo neba; sborna, statei. IV razdel programay MGG. Moskva, Izd-vo Akad.nak SSSR. No.7. 1961. 88 p. (MM 14:12) 1. Akademiya naulk SSSR. Mezbduvedomstvemnyy komitet po provedeniyu Mezhdunarodnogo geofizichenkogo goda. (AuroTas)  SIY SHA I V.I.Ltranslator); BAGARYATSKIY, B..A., red.; RIJSKOL, Ye.L., red.; PANTAYEVA, DZHATVTE-VAM FpKh.9 tekhn. red. [Experimental investigation of space near tho earth3 Eksperi- mentallnoe issledovanie okolozemnogo kosmichaskogo prostran- stva. Moskva, Izd-vo inostr. lit-ryp 3951. 277 p. Translated from the English. (M]= 15-./+) (Solar system)  BAGARYATSKIY, B.A. Discussion of the results of photoelectric measurements of the co:; tinuum of the airglow. Izv. AN SSSR. Ser. geofiz. no.12:1901-1902 D 161. (MIRA 14-.12) (Night sky)  91K910 AUTHOR: TITLE: PERIODICAL: S/053j61/073/002/CX;, 1/005 B1 1 7/B21 2 Aagaryqtskiyj_B. A._ Radar-reflections by polar aurora Uspekhi fizicheskikh nauk, v. 73, no~ 2, 1961, 197-241 TEXT: This is a survey of technical literature which has been published about radar studies of polar aurora. For the first time reflections of radio waves in the meterband have been observed from the ionosphere, which show the same characteristics as polar aurora zones, shortly before WWII. Much attention has been paid to radar investigations of polar aurora since 1947. The program of the International Geophysical Year also provided for studies of radar reflections of polar aurora. These phenomena'have been ob- served in numerous countries and also in the USSR; here, studies of Ya. G. Birfelld are especially stressed. The present survey mainly deals with ma- terial published be-fore the middle of 1960. A large number of results is not included, because they have been evaluated and published~ ChEqpter I deals with basic concepte of radio reflections of polar Aurora. The author points out that "reflections by polar aurora" is not an exact physical term, it is Card 1/4  S/053/61/073/002/00'1!/003 Radar-reflections by ... B117/B212 used for convenience, and tradition only and one has to see in it reflecthns of regions with higher ionization, which are related to the polar aurora zones. Now follows an enumeration of new findings, based on &available ma- ' terial, about -the structure of the ionosphe re and the possible radio re.- flection mechanisms. The following problems are discussed in chapter I: a) Range of reflections; b~ type of reflectionsi c) characteristics with respect to polar aurora; d) duration of reflections; e) spatial distribution of reflection zones; f) response of reflections; g) comparison of reflection zones with visual properties of the structure of polar aurora; h) altitude of reflections. Chapter II 6f this survey deals with the change of radio reflections in the day time and at night and their correlation with geomag- netic activities. On the basis of the material available, it can be estab- lished that there is a definite dependence between magnetic disturbances and the occurrence of anomalies in the polar ionosphere, which show up as auro- ral radio reflections. It can be assumad that the ionosphere, due to corpuscular currents does obtain a Lmber of properties in the polar aurora zone and also the region near the pole, which are missing if undisturbed and which have not been observed on other latitudes. Chapter III of this sur- vey has been devoted to the relation of radio reflections and various Card 2/4  S/05 61/073/002/001/003 Radar-reflections by ... B117YB212 peculiarities of the sporadic ionization near polar aurora zones. A consid- erable difference between sporadic ionization in medium latitudes and aurc- ral sporadic ionization has been observed, this is especially characteristic for investigations of the far-range propagation of ultra short waves in the ionosphere. Chapter IV brings the geometry of reflections and chapter V the electron concentration. Concluding the author notes that the experimental data, which are mentioned in this paper, have been obtained during observa- tions of radio reflections of polar aurora in the ultra