SCIENTIFIC ABSTRACT SAVITSKIY, A.V. - SAVITSKIY, F.S.

85041 S/l26/6o/olo/oo4/oio/o23 E193/E483 ,On the Problem of the Effect of Stress and Deformation on Self.-Diffusion radioactive AS and Fe isotopes. The method employed entailed measuring not only the intensity of the P-radiation beforeand after diffusion annealing but also the intensity of the y-radiation, which being independent of the depth of diffusion indicated the concentration of the radioactive atoms present in the specimen and participating in the diffusion process. The results obtained showed conclusively that applied stress and,deformation have no effect on self-diffusion in metals. Regarding silver, this conclusion was in agreement with the findings of other workers (Ref.15). In the case, however, of steel it has been reported previously _(Refs.4 and 5) that deformation considerably accelerates the rate of self-diffusion in this material. To find the explanation for this discrepancy, the author, using his experimental data, calculated the values of D forunstressed and stressed steel specimens with the aid of both the method employed in the present investigation and that used by the writers referred to above, who had based their calculations on the intensities of ,the 5--radiation alone, Whereas D, calculated by the former Cara 2/3  85043, S/126/6o/olO/004/010/023 E193/E483- on the Problem of the Effect of Stress and Deformation on Self-Diffusion method, was the same for stressed and unstressed material, a large increase in D was obtained for the stressed specimens when the latter method was used. It was inferred hence that.a cert ive atoms may be lost during the ain proportion of radioact diffusion annealing and that if erroneous results are to be avoided, the difference between both p- and y-radiation before and after diffusion treatment should be taken into account in the calculation of D. There are 4 figures, 3 tables and 19 references: 8 Soviet and 11 English. ASSOCIATION: Fiziko-tekhnicheskiy institut AN SSSR (Physico-Technical Institute AS USSR) ,SUBMITTED: February 17,~iq6o ~Card.3/3  8h865 2qoq, 17-13 S/079/60/030/010/001/030 BOO1/BO75 AUTHOR: Savitsk A. V. 1 -Y1 TITLE: Solvation of the Ferricinium Ion PERIODICAL,: Zhurnal obshchey khimii, 1960, Vol. 30, No. 10, pp. 3167-3171 TEXT: In a previous paper,(Ref. 1) on the oxidation of ferrocene.by means of iodine, the author-,came to.the conclusion that the solvation energy of the ferricinium ion reaches a considerable high value. To-check this assumption, he studied the equilibrium Fn.+ (3 2)1 Pn+ I- in 0 2 ethanol between 150 and 45 C. (Fn = (C H ) Fe), The solvation energy of 5 5 2 the ferricinium ion was calculated according to the corresponding cyclic process and from the heat effect of this reaction. The experiments were carried out at ferrocene concentrations between 2.5-10-4 and jo-3 moles/1 and at iodine concentrations between lo-3,and 1.2-10-2 moles/l. The spec- trum of the solution within the absorption range of the ferricinium ion (580 660 mg) was recorded by an C~ 2 M(SF21.T) spectroDhotometer. As Card 1/3  84865 Solvation of the Ferricinium Ion S/07-/60/030/010/001/0"0 B001/B075 the ionic strength of the solution did not exceed 10-3 moles/l, the. ac- tivity coefficients of Fn and I could-be equated to unity,-and the ac-, tivity coefficients.ofthe ions.were calculated according to Debye. Assum- ing that there are no side reactions, and that the solution follows the Lambert-Beer law, the following equation is written down for the optical d nsity D and the initial concent Fn1O and 0 e 00 irations 11 ' 2 2 -3 2 [Fn] (Dco - DO) AE + K_ Y (D Co D0) 1,21 where Do EFn [Fn] o + AE= E + F_ E (3/2)EI K denotes the, equilibrium 1 [,21 o Fn I- Fn 2. ~3 2 constant, y - the activity coefficient of the monovalent ion, E.-the absorption coefficient.of the molecule and the ion,-respectively, I 1 21 the iodine concentration in equilibrium, whichis littledifferent from [12] 0 if iodine is in excess. A linear relationship between 0 (D 00- D0 )_1 and 7 2(D Go- D0) [1 21 -1/2 (Fig.) follows from this equation. 'The values for and [121 were found by successive approximationz. The values of K and LE determined by the method of least squares are given in Card 2/3  M665 Solvation of the Ferricinium Ion 9/079/60/030/010/001/030 B001/B075 Table 1. Herefrom it was found that AHO equals -5,,5 kcal/moles and 6S0 equals -16 e.u. (Table 2). The absorption coefficient of the ferricinium ion for various wavelengths was calculated from 6E(Table 3). The sum LFn + L I- of solvation energy was found to be equal to 129 kca 1/moles. In Table 4, this value is compared to the sums L M+ + Li- for other M. cations: Li, = 199, Na+ 170, K 162, Rb 147, Cs 137, (CH 3)41"' =100' (C2H5)2N 90 kcal/moles. The author mentions an in- formation by 0. M. Gayssinskaya and V. A. Sokolov, and thanks Ye. K. Syrkin for supervising the present work. There are 1 figure, 4 tables, and 10 references: 2 Soviet, 5 US, 2 British, and 1 German. ASSOCIATION: Moskovskiy institut tonkoy khimicheskoy tekhnolo-ii (Moscow Institute of Fine Chemical Technology) SUBMITTED: December.7, 1959 Card 3/3   S/08!/6z/000/001/005/067 B156/B101 i%UT-HIORS: Savitski.~,, A. V., Syrkin, Yee !;"echanisa ard thermodynamics of the oxidation of ferrocene ;Md ruthezocene by iodine PERIODIC": Referatii-yy zhurnal. Khimiya, no. 1 1q62, 62, abstract 'r.. po khimii i Ichivi. tokiinol. (G~r'kiy, no. 1, 1961, 1B450 T:'ZT: The kinetics Lnd thermodynamics of the oxidationof ferrocene (F)and nd C 1, OH by iodine have been studied by spectro- r;.i'~,onoGene UO a 6 2 5 P Z-A ry 'Iemperature-~. It is shown that during the reaction, ~r; a ed C H The ionization and c-,V ioiir; of F and 11 are form. in 6 6* potentials of F are ev). The authors consider thatthe cation of ruthenocene is ~y ntgble than the cation of ferrocene (Fm). The reaction i5.13t order to F and 2nd order. wit,h respect to iodine. The following were determir, P d for the limiting Card 1/2  S/051/62/000/.001/.005/067 !..-echarLis.-..- and thermodyna-mics ... B156/31oi S~age: r i 6 kcal/rIlo t-, H 6.5 kcal/mole, -"-S" -32 entropy units. ..videntl,-,. the iodine atom formed in.the reactiou F + 21 --~ FI + I oxidizes 2 the second.molecule of F by a reaction with a low activation ener(;y. For the reaction in C if OH, the heat of solvation of Fm is assessed as 2 5 40 - 50.-cal/role; the rate of the reaction is proportional to the concentra-I ion of ~Y to the first power, and to the c oncentration of 1 2 to the power of 3/2. !on pairs are formed in the C H and solvated ions in H OH. 6 6 C2 5 !Abstracter's note: Complete translation.-] Card 2/2     properties of. sc:.-..-conduczors. K. D. n:.s prEsan:a:.:Or. thle fol pe?e.-S. ~~f suscept"ll-i'l 1-ty 01.1 Sc:r,-.;Colv,L.,Ct:ors. K. D. Tovs::yuki Stakira, 0. X. Porotz. e, ~;Gse, ?bse. Z pro?er--*cs of HSTie, Pb- X. 0. Tovsr-yuk, M. P. Gavaleshko, Ya. S. Sudzhak, P. M. Szeril.-P P. -7. Voro.-.yuk. xacnat;c suscc:)Z;.blli,,y,o..F CdTe z:rd ZnTe- r. V. Potykavicn, A. V. Savirskiy. I~zGnetic properties of the systeia H'qTe-CdTc. K. D. Tovsty k, T- M. Raranko, 1. V. Potykcvch. ^:~~:Sozrooy of the thermal conductivity o"" CdSb- 1. M. Pilat, L. 1. -CdTe. es of the systenn 'n2Te3 cc ca masne t i C, a nd op ca I P.-G-Per T V- Potykcv-ch, VL'jav, S V. C.-. 71, C~~ c C, c rys tz-.  AICCESSION NA: A-PhOO93Jl S/0l26/63/ol6/bo6/b886/689o AUTWII: Oavi~':r'kdy' A* V. TrrLE: Evaluating small values of self-diffusion coefficient with.the aid of radioactive isotopes SOURCE: Fizika metallov i metallovedeniya., v. l6p no@ 6.1 19631 886-890 TOPIC TAGS: self diffusion coefficient, radioactive isotopep silver, metal diffu- sion, diffusion temperature relation, diffusion activation ener&r ABSTRACT: The article presents a method for calculating the coefficient of self- diffusion for silver. This method was based on the use of radioactive isotopes; it represents an improvement on a previous method which could not be used for calculating very smaU values of the coefficient, The for=xlq for the mass X of an isotope passing through'the metal surface in time t is M C" JfDt. The coefficient of diffusiork given by this fomula vas Card 1/3  ACGFZSION NRs AP4009381 All D 4q t and the quantity of the X iBotope was where I is the sample activity registered by a counterp S is sample surface,, alpha is the coefficient of proportionality. -The last formula cannot account for the absorption of radioactive radiation within the sample, because at very low values of the diffusion coefficients thedepth of isotope penetration is so smal I that the'absorption of the radiation registered "is practically i;npossible. For this reason the author derived the formula 4 J. for'calculatIng very small values of the diffusion coefficient. Here d is the thickness of the metal layer in which the atomic "exchange" between the solid a A r the molten metal occurs. "The author expresses his appreciation to S. N. Zhurkov Card 2/3  Acussio,u xR: AP4W9381 sumawm; o9xay6,3 DATE