short wave rarge. Most of the observation materials have been obtained by applying relatively simple radar techniques and methods. It was possible to establish various basic characteristics of the phenomena observed and also their position and the role which they played among other geophysical processes in high alti- tudes. Due to incomplete technical devices, it is difficult to establish more accurate charabteristies and physical parameters, and the development of special methods and more perfected technical instruments iB necessary. The author is also pointing out the necessity of forming a clear theory or a suited working hypothesis. In the beginning of radio investigations of polar aurora the geometric reflection scheme developed by Chapman was used Card 3/4  S/053/61/073/002/001/003 Radar-reflections by ... B117/B212 as theoretical basis for the procedure. The steady increase of evaluated experimental data makes a theory more and more necessary, which could ex- plain the occurrence of radio wave reflections from regions with an anom- alously increased ionization in polar regions from a physical point of view. The number of observation stations which will be reduced after the IGY, could be compensated by application of new instruments and special methods. The following persons are mentioned: Ya. L. "'part, F. P. Dobryakova, E. F. Chudesenko, B. S. Shapiro, X. I. Gringauz, V. N. Dovger, A. P. Nikollskiy, V. I. Pogorelov, V. I. Yarin, B. Ye, Bryunelli, S, F. Sandulerkq Ya. I. Felldshteyn, R. A, Zevakina, Z. Ts. Rappoport, V. M. Driatskiy, A. S. Besprozvannaya, F. Ya. Zaborshchikova, N. I. Fedyakina, A. A. Aynberg, -A.-,.I. Grachev. There are 25 figures, 2 tables, and 86 references: 26 Soviet-bloc. Card 4/4  KRASOVSKIY, V.I., doktor fiz.-matem. nauk, otv. red.; 2AGARYATISM, B.A., kand. fiz.-matem. nauk, otv. red.; ZHITHIKOVA, S.A., red.; DOROKHINA, I.N., tekhn. red.; MAnUKHINA, L.I., tekhn. red. [Collection of articles of t1le Intergoverrmental Comittee for the Execution of the International Geophysical Year) Sbornik statei Mezhduvedomstvennogo komiteta po provedeniiu Mezhdunarodnogo geofizicheskogo goda. Moskva, Izd-vo AN SSSR. No.-10. 1963. 153 p. (MIRA 17:2), 1. Akadeniya nauk SSSR. Mezbduvedomstvennyy komitet po pro- vedeniyu Mezhdunarodnogo geofizicheskogo goda. IV razdel prog- rammy MGG: Polyarnyye siyaniya. i svecheniye nochnogo neba.  FELIDSHTEYN, Yakov Isaakovich; BA PM7__B.A.., kand. fiz.- mat. nauk, otv. red.; SIHCHUKINA, Ye.P., red. izd-va; POLYAKOVA, T.V., tekhn. red. [Collection of articles of the Intergovernmental Committee for the Excecution of the International Geophysical Year] Sbornik statei Mezhduvedomstvennogo komiteta po provedenii:u. Mezhdunarodnogo geofizicheskogo goda. Moskva, Izd-vo AN SSSR. No.5.[Space-time distribution of magnetic activity at high latitudes of the northern hemisphere] Prostranstvenno- vremennoe raspredelenie magnitnoi aktivnostj v vysokikh shi- rotakh severnogo polushariia. 1963. 63 p. (MIRA 17:2) 1. Akadertlya nauk SM. Mezhduvedomqtvenrjyy komitet po pro- vedeniyu Mezhdunardnogo geofizicheskogo gods. III razdel prog- rammy MGG. Geomagnetizm i zemnye toki.  CC-NR, AT6026625 SOURCE CODE: UR/0000/66/000/000/0079/0088 AUT11011: Bagaryatskly, B. A.; Pei dshteyn, Ya. 1. ORG: none TITLE: Auroral radar echo and structure of the polar current vortex SSR, [Cc Iskly Nid Y~Poflzfche VysokcehInAqjye' SOURCE: AN S I i " IYM!PY issledoynnWa-~-c-,61asti geomagnettams. I aerono~nQfflgh4atitude studies in poraspetism and ,aeronomy). Moscow, Izd-vo Nauka, 1966, 79-88 TOPIC TAGS: radar echo, atmospheric Ionization, aurora, signal scattering ABSTRACT: Ilic physical theory of the so-called auroral radar echoes from the ionosphere of high latitudes in the 30-1000 Me range includes i;o-basic` processes. The first concerns the mechanism of reflection or scattering by means of which It Is possible to explain the occurrenc4 of eeVo signals at these frequencies proceeding from the permissible values of the electron density in the regions of auroral Ionization. The second question is associated with Interpret- ing.