ACQ: O3Feb64 DCL 1 00 SUB CODE: M . No REF sov: oo6 .. OTHER: 002 Card 31.3  ACCESSION NR: AP4041376 9/0048/64/029/006/1051/1052 AUTHOR: Tovatyuk; K.D.; Savitskiy, A.V. TITLZ# Magnetic susceptibility of ZnTe Zke~ort, Third Conferqnco on Semiconductor Compounds held In Kishinev 16 to 21 Sep 19627 SOURCE- AN SSSR. Izvestlya. Seriya'fizichookayn, v.28, no6.1964, 1051-1052 TOPIC TAGS: magnetic susceptibility, zinc compound ABSTRACT: The magnetic susceptibility of ZnTe was measured at temperatures from 293 to 600oK. The material was synthesized,by heating the spectroscopically pure elements in evacuated quartz ampoules. The single crystals were grown by the Bridg-1: man technique. X-ray studies showed the crystals to have the sphalerite structure; i the hexagonal modification was not found. The samples for measurement were.eylInders 20 cm long and 5 or 6 mm I*n diameter; after being cut and polished, they were etched with aqua regia and the resulting thin film of tellurium was removed with HC1.-The susceptibility measurements were performed with a modified Gouy method described by! W.G.Henry and J.L.Rogera (Phll.Mag.1,223,1957). the magnetic susceptibility of the- single crystals was found.to be Independent of temperature and equal to -2.98 x Card 1/2  AC.CESSION NR: AP4041375 To investigate the effect of adsorbed gas, the susceptibilities of compressed pow- der samples were also measured; The susceptibility of these was -0.536 x 10-6 at room temperature.and increased linearly with increasing temperature. This behavior 'is ascribed to adsorbed oxygen.- The susceptibility of the single crystal is ascrlbp~ iced to the lattice because of its temperature independence. The lattice iusceptibi- lity calculated for ZnTe by Kirkwood's formula is -2.64 x.10-6. There is"according-1 1y a paramagnetic component of the order of 0.66 x 10-6; from this It is concluded that the bonding In We Is predominantly covalent. Orig.art.has: 2 figures. iASSOCIATI(Mi Chernowitakly goOudaratvenny*y universitet (Chernowits State Univer- sity) SUBMITMD: oo ZNCL: 00 StM CCDZ: 68, ZC_ M Rff'S(Wj .004 OTM: 005 Card Z/2     24792 65' IdImt, 45003466 Is l Fesuit6 Treasurenm :of the' ~61 coefficients.' s f peci 0, e t 7 iw': 4- - !~- A-1 10r 40::L- 42 ~65 5 7 133 2 -I: 6 10r 131'::L- 41 3 , '136 + 4t , 130, "3 -L- 4:,: ; 85 -.1,1101, 124 37 7 6 131 Z -s 125, rd ca 3/~    L 106-66 DIT(1)/E-IT(m)ATC/E"IG(M)/T/DT(t)/a-IP(b)/r--WA h) (c). ACCE9SION'BR: AP50198 6 UB10181165100710081210TI~ fy, S AUTHOR: Bercha. D. M. Pankevich, Z. V. Savitskiy, A. V.; 9~avstyuk, K. D. TI FYI. ST TIE: Fiezoresistance of Sb2Te3 SOURCE: Fizika tyerdogo tela no. 8, 1965, 2437-2443 2OPIC TAGS:- antimony telluride, crystal lattice, semicbnductor, piezoelectric, group theorys,piezoelectric effect ABSTRACT: In view of the fact that the compound Sb2Te3 has been.little investi- gated in the past, and not at all from the-:point of view of the*.structure,of the. energy bands, the authors,supplement the.group-theoretical analysis,vith measure- ments of piezoresistance, for the.purpose of establishing.some of the Aintinctive features of the carrier spectrum. The p-tyne -single. nrysta3s were obtained by zone,w refining technique and the measurementi were made on plates measuring 15 x 2,,x,2. MM' cut both parallel ana perpendicular to the c-axis (which in turn was'perpendicular to the cleavage pDwe).- The sample conductivity-.at room temperature'rqnged from A 2.6 X -102 to 5 X 103 ohm-1 -1 peratur s 160- cm . The measurements were made at'tem e 300K- The accuracy was 20-25%. %be diagonal components of the piezoresistance 1 tensor were found to be approximately one--two orders of magnitude-Jarger (- TO X X 1012 Cm2/dyne) than the off-diagonal ones (-3 x.1022) and exhibited a slight Card 1/2'   t bse,to A 3-~-bo.6o,c mp~r .atui clud4d'-'t 6       L 32965-66 EWP(J)/EVIT(m)/T 1JP(c) RM !