*the characteristic space and time peculiarities inherent to this type of reflection, The pres ,ent article is devoted to the second problem based on radar investigations of ionization in the polar-aurora regions In the Northern Hemisphere. The 19 stations involved In the hweBtiption  WM NR1 AT6026925 were divided into two groups, in each of which the statistical characteristics of the observed radar'echoes were substantially different. The statistical data revealed that reflections from regions close to the auroral zones occur with greatest probability during those hourr. of the day wheni. according to the theory of the polar current vortex, the current density is maximal. A leterpeak of reflections recorded at most middle-latitude stations between 2400 and 0400 local time,is accompanied in all cases, without exception, by a decrease of the horizontal component of the magnetic field. The first peak occurring between 1700 and 2100 hr Is characterized by them development of a different type of magnetic activity. It can be established that for stations of the Jodrell Bank type, near where the constant field is not disturbed by the presence of anomalies, this activity Is associated with an increase of the horizontal component. It is con- clud~d that reflection from* the zone of polar auroras is an effect which owes its pa' ftern of be- havior to the development of the polar current vortex of a magnetic storm. The frequency of the. appearance of radar echoes depends on the conditions of the occurrence, disappearance, and'shift during the day of regions of high anomalous ionization. Therefore, the presence of a close relationship between magnetic disturbances and the appearance of radar echoes should be expected, and actually the time regularities of magnetic activity -and auroral reflections occur identically in basic features. The periods of maximal values of the frequency of appearance of radar echoes vary in relation to the geomagnetic latitude of the station. A comparison of the spiral distributions of magnetic activity with the corresponding distributions of the auroral ultrashort-wave reflections revealed that they practically- coincided in the entire range of in-  AT'602692'&""~-' aff6r.61 latfweg., 711a indicated that the penetration of corpuscular fluxes Into the upper layers. o4gw atmosphere has a direct and s1multancous effect both on the occurrence of po- wapeft allvity &W on Ow appearance of radar ultrashort-wave reflectloas. Orig. art. has: A ,NMCOM64,,17/ SUBMIiATE:2lApr66/ ORIGREF:008/ OTH REF: Oil  - IBAGARYATSKIY, B.A.; FEL'DSHTEYN, Ya.I.; LEBEDINSKIY, A.I., doktor fiz.-matem. nauk, otv. red.; MnYUTINA, Ye.N., red. [Collection of articles] Sbornik statei. Moskva, Nauka. No.12. 1965. 56 p. (MIRA 18:4) 1. Akademiya nauk SSSR. Mezhduvedomstvennyy geofizicheskiy komitet. IV razdel programmy MGG. Polyarnyye siyaniya.  BAGARYATSlaY, _Y1J. A. UW/PhyBics Jun 48 Crystals - Structure Crystals - Measurements "Cameras for X-PAY Structure Analysis of Mono- crystals," Ya. A. Bagaryatskiy, M. M. Unamakly, In of Phys, Moscow Order of ranin State TJ Iment M. V. Iomonosor, 10 pp "Zavod Lab" Vol XI7, No 6 PA 14/49 -1108 Describes (1) universal X-ray camera f-.)r taking rotation X-ray photographs; (2) camera for de- termining Identity periods of a crystal. Photo- graphs and diagrams. dM 14/49T108  ad a /~ R M / SATI , Y BAGA+TSKIY, P. A. Rentgenograficheskoe issledovanie stareniia aliuminievykh splavov. 1. Primenenie m6nokhromaticheskikh rentgenovykh luchei dlia izucheniia strActury ostarenrykh splavov. (Zhurnal tekhnicheskoi fizikij 1948, v.18, no.6, p.1127-830. plate). Includes bibliography. Title tr.: X-ray investigation of the ageing of aluminum alloys. 1. Use of monochro- matic X-ray for the inve,,tigation of the structure of aged alloys. For abstract see Index Aeronauticus,,1951, v.7. no.7, no.11, p.j65 0l.z4F 1948 SO: Aeronautical Sciences and Aviation in the Soviet Union, Library of Congress, 1955.  V L D"ofmiudess of dw orientation of coarse single cryetals. Vu. A,linstsid) and B. V. KolontsovA Moscow State 11"Iv.). 0"dshoys Lab. 15, l(KI.2-710949); cf. C.A. 43. 491N.-lUck-re6ection inethods for the ork-ntatim of kurfal fuunuffyAtali were droctibril toy E'blrio and 1-*Onrn- Ix-tg (Z. Kriji. 89, 525 -8(IJXM) And Cdvinitigvf (Oid, 9 1. 424-t209M. The back-fellec-immi cutulitims fee struc. tural planes with W above 101) are d6cussal and tabulattA for crystals of Cu. Fe. Ni, At, and their siloy%. and the wave lengths nkvtt suitable fit white x-radiistion indiral"l; the miumnittams ihmiSh Lindenumn windows afe partiv imt favorablecuoulph. Thrictimigfltitwr.%vncroiCuiiii,!Ztiiti W 1. radiation must be considered: (or Fe ctystak the Ar I rudiation is particularly suitable if the voltage is held lwhm 'M Irv. and the short waves are filtered away by Al foil (10 to 20 p thick). The app. used was a r4untmon fxuc ""Met's '9 , with a gonlommer head ftw precisit"i Adj" - 11trill.11 Mpl.l. by bAck reflection is drumstralml for (he fjm~t grneral'..4- in the gnamo-stereagraphic pro~-ction, and its transImins- tion to oriented pooitious of the crysiallographic axes. For the detn. of the indrus of the %lx)ts the Crrininjrr by- bola Ill f I in imnetric Imetal cr%~tals. a use u ml and face-renteiml lAttice, 6 *'%tand- ard;',strfropsms me given for the dirmtiou% N (WWff protractor with 2M nim. diarn.). ThemientA. tion of a polished Fe crystal is given as an example for the practical use of The standard diagram. und the relations in the stereogmphic pm*iim drumonstuted. For cipuls of h"m symsortrY the oscillation mr1b,al is more vm%-rnirn% than the standard woJection unribmis. W. 1-*.iivl  400 9094 00 0 * 0 4 0 0 .000000000 *9409060e* a c 0 a IQ x L 2 0 a ru a I I vi W A.0 )WO LfTlit Aw.cf .of, tax Ion 10 x ION u an mill VUS4 libvx 304 41 AT LITTI% cStalls IRALTNAISIT13 U4042111 1VN9:MllTLPw I I *03l ~.7 Ito., -sqdvivOICKId pul SupAup 7D"- xq 000 a- qmpp I-A-5 ?3)10" -O IIPWIS 193SA- 10 -111YIP"Ol jol too 48412 . rzatirva aMpgjipp Atu.y pgdol" Alam SN143PU ck j) VAMOM"V7 04VVPOOOZ -A A-)31 . slo.-gril *V,nA (,uris%nH al) 'A PUU 11 JO) "a"D woo 00- c00 ff 00 C- D4 A -r-k -A -1-r -f Bill 43-10,14-W, 7- K ft n it 01-6 1 (,.w 0 0 6 0 0 0 0 0 08 0 o 0 o ' 0 -6 a a O s 0 A a as a a  'A DWA-b"Id X-RAY Mr-Olnealor. yu-LAWKWAII.- %ky.aasl F. V. Kokmasova Jc-rcW. Lab.. 19W. Ilk (8). RM- 961),--fin Itus"n). 11w momschromattir is intended prin. dpally f(w mingle-Mvtal work. fior which flat monm4mmustocs (which j(h-P a. beam) have ho little ikitennity. Asmalloperturc (11-2-) is uOrA MW the geometrical arrangement allows the wfw& fwall PIKA to be - viewed ", Focusing is neconarily imprriect, but this is immaterial fcw many splisi. wheir the van requirement In to mravve bwkimmind weltering. T'he J= ( the di.4 bes. is either w1usm or in the form of a narnm bne, quarm or kip" was toed, the a doublet wax not resolved. Formula od a graph for calcukting geometrical temotiti involved an gixen. The adaptation of ordmar~ r4je-crystal tam"sa for uw wM this nummehromator is sight line,, A (Iss an a gun) . together with the slejOe coffimator n6A.. slmi- -k4nas %be mean dirscUon of the twom. (Albs. from Fulmer Pronarrh Institute Translation No. 33.) - R. W. VI  k~,Tj 144 .81rodurml Chartres In Op Astina of an Al-N-1111c Alloy. ',I. it. 111pittypf.k4v Fnil.;. IP:P 20. (4). it; i 'i~~arrh hO, blinxIldim. V Thr ti-iriltT.f, allm. %I Of %U; "'Ill arl"'11111A lit 01 %lill lilt: 1-1 11.11, Ict-JA I'l limil AM-%. if JI'll I%et-iiinasi t%j, (imi, *-,I*-,. A,.). x.##%.v a file l'-fliftiv M Of Mg In-% pillilit'l ilk" 01.14ACO) ~Ijvlov th.it: (1) after it 21-4 V. arfil Ailvr ap-64, at :Rkl, all.1 ptvillitw. .4 q flew plimm, its Ifilli " I.. MAI 4.1 .%1001'. IS Idjoele) ml ",At IWl is Iii-ill 1-1PIAlkern Ill-, ilich;,41411111 oftililm I.-tifeell tile Wit IV lot Oil. M W.IN7111. AIM I h., N phn- I (.,I W vr% fit alhigm 1.111- -.111 lesit im I mieflIA116.1ko (if I lillam,.For.-Ahv.l: C.6-rM. 411 Mill.. 111AUR 11111101t,11111111 diflTAP10111 VffeeIA Kill I.V lay midl k6miliall-lim 3pl-mil". of it%",: ... 