--ACCKR-zk~6-0176-03 (-AT SOURCE CODE: UR/0189-66/000/001/0029/0031 'AUTHOR: Levin, B. Ya,; Savitskiy, A. V.; Demicheva, V. P. j, ~ORG: Physicotechnical Institute im. A. F. loffe AN-9�0-(Fiziko-tekhnicheskiy linstitut AN UkrSSR) TITLE: Effect of the degree of stretching on the strength of capron fiber SOURCE: KhimicheSkiye volokna, no. 1, 1966, 29-31 -TOPIC TAGS: synthetic fiber, polywnide, tensile strength, nylon ABSTRACT: The authors study theeffect.of stretc4tng conditions on the.strength of polyamide fibers at liquid nitrogen temperatures.15 The specimens had minimum initial orientation evaluated from measurments of birefringence. The experimental data show a linear relationship between strength and degree of stretching. Elongation and .Molecular orientation increase 'when the stretching temperature is raised. The experi- imental data prove conclusively that the strength of capron fiber is a function of the degree of stretching alone and is independent of the temperature and the rate at which, the orientation stretching is done. The increase in strength properties of the capron takes place in such a way that stretching does not change the breaking load at -1960c reduced to the cross section of the original fiber. This same relationship is observed in specimens of,2o1yethylen;Knd rubberArben they are stretched to 4oo-7oo%. If the Card 1/2 uDc: 677. 494.675   L22L98-66 EY4P(J)/EWT(m)/T RM ACC NRt AP6009874 (A) Soma CODE: uH/o4l3/66/ooo/oo4/oo60/oo6q. INVENTOR:' Sa1ritjhjy x A, ~,V: Skach lova, S. Ya. Neugodov, P. P. Hatushenkol Arkhipova,-F.-V. Falev V."' Badayev, V_K. ORG. none -TITLE: Preparation of polyolefinsl Class 39, ~!_o. 178982. lannouniced by State :Scientific-Research Institute of Polymerization Plastics- Experimental Plant (Gosudar.3tvennyy nauchno-issledovatellskiy institut polimerizatsionnvk h . Plastmass, eksperimentallnyy Z*avod); Central Scientific-Research Laboratory of Reagents (Tsentral~naya nauchno-issledovatellsKaya,labor riya reaktivov)j, SOURCE: Izobreteniya, pr-g*shlennyye obraztsy, tovarnyye znaki, no. 4, 1966,~69~_ TOPIC TAGS: olefin, polymerizationp polymer ABSTRACT: An Author.Certificate has. been issued describing a methods of obtaining polyolefins by polymerizationlof Alpha-olefins in a medium of an:inert hydrocarbons solvent with heatIng in tFe presence of acatalyst consisting of a mixture.of dialkylaluminum chloride and a heavy metal compound. To speed up the process of Chelate derivatives polymerization and expand the variety of heavy metal compounds of orthovanadic acid are suggested under the general formula VO(OR) (OIX)2 . where, R;is','- the hydrogen or alkyl and X ip the.remairider of the chelating agent. Methylether of vanadium orthohydroxy2uindate is the chelate derivative of.orthovanadi,c acid,sugg st d M: 07,111 SUBM DATE: COD 13.Aug64,~ Lr.,d CM 678,342  L 24286-66 EWT(m)/EA`(M)/EWP(t) IJP(c) RMY/JD/JG G ACC'NR- m6omoi SOURCE CODE: UIR/005-1/66/020/002/029~/030-LJ S AUTHOR: Kurikj, M. V.; Savitskiy., A.. V. ORG: none TITIE: Optical properties of zinc telluride. II. Effects,of Inj, Gavi, _pu impur ties on the absorption edge SOURCE:' Optika,i spektroskopiyat v. 20) no. 2y 1966, 297-302 TOPIC TAGS:~ zinc compound optic material, telluride, absorption edgep exciton ab sorption, impurity center, energy, band structure s a continuation of ear 19, 115i 1965)-., ABSTRACT: This i lier work (Opt. i rpektr Y with emphasis on the'influen of different impurities on the exciton ab orption 7 ce s The ZnTe tingle crystals were prepared by a technology described in tbeearlier papeka The impurities vereadded in the melt. The influence of theimpurities In, Ga:,'and- Cu with large concentrations on the intrinsic absorption edge of p-type ZnTe was, in,-:,,. vestigated-at 300, 77, and.20.4K. The optical mea~urment procedure was described in the earlier paper. lAt the concentrations used (1.6 x 1019--1.6 x 1020 cm-3), the indium and g~~~ities cause vanishing of the excit.onabsorption and a -shift 19. of the edge to the long-wave side. The copper impurity (concentration 3-5 x 10 cm73) had no effect'on the absorption edge or on its fine structure. The disappeir~-'.~-.-, ance of the excitons and the shiftof the absorption edge sis shovn by analysis to bell caused mainly by the effect of the impurities on the energy band structure of the Card 1/2 5 -34 -548-0.  ..:L 24286-66 ACC NRs Ap6W7001 semiconductor. The iauthors thank M. S. Brodin for help with the workp and V. L. Broude and K. T. TovstYuk for valuMble discussions.~Orig- has.. 4 fi art. guresp~:'.-- 1 To-n-mlaj and I lible. SUB CODE: 2D/w SUBM DATE: koet64/-' ORIG REF.. 0061- OTH IMF: 005'.,~,~F z. A ? Card 4,  Hun WISIOU1004141 U41mosiow A- A-L-4-L-S.-k-l- k i~o 4 tu. C401 014"19113 AND 011,0090111% .014 4- Y4. Budd 110-MMM 13* In ameaml golb ' Cu. A m rrY Wd . y of 9 woo goo aloe aZ~ INITALLUKKAL LlTi!R4TURt CLASIMPOCAU011 l too U It AV 00 is 0 T 11 P a I, a I,aa a It a it IF RItait I aft MI L: I If tw0it I I IN NO 9 a a 3 gas OP  A 187 Al.& IND C410161 no Apso arm coplof PSfXIUI5 A.Q, P*C*INP9S W112 -00 - 00 fig 0011- -00 0 0 0;0 Ago* 004, 00 0,0 0 Sliv, 1200 j~od ppig. with N11.011. t o 0 009 goo qo 11100 AIn-ILA MITALLUR64AL LATER.A.TWO! CLASSWICATIM w0 IM 0 1.0"Ove Isiffoo "it 4". Gas NILL11 m mV Ail , a AV 00 " ZA A I a ad a 0 v I ff a 9 AN 0 3 a i t, 1, 0 41 91 Is AV; Is foo 0 0 l 1 , 00000000000004.40' 00 00000OW00000WOO 0 ~ 1 - 1  -J7 5 CJ p l()301. Dabccrad,crv -'Lcr _jjr. -T-'crairfLan ~Jentlral institutp nd of oery'101~~- ~Irr Receiled 10 Feb '919 P,eT-,O--t U-!,',',14, 3 Jan 1952.  ~T T "The Synthesis of I- (p- Ctgphe nyl )2- (,;'9-1 thylaminc., )-Pro nallie (Veritol)" Z? Tj~ajj7 10, JTO. flur Cbshch.. 21, 1940. Laboratory -..'or the Synthesis of Hormones, MIxedirian Cen',ral Ins'Litute of En_-ocrincloL7 and !teceived 2"S Ya~l 1940. Report U-1612, 3 Jan 1952  "The Derivation of Certain Yirlidine-Sulfamides and, 'Kylidirie-Sulfo Derivatlives of Aminopyridine," Zhur. Cbsllch. 1121im., 10, No. 23-24 1-940, . Department of C-T-gw-dc Chr-rustry, Mcrainian Institute of a-c7erimeental illedicine. iecei-!,red 13 lirune 1940. RePort U-1612, 3 Jwl 1952.  W !4) 0 a 0 * 0 0 0 a 69 1 1 0 9 06 (& LLLLLA_A__1 A so .4 Sme lidin I rt S::~xylidin rivistlysis Z.. F Rodionovsk-aya' (194()).-Tbe f( 00 a "Itlityl-"Celau dimethyl-ls-arctg 0 '11"Iethyl-&S"lin 00 1. 12,4 - diforthy !N. 2.6-dimall 06 -.5-dintielity14-a '00 00 09 -a and "Ildinowifoold do- A- YJ6 SaTiUW and B. 1. v. (U. S, S, R.) 10, 2W, 1 d$. were prepd.: 214-W- 'any) chloride (1); illonamilde (U); 2,4. Lamide (Iff), 142,44. ,limethyl - 4 - aretamidophenyloullonylaml pyridine (VIU): and 1.(2,5-dimcthyf4-amhwphenyw~oullonyl- amino)pyridine (EK). I was obtained by adding 32.0 g. (0.2 mol.) 2,4-.NIrsC4IINJfAc during 50-60 min. to M.5 inf. (1.05 mol.) freshly distd. T CISOA while mixing, UNle further mixing the reaction mist. was beated for 1 fir. at 80* on the water bath, then poured over ire. The li~ virldwa4TIr (MVP m 1334". flytheassuemethod rhic in 156-8*. NIIj -win. (M MI, 26 woo adualf 7 g Y lri;ii io'74 C. of freibly prepd. 1, will shak .ng. An I appreciable bmt evolution was noted. The reaction was frupleted on heating the mist. for a short time an the water bath. The ppt. obtained on cooling was filtered i and washed with water. After reerystc. the ppt. from dil. 21c. gre 11 was obtained, tn. Z"'. The yield was 21 K. (4.8 g.) was Wiled with 33 nil. HCJ (d. 1.013) on a -Andballiforlbr.20ruin. Acry-A.ppi.septi.oncooling. I L A .1TALLURCACAL LITERATURE CLAISLOICATION 91no.0 -1 IsIcso IF CNV all It wag dixonlytil in If 0 and a 10111 wKlauln. "A,, ed.ird to a weak alk. rest= Thr f1l pritil. wa% filtered at once and was wasbed with ligo. 'I'lle yield was;1~2 a, (11111%theory). After fecrysts. from 1110colorless needits, in. 187-8% were obtained. IV was obtained by adding 14.1 g. I-aininopyridine in 170 mi. of hot arriont: to 19.6 t.nfpurcIIinl7Otttl.ofliuta"tnw. Thettactionmixt. wat mitred. while, heating to boiling, (tic 6 lits. on a water faith. The liquid layer. was pourrd off the -1x1. ppi.. which was extd, 2-3 times with brusene, thrn with x1c., fill cred and wo4hed oilaln wit Is vic. TheyirldwilsI4.3i (about 04M. (:okvrlc?A crrtlal.4, tit. 2M,iF V, were oh. Iained oil recrystil. front Rio. IV (n.-4 x.), it% lim toil IICI (d, t.08), was builtd on a sand bath for i In. 15miu. A small amt. of crystals septi, on t-mlinig. To the inixt w1ut now added a It)% soda wit%. to a weak alk. reaction and the total ppt. was filtered and wailied with list). The yield was 5-1 X. of V (fN17C.). I.Ightyellowi-herystalI. in. 244-5*, were obtained on retTysts.' froul water, VI wati obtained from :1.1 it. 2,.i4litnethyl-4-aLvi4inidoben- zene-ndfonyl chloride by the proi-edure of It. The Yield wlorlr~s, 4iiny vryvtaI4, in. 242 V. VI waj 7.7 1. ul t (12.1 Jr.) W23 boiled on the %and bath with 8A ml. of IICI (d. 1.08) for 111-12 inin, The wpu. of the reaction prod- net began while the inixt. was boilcd and wa4 completed on cooling. The pin. was dissolved in 11#0 and a 10% %ad& soln. was added to a weak alk. reactium The prit was filtered and washed with 11,0. The 3rield was 8 S. of V11 ~80%).. .Colorless Lry-stalls were obtained on- re- bOWLnv U U Al 10 111; ; ; ; , ; I g' '_ ; %I ; ~ (-1 1 It a it :r 0 0 0 0 0 0 a 0 0 41 0 0 JL_O 0 0 Ole 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 a it U 13 W 0 is IF L-A- 2 -A _1~ _11, ,-- I J_ 1", 7 U-1. Sta-loy, _P0111 VILL11 GIK Q- III An I a (W 0 a N1W9l*jj4~1 Tom, 41111111 0 0 0 0 0 0 0 0 0 0 0 0 a 0 0 0 a 0 0 0 0 0 0 0 0 0 * 0 0 -00 -00 -100. -00 wee 0f& use to 0 see ;;Of see 299 No 0- =90 Ce 0  0 troto HiO, in. IW-w()V. I-Aminopyridine (7.44 19 in 15 in[. hot acetone was added to 10.4 C. of 0 W V 00 in 75 mt. of hot acetone. The reaction mist. . h W 00 09 to beilinic for 6 firs. on the water bath. while stirring. ne liquid was pawed off frogg the formed ppt. whkt was 00 cxtd, -1-3 times with beniew. then with sic. It was ' so The yield was 10 g. of VIU 61tefed and washed with &1c. 00 i8g%). Shiny crystals. in. 243."V, wrreolitainedou so rtaysig .frum 11:0. VM (0-32 g.) was heated with 1.2K * 00 for 15-Z) ml. IICl (d. 1.05) on the water bath st " 00 train. A 10% scxla soln. was added, an cooling, to the 00 reaction inixt, to a weak alk. reaction. The selid. cryst. 