44"'llmil Imill .1; , (.it m%%, Ill.- An, m".110-1 al-W Oil." -f to- tyl- 101~1 if it'. rt,ilm-I flottil, r tile -10 "it.: (it) X-my tilicAngialfba fit the t,41isrAlIv ac-1 A% %%vll stol fhivw 44 fill, p1hei. 4'ell (,it 10.0111t) 1'r. At Ilk), 4tut fior IIA hr. lit l(NOA!.: 1-hem. 1-dierliA if 1111'.1,41 mle. iltill"ovil"lid ifiPlifelout frolit hirmilimiq 'Aillt Ihf, V-1114ot*v. lit of the I '%,., prim a it,,, attlIll Ill the MIJUl FANIn. ~ 41) hlier AkMilllj fltr M111. ni it-, 1 V.. ifil,1111"liM.- difframi'lit I"llefliq vir. WrIly defit .1-4 fnlius A!;..qr *4466.0 A h.vir""Iml .4 ...-1 ............ d If I, th"i. Alt Ih- "Ats &~ gvimi. 710. I.S.O.T.  Probable meChanistru of martgusite decomposition. N*11. A ' Ila ryalskil. DekladyAkad. Sauk S.S.S.R. 73. 1161 4 09.PrLA *tIntofeticalmudy in inade %if the orientation iv- i4tion ill file rurbide phase and Ilia Strtimic in the rally Mill"ofteltilwi-ing. Itinallown, hat a Clow velalloo exi~l. IWl%%tvjl the ul. 411killihnilons lilt tile (IMI (.t .4-11 skille and the (101) Idanc (it tuartensile. vkhru tile I likil dilet-thin In the venicuille cohickhrii with tile 11211 direction in tile m4riensite. The rclattion agrees with that finind by calki. '11w rkirresilikinding mcchanitun of the niarlensite up crineut. ill- llaurfortuation *I low tempering lculp'l. il: (I I -l"in. ning" J nutilruslie oil (121) pLamrs by 14twk% oi thh-kness duti)!7; (2) shift of the C atimis to file (winning planes; (3) beicklinc of certain at. planes. This mechanism re, quiref. movement of Fe alkinis of less than one at. spacing. A similix mechanism explains the ppiu. of the second phase i!i ill ralumin. Two-ilimen-vonsl x-ray diffraction effects in tt 11121 direction and one-dunctishnihIrfler1% lilt (I im planes of lite reciprocal lattice of niartrosilc shotild he observrtl duri ill letntsring at low trint1q. A. 0. Ouy  - 41 4W LOW 1+; U.S. S I. crystals with. rnonochram~atic radalation al 10"VT T-araparatux-es, X-rry M tin-a-, cf si-rtcle nnrstads of' X~Cu and a-Gu.--Vg aa  r *On fbi Question of the Mechanism ~f ib. necoulTindfinn in AlloYs I and SW U. a a to "In Fi:ikil I Y (, [ IP51, - . . cas,an]. The ageing of Al alloys at intermediate temp. (150'-200'C.) results in the ,Jou~n'al of the Institute Of MOWS formation of a metastable state where the lattice of the " Vol 21 Part 7 con- precipitating phase and that of the solid soln. are " f . nnooft t and the strains set up result in the hardening of the Mar. 1954. - allay. In Al-Zn, Al-Ag, and Al-Cu-bTg alloys the motastabic Properties of Alloys precipitating phase is essentially the same as the stablL , i l i l l1 h -Cu prec tate, but n A a ases are differeut; oys the p p the lattice relationships are given for the Al-Cu-Blg Alloys and show linking along the (012) planeL of the solid mofo. The" flrst" decompn. c,fmaTtons1to(l00'~-lG0'C.) lathought, to hivolva the formation of motastable FbC and a theoretical relationship is presented which allows linking of t4r) strabuxt FeC lattice along the (121) martennite planes. Therelatioij. ship is the same as that observed experimentally for marteasi(v decomposed at SWAM' C. and thus supports the inotnatablo linkod-pptn. theory. In Al alloye concentration of solift atoms occurs before pptn., and it is considered important to establish whether this occurs in steels and other alloyR; &*pproaches to the problem are outlined. 36 ref. (Abstme" from Fulmer Research Institute Translation No. 45).--.-D. M. 11.  Pt POW DIFUGWOMMOIS is as I ro"Ald X-Rapa. V%L~A_Jj%f&ry-#AAy,(U#pfAi Ax. Nook, 1931. % (2), 2W.- .95).-IlnHusmian). A review c4ommimw umth" intim- Wtuxtrimmoidn* of X-ram IThe data ixt llinra' metin-1 am Iwwwpunim In the folittwitilt abolmi.) All4millim in call"I to tile. advasklAW "( ushlg A (64491Y beft'i) F111414~' thromator with Ow w8wting pWm at an w*6 to the surWv. 7Uounfirmthelakywingadrant": (i)cryxW-JWmdW&n in larlp, aLlowing a hop sprcis"-film dm"nm (tmmmawm method) asW tbadw high madn.; (ii) filme mu be placed .L the b~. again au~ nods ; (iii) own*--cry*W dim. lance usall, giv* good ingenal's ' I%*' mrUsod is specisHY "Comm,ndAl for -Min-dw 0( . (Ab. strucWd from Fulmer Bra, rch I-wilut, No. 34.1 -P- W. C. ~-A  IR ~L Ost$ 1. It .0 1, t? is W 0 11 A 11 V 31 Is X ft V a 0 4 41 ,A IN W-l! Q-9 I A. All 00 A' .-- 0, 00 N--X 11M 00. A 5" got 00 6370. 1 001 miogution or the Inteneity of diffuse 6cattering of X-rays,for .00 loss 6991m alloys. YU. A, Balarya okki SM, 77 (ND. 1) ~00 Doklo AMC IkUk, & 45-8 (1951) In Ruslifil.- .00 TtA probles; Is oonaMerod in 1 dimension. A fbreiob atom occurs (pp rhmo 1 -00 almo 419plac*d) at IrreRular intervals in a rovular chain, Thm mnntterslI goo intensity is sonde up of 3 terms, due to the regular array of atomm, due goo to the errors only and the arose term. Of these only the second has a value e at points other then reciprocal lattice points. FbIlming Merl= (Abittr. 0. 6159 (195.3)) the diffuse scattering Is calculated for a (Wissinn Aintribution : 0 0 of the dintano9a between errors. From publimbM Antn the diffuse scattering goo 0 in AI-Cu alloys Is drawn out for 3 different degrees of serregation. so gi A. T- I.IncKav see ir,Ze 00 .$..it A, WITALLUPWAL U19RATURE CLIOUIRKATION -Z. ts 00 lit 81 I" .1. CON. 0-4 3, 111 43K CAN III U U AT -0 1 1--- V- 1 4 V, ;-''t ~,~ L I a 04 0 Q I W AI1.3 I : V rp 0 .01 ; ; , T ; 1. a x a it . - 0 0 0 0 9~0 41 0 0 0 0 0 a 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 140, 0 0 0 0 0 0 0 0 0 0 * 0 0 0 0 0 0 0 510 0 q 0 0 0 0 ; Z  -16 *X-fty JEWS on 00 AXIAU-01 the Ah1W 44%) Yu. A'auk Our 8.8.8.R., 1951, 0~- Rtmisn]. Data on( the diffuse scattering of X.-ya by AI-4% Cu allo), enable a number r4 questious to be answered. Onamonochronintlo holograph of' the naturally aged alloy them am no two. S tImeWonal diffraction spots with 30. and 03. indexes (in the co-ordivatee of the reciprocal Isitice of the solid soln.; the. full stop replaces too non-integml third index jej, but spots with 11. indeires are present; hence the two-dimemsionAl 1 diffraction at this %tap of the I ' aping in not prodived by thin layers of the W-CuAl, phase, This agre leZakharova's conclusions (ibid., 1050, 70, 55; X.A., 1% 03) for AI-2% Cu alloy. The observed asymmetric distribution of the', Intensity of two-dimemional diffraction agrees well with B.'s cadculationo (ibid.. (1), 45; preceding abstract) bawl on the hypotheals that Cu atoms collect in regions contg, 2-3 atondo layorB (001), with mine change In interplanar distances. It does no4 support the suggestion that the displacement of neighbouring planes plays the predominant part. The apparent discrepancy between them conclusions and the resalta of Buinor and Jerinntan (ibid., 1950, 74, 707.929), who obwrvM the same formations in both naturally and artiticially aged alloys, to fliftt nglons of Jo-j ()u con. centration were eichtd out, so that the parts contg. collections of Cu atoms and the strained regions of solid solo. Around them r isolated; the atoms in them regions rearratiqla =mvNpa`to fam. A stable phase, pr6ably MAIj. Gniniers exp4itation (Memm, 1940, 11, 305) for the forniation of & JkliperstrUCtUrC At A OCrtAlo. Otago Of hMt-tVCMtR1Wt is not oonsidered aLtWotiory; B. suggests that the regions with the superstructure consist of 12 atomic layers (001), and the concentration of Cu atome in them corresponds to the compri. CuAl, -, layers Noe. 2. 6. And 10 consist wholly of Ci]i atoins, 0. 4, S, and 12 only of Al atoms, and the odd 143-Ors contain -an arerago of 118 Ca and 516 A] atoms. This structure itaidly rearranges to the 0'-phaw, which (ornis lit In "hick interlinked. with t-4 lattice of the solid soln. During the rowth of the 0'-plinso nuclei, c falls from 6-06 to 5-8 In tTo formation of 0 or W phase nuclei, a considerable t-incroaso in the elastic energy of the lattice is noom-tary, and the formation of the bonds at one L%tticc point cau" strain 'in the surrounding rrgiong, although this is reduced bi directed diffusion of Cu atoms to this point. Hence ~s regards energy, structures in which the Cu atoms collect in 2-3 atontiolayers aropreferabletotboac with the ui%x. number of Cu-AI borida. At, higher temp. the Cu-Al bond Is wcalker and the role of elastic energy is reduced, so that there arc a large number of Co-Al bonds and a more even diistribution ;of On atonts throuchout the lattice. Tho medimnism of natural ageing of M-Cu Alloy is thus determined by the 'arg iff~:n- in op. "tomio vol. of this solid scln. and the tat g phase In AI-Cu-'Afg and A]-Ag nllf~vs the Pri I ce I" .all v d I Rp" ind the aping mechanism is essentivilk differunt-G. V. E. T. ~s,  I A cm ~ae -at-are of fomt-l an s~udaces of sted bfW- -4 pi-zh- Z 17 1452 (--T-.