00 s fillered and washed with IfoO. The yield wa,% p o 0 0 recrysts. CK ftoin dil. a1c. It m. 217-18' f ~ 11 ~ 1 James 1. Lichtin d e, niq 00 0 00 00 00 00 00 0 00 00 00 09 00 06 00 00 L 1 0 0 1 9 0 0 0 0 0 0 0 0 0 0 0 0 0 00 0 0 0 0 0 0 0.0 0 0 0 0 0 0 6 4 0 9 0 * 0 0 0 0 0 00 0 * 0 0 0 0 0 0 0  000 0 01 0 0 0 0 0 0 0 0 111 0 0 0 0 0 0 0 0.01 00 0 960006096069090900 IT CK At 0 X L a I W A 6 L A b I I . . . . . . LITTgn 3-0 -10 41- 000#21 r. GSOLWS sun I ~~VESLALS wil- 1:0 Rreal 040 OSP 00 000 so 0 OR 000 C. 60 *001 0.ipw ii"uX Aq 3uptiv 03 P3.)Ilpaj "q1j"I 11 00 see npaj l9all-IlAdaid -jArjaq"%0qj*u#-tOl If()-3Y Of ad qllAt;v-l 00 dA'z M-t -1t6 I q3 V wee 0 0" CROM Sillaid*91 OUT 221132-094 SNIC" "it G"V OK Mova CNI oxv &I I I OR w Y4 A ". 18 00 .11 am a, 11, .3. Is "I __41 As 0. It lp It a a 4 1 i W, ; -W 4 Al a J. A J~  *all 11111 A 11, P Is i YJ TI 1) Ts I, ry ~LT-' 7i 1 3 1 - 3- s 1;! z v - -- ze ' 1 06 A 7 4 0 -q- 1' 65 prli~'tic~ ' ~i 3- lla ll Wd b"W 00 ) -su u A orAu e. A. Vs, ' " an 1. Rudlonriv%kaya. J. rx. Mem. 1 17, 14.11-1 (h);7)(in RUSA;kn). -3-Amin- oo I n' vAtIms0c (m. 243-41") (19.1 s.) III ON) -- Nfc,CO wilt a of ; t!! iy1drit lowly to It.(% g. p-AcMICIll. ILhCI in th) cc, 1 d 4 fi d dild h 11 0 h il C I xv rs.. an . %it en e , M" O, t , oo a ving VTI:; 3 .(,V- -a, ef ybotf., wild I.Wr. 111, 2113- ' lld. litOll). licavet"Sli"ll I,;%, N* Idecollip".) (fli"It ' -dt. ucith~ IICI. ltio, III, -1k.11 b~inlc tivily -.ti- did * 00 rhe Ac desiv. in '21A.5 cv. I I [it la,t,my. Q 9 wa% refluxed 2 hrs.. cMed. treated with hot 2.51-~ IICI 4D after filtration, littered hot, anal the filtrate inade slightly =00 alk. with 101~ Xa,CO. to yiAd M.5~ 3-jm1favii1,im41,,- e r 111~2112- 4' (frolo (fit. 14011). W'I. ill .111. IICI. oe -00 are Zf it ~ F :-o 0 voo is I ASS-SLA SITALLUOIGICAL LITIFIVATIAE CLASSIFICATICIP Lee u Vs 1, .0 is .1 "1 a ft ; ; I An I I a pw 0 ~1 w -9 ~ff to It 0 0 0- 0 0 9 00000 go 0 o e gee *I* o 111loe* i goo 0 0 0 00 0 0 fees 00*000 000000 *-*-a a a Ito of 41000006 goof* o so qf  Dilath estrals 7.T. P, gait,  4~1. g;Tll. -- - -, - - P. 22,1 QWXfn Ru-+-- IT, bath ws. pcl7memrd by ~,Cinr TbeTe tre ij;cl trd Lqr~x--4- -e it IV ~o, 238 M~ C4 l4iids ftaving Lac = ;:5 dzj :::z, A's R" .;" i43f 2~ 'V ~!m~hee F-He,:   A 514 -A "All all 11311110j"~ oil !u1.1 Ok lip I 31 "if s I , 111j Wita F, A II I I    LOGE,'OV, Mariya Kapitonovna; LURIYE, Dzhan Aliyevich; I'I7,1,JIUVSKIY, Mikhail Illich; ORLEAITSKIY, Yakov Pavlovich; SAgIISKIL, -Axon- Yak93~~ SHUBIN, Vladimir Petrovich; ICTUO, M.N.y k~. T-ekhn. nauk:, retsenzent; POIYAKOVA, D.I.,red.; BYKOVSKIY, A.I., red.;GORITIOSTAYPOLISKAYA, M.S., tekhn. red. [Album of equipment for the mechanization of foundrieslAllbom sredstv melchanizatsii liteirjykh tsekhov. [Earl 1-1 K.Loginova i dr. Mojkva. Mashgiz, 1962. 131 p. IMIA 15: 10) (Fou~driet3---Equi,ment and supplies)          Vr~ROVU7, A.; Everyone for the,col-lective, the collective for evei-Tone. Av"I.transp. 43 no.11:1.0-12 N 165. (MIRA 18:12), 1. Direktor 9-oy avtobazy upravlenlya mezhdugorodnvkh perevozok Glavnogo upravieniya avtomobillnogo transporta larjobiltellnocro,komiteta Moskovskogo gor(-,dskogo Soveta deputatov trucbrashchikhpya (for Varoblyev), 2. Glavnyy ek-oncmist 9-oy avtobazy -upravleniya mezhdugorodnykb perevozok Glavncgo upravleniya avtoviobiltnogo transparta Ispolnitellnogo kmuit~!ta Moskovskogo gorodrkogo Soveta deputatov trudyashchi-khsya (fcr Savitskiy).  on. LA. C,.. 4 C11111"s nral"IfLix YCTPOGCTB JL OL C~ IL OL %.- BI. f2 -- (c If) A* 16 q2CM) IL OL R~-A A T. ?-.-. A. C. I."- L M. C-." Np- RD r. a. 4-M 0. K hi- -F-- L CUMMIS NPODOANOR CISIN . . . ..... Py-,.- It IL rp.- 12 7 Ic in - 10- Is-) lope .b"vg tin, im, cmenial meting at tin asioutiris viesmougimL sustaty at man ftommue MA 2101WUML cowmalestione is. A. 2. Pop" C~2), amew, 8-22 J%W.  PHASE I BOOK EXPLOITATION SOV/5245 Ministerstvo svyazi SSSR. Tekhniche5koye upravleniye Novyye razrabotki v oblasti radiosvyazi i radioveshchanlya; in- formatsionnyy,abornik (New Developments in the Field of Radio ~Communication and Radio Broadcasting; Informational Collection) MoIscow, Svyazlizdat, 1959. 80 p. 11,500 copies printed. (Series: Tekhnika svyazi) Resp.,Ed.: A. S. Vladimirovj Ed.-: V. I. Ba3hur; Tech. Ed.: G.'I. Shefer. PURPOSE: This collection of articles is intended for technical per- sonnel concerned,with the development and operation of radio communication and radio broadcasting, COVERAGE: The book contaIns, according to the Foreword, information on new developments realized at the Gosudarstvennyy nauchno- issledovatel'skiy in5titut Ministerstva svyazi SSSR (State Card 1/3  New Developments in the Field (Cont.) SOV/5245 Scientific Research Institute of the Ministry of Communication USSR). Radio communic*ation and radio broadcasting apparatus are described. Several articles are concerned with the development of new checking and measuring instruments. No personalities are mentioned. There are no references. ,TABLE OF CONTENTS: Foreword 3 Savitskiy., B. 1. Receiving Equipment for.Radio Relaying of Ultrashort-Wave Frequenby-?WfAlated Broadcast Programs Simonov, N. A., and N. V. Deryugin. MAK-57 Automatic Control Receiver for Short-Wave Main Communication Lines 17 Mashbits, L. A. Instrument for Testing Radiotelegraph Channels and Equipment 37 Card 2/3  New Developments in the Field (Cont.) SOV/5245 Prokhorov, A. M. Instrument for Measuring Group Delay Time in Superhigh-Frequency Range 49 Bobrov, A. I. Generator of QS-R-60-Type Signals With Calibrated Output Level 59 Rabinovich, 0. 1. Heterodyne Wave Meter 65 Fomin,,M. V. Installation for Calibrating Superhigh-Prequency ,Attenuators Gurevich, M. V. Ye Belovitskiy, and N. V. Deryugin. -Elec- tronic Copying Device for Reproducing Electric Pulses of Arbitrary Shape From a Drawing 75 AVAILABLE: Library of Congress: (TK6563.R92) JF/dfk/ec, Card 3/3 6-15-61  sov/lo6-59-1-5/12 AUTHOFO Savitskiy, B.I., and Kotikova, R.A. TITLE: e Selectivity of VHF Broadeast,Receivers.(K voprosu. ob izbiratellnosti,radioveshchatellnyl~h priyemnikov v poddiapazone UKV) PERIODICAL: Elektrosvyazl, 1959, Nr 1, pp 38-43 (USSR) ABSTRACT: According to the present plan,for broadcast coverage of the Soviet Union, a four-programme scheme is foreseen for the band 66 - 72 Mc/s in the European part of the USSR, and a six-programme system in parts of the most densely populated multi-radial territories using*supplementary ~bands 64.5 - 66 Mc/s and 72 - 73 Mc/s. The first of these supplementary bands can only be used when the two T.V. channels areabsent. Rather close.spacing of the channels is envisaged with a minimum spacing of 575 kc/s, which should be adequate for present and earlier receivers. Interference must be considered not only from other stations but alsoby means of tropospheric scattering. For fairly distant ultra- shor t-i~rave stations, distant perhaps 600 to 7,000 kilometers, the experiment Card 115 has shown that a disturbing station.with a different programme must be spaced at least 20O.:kc/s.from the  sov/106-59-1-5/12 The Selectivity of VHF Broadcast Receivers desired programme, while if the programmes are the same interfering stations need only be spaced more than 100 kels avray. In the Soviet plan the spacings envisaged are respectively 250 and 121~ kc/s. However, these figures, were arrived at without taking account of.tropospheria, interfere-rice. Since transmitter instability has rendered common channel working impossible even if transmitters are separated by considerable distances, the spacing between channels has been made not 250 kc/s but 25 kc/s and this., has increased the danger of interference by distant stations. One result of this re-allocation of fr3quenalles i sal of the selectivity necessary in V.Hffl~ s re-apprai Now the interference may be expe-2ted for receivers. I t, channels spaced at 12', 1507 175 and 200 ka/s from 'hod of measuring selectiv4tv Mu S t wanted station. The met L j also be examined. The singla-signal metthod consists of the following steps. A receiver is ti-Lned to an incoming signal from the GSS-Chm w i t 1h, 15 1E cs deviation modulated -with a frequency of 400 or 1000 c/s, Ut, U - equal Card 215 and input level is adjust-ad to gi-~;-e an p-tput powe- to 10% of the nominal output. The procedure is repeated  sov/lo6- 5Q, - -.L'-5/12 The