- -~7 ~- IMl- U S S R 13W* gave a bright oic-r Liyvr of F"W~ as, etchcd htlqogr.-,pu5 rnid4le ront- d ~ ptu!~ 4 ~ud an m- tcr' 61 1,;zc Wl . w)ul --in. C) treatrd 1w 6 lv~ w MW ~t~d an l ~ C l . ,~d -tt, 1.~- J ph- f F,-,W, -,d F-W, t e~ A wonxly d, -Aith a thwk miVi Lty,-f ,I Fc,% * 'ith i-tl- ul 1; 11411muski-  77- al Mr; A2--as -.4  -11echanism of ratural aging of aluminum alloys, Vu.A. DAIady bogar yatski Akad, Xavk S.S.S.R. 97, M-432 ~ mhesis tbat the Ist stages of natural aging (1952).-The hypi arezussocd. with the ppra. of a phase intarazediate bcoveen the solid soln; and the - (Guinier, Metcux el Cor phast .0 OSI is 18, 209-1709-13)) and the theory that the 2nd phase is Y the one which ppta. origmally (Ceislet and Keller, C.A. 41, 76f) were expernnentally checked and found lack-ting. Rdnt~ zenogratrig. U-en %vith a motiochromatic light ou mono- CrYAOIS or a 3% Cu-1X-,'/O Mg Al Lifloy agid, for 3-3 ruin. at M* showtil that spots rxrresponding to the 2nd phase (Al:- L CuNlg)-did not-co"espond in their position.to spots of the: Zid plizie produced -by-natural-aginz;~ No particles of the.- ensional nuclei, are' 2nd ~Plv~ze, Eden in the shape of unid,M th produced bynatur-alagiag which lead tothe fortnationof e'. Atoins ofCn anti Afgas ren: as of Cu And At tending to approach each other within thi.! snace lattice of a supersat td-soln, cannot-form.- the most account n ' 0 thermodynamically advantagm n 's T figur M Z of the SIj tround ills! Atoms of the solid sol.. and  :7 T, M t, VIVI, Iq j ~A .4 7 - _% ' .0 rtt? iintsoccur 4" `%,;;~-~224W n65 e Corr 'Ity al atoia~ plants destroying tb ect oerioU K in V anes wit',iout causing any changes in th4 4~ 014% these pL --pas-ion so that the pliewimena of unklimensional diffracfion--.~' calnWotmened _A:,AUIn_dJAtirTj_ W __aj pie, ance W e pa ing J. :'atoms -0 4 1. is prod-teed by Lh6e displactrawt-4 Itailing to strei- T. the iatlice and ehanyjts In mech. pr6pertics of the alloyt,14, -i-These areas cannot be considered as those of the 2nd phr,~ei -pondeAl the), corre, to the prepptui atiast assacd; with-Abo. r 'forniattion G? a vwy tylve of boud bew"a tho Atowl Ill 78PActlattke. 11:15"dog fivill the a)-Go. StIltetu natu j aged to that Lf artificially aged alloy takes p1 Sh W. new rearrangement of Cu and Al atoms Along (010) planes, the mechanism of trauslormation Ls at ph reseenibling the lomL3,ion of t-in plan" in t. Irt Gpots Imn"I by the 6' phase we not al-arp, as Previo x Claimed, but are OungauLd evtu at tht earliest stag fr-lation. J. D.11  BAGARYATSKIYO, Yu.AL.; TIAB IN, I.P., akademik. Calaulation of X-ray intensity dispersion at various degrees of diffraction orders in the distribution of defeat& in crystals. Dokl.AN WSR 92 no.6: 1157-1160 0 153. (W-H, 6:10) 1. Akademiya, nauk SSSR (for Bardin). (Orystallograpby) (1-rays--Diffraction)  Yu A. USSR/Physics X-Ray Background 1 Nov 53 "Computation of Intensity of X-Ray Background at Various Correlation Degree of Solid Solutions, it _-Yu. A. Bagaryatskiy DAN SSSR, Vol 93, No 1, pp 35-38 At-tempts to solve problems of scattering of x-rays in solid soln. Obtains the same results found by M. Lifshits (ZhFTF 9, 4(1939)) and-~Yu. N. Obraztsov (ZhETF 8, 5 (1938)) for the one dimensional case with chain atoms and in absence of distant order. Presented by Acad I. P. Bardin 1 Sep 53- 275T93  YO.,X, U&WPhYsizal chemistry - Crystals, 13-5 Alist Journal: Referat.Zhur - Khimiya, No 19, 1956, 60845 Author: kBagaryatakiy.. Tu. A. Institution: None Titlez Roentgenographic Investigation of Aging of Aluminum Alloys. III. Use of Roentgenogoniometric Methods for the Determination of Mutual Orientation of Phazes. IV. Procedure of Computation of Diffused Scattering Photographs Original Per*fical: Fiz. metallov i metallovedeniye, 1955, 1, No 2, 316-338 Abstract: Description of method and results of determining the orientation of equilibrium phase A12CuMg (S-phase) in aging alloy Al-Cu-Mg (duraluminum) and ascertaining the nature and cbaracteristics of strengthening phase formed on artificial aging,ift is made of alloy monocrystals and roentgen.ograpI pictures using Laue cameras, rotary and "KFOR" with monorcmator. Roentgenogonio- metric pictures in IaW which do not distart the appearance of Card 1/4  Wa/Physical Che'mistry - Crystals, B-5 Abst Journa.12 Ref erat Zhur - Aimiya, No 19, 1956, 6oB45 Abstract% the planes of inverse lattice permit uniquely to determine orientation,of S-phase in relation to the solid mothor liquor ((K):/_71o__67s_ALTo_6T.., /M 11/U12T,!y, COOjTS11LM71aj there are 19 .---o7s - --- sud*07stallographically identical orientations of S-pharje particles in the crystal. Tb* is pointed out a correspondence in structure of cc- and S-phas6s which leads to this law of mutual orientation. Analogous pictures of the alloy following aging at 2180 and analysis of the results obtained permit to reach the conclusion that in artificial aging the strengthening phase is the same S-phase but in combined state conjug* ,Fd with the solid solution which causes certain peculiarities in"particular a not exact fulfillment of the above stated orientation law. Considered pLtion of 2 are the possibilities of determining the mutual 4WW phases by the proposed method even in that instance vbjin the crystalline structure of one phase is unknown.,-IV. By means of vectox, analysis a computation foxmula is derived for the transi- tion from coordinates in a plane picture of diffuse scattering ob%&& tained with monochromatic radiation to the coordinates in the space of inverse lattice for the point responsible for scattering Card 2/4  i MaWF4791cal GImmis+ry - Crystals, B-5 Abet Journal: Referat Zhur - IOLUiya, No 19, 1956, 6o845 I Abstract: in the given direction the se of cubic crystals: c~ yQ-1 S,~i %(xlx2x3) = a~A_l 7 + (DQ-1 - 1)SOI. Where Ha is vector of inverlaxelk"ce having coordinates xlx2x . measured at the scale a* = I/S (a -- period of crystal latticei,,.~ ~.d y coordinates in picture measured in the direction of unit vector i of the crystal and perpendicular thereto (clockwise on looking at the picture in the direction of primary beam So)) So -- unit vector In the crystal of direction So, D distance from speci- men to picture (in same units as x, y), Vxl~ + 7 + D-1 - There are-given developed particular formulas for 2 instances; when vector i is parallel to direction Joso7 or Jig in the crystal and position of vector So is arbitrary. Derived are also formulas for the inverse transition from coordinates of scattering point in apace of inverse lattice to the coordinates in the picture: x/D a (*)I(SSO)~ y1D x (iSSO)/(SSO)j where (IS) and4MO) are scalar products and (isso) the triple qk-Aed product of 2 or 3 unit vectors in the crystal and S m So +;ka*Ha. In the supple- ment is provided proof of multivalued nature (with accuracy up to factor -1) of the values of coordinates obtained on computations Card 3/4  USS,R/Physical Chemistry - Crystals, B-5 Abst Journal; Referat Zhur - Khimiya, NO 19, 1956: 60845 Abstract: by means of inverse lattice and the usual computation of pictures by the Laue me-thod. Crmnunications I and II, see Zh. tekhn. fiziki, 1948, 18., 8271 1951, 21, 658- Card 4/4  -, I ];-ray investigation of the aging of aluminum alloys. Part 4. Methods of diffusion-scattering roentgenograms. Fiz.met.i metallovel. 1 ne.2:330-338 155'. (KLRA 9:4) l.TSentral'W nauchno-iseledevatellskiy institut cherney metalur- gii. (Aluminum alloys-Astallography)  -,'The f-phase crysUl ttructurgend Ats m- ------------- I'M VA.171 M WR  fi r19 -Ff) t