Selectivity of VHF Broadcast Receivers + 250 kc/s from the centre frequency. The selectivity is f defined as the ratio o, the appropriate input levels. The selectivity measured this way depends bo-th (nn the characteristics of the JF amplifier and of the PITI detec- tor. The real selectivity of thereceiveris determined by the ratio of the.signal and interference levels at the output of the IF amplifier. A number of measurements have been iaade on mass-produced receivers of the class II type (Volga and Vesna) and of a higher priced model (Druzhba). Fias 1, 2 and 3 show the linear selectivity (amplitude ,frequency characteristic of the IF amplifier); character- istics of the FMI detector,taken from the grid.of the preceding valve; the transfer cliaracteristics of the FEL detector, taken from the input of the receiver;and the. transfer characteristics of the detector (the dependence of output voltage on the frequency of the input signal for a constant high-frequency voltage at the input of the receiver*and a fixed frequency deviation). Curva.2 refers Card 3/5 to an input of 25 microvolts, curve 3.refers to 100 microvolts and curve 4 to 400 microvolts. -I-LU is evident from the curves that in the case of the Volga receive-r the  sov/lo6-59-1-5/12 The Selectivity of VHF Broadcast Receivers shape and form of the linear selectivity characteristic depends on the input-leveland when this increases the characteristic shifts towards the high-frequency region. The bandwidth measured at the 6 dB level is 320 kc/s and is impermissibly la ge; the Vesna receiver has similar rg shortcomings And its bandwidth changes from 325 to 210 kc/s when the input level changes from 25 to WO micro- volts. The performance of the more expensive Druzhba receiver is more satisfactory. The bandwidth changes less because the effect of AGC on input capacitance is less marked, since the grid capacitance of the valve forms a smaller proportion of the total- tuning capacitance of the tuned circuits. In West European coup-tries and in the USA a maximum deviation of t 75 kc/5 is used and even in West German receivers the bandwidth is maintair-ed as low as 120 to.140 kc/s. Several recommendations are made: adjacent channel interference should beconsidered at., 150 kc/s intervals; a better method ofselectivity Card 4/5 measurement must be devised5 cir,~,uit design should be   SANKIN, Nikolay Mikhnylovich; TRUUOY, Yedim Ivanovich. Prinimali uchentiye: TIMOFEYEYA, G.Ya.; KHAHOY, B.A.;,SAVITSKIY,.B.I.. BORISOV, G.B., otv.red.; VORONOYA, A.I., red.; KARKOCH, K.G., tekhn.red. [Principles of technical planning of transmitting networks for television and shortwave F.M.broadcasting; information manual]. Printsipy tekhnicheskogo planirovaniia paredaiushchikh setei televizionnogo i UKV ChK veshchaniia; informatsionnyi sbornik. Moskva, Gos.izd-vo lit-ry po voprosam sviazi i radio. 1960. 93 P. (MIRA, 13:5). 1. Nauchno-iseledovatellskiy inBtitUt avyazi Ministerstva~svyszi SSSR (for Sankin,.Tranov). (Radio, ;Shortwave--Transmitters and transmission) (Television broadcasting)   20090 S11061601000101210031009 3 A055/AO33 AUTHOR: Savitsk-Ay, B. I.. TITLE-t Some Protlems Conne,ted With the Operation of Ratio Detectors PERIODICAL:, EllektroEvyazl 1960, go. 12~ pp~ 19-29 TEXT.- 'Ra4lio detectora are very often used as f. m. discriminators in modern broadcas,~ ultra shcrt wave receivers, where the quality of the sound and the noiseproof,characteristics depend, to a great extent, on the sup- pre5sion of amplitude jr~~,dulation within the limitsof the working frequency- b-and. The obje-_,t of the present artliQle is, therefore, to.examine some pro- ,blems relat-in.- to the operation prInciple of ratio detectors, which have not yet been discussed, all leasl~ in a 2,aff ici-Antly romprehensive way, in tech- ca _t_ l4---at-;_,re, and-, in partit~ular, the problem of suppressing amplitude modulation, The auth~2r first deals with the phase-shifting transformer and the tube preceding (this assembly is named by him "modulation-mode con- He works cut simplified formulae expressing the output voltages of this converter of f, m. into a. m., and uses,these formulae to derive. the conditions ensu.riag the linearity of the static characteristics-of the Card 1/2  20090 ~S11061601000101210031009 A055/AO33 Some Problems Cennented Wi-.h the Operation of Ratio Detectors converter. He then examines the typical a. m. deteation circuit (bridge circuit) in +-he xatio deteetor, and, in parti,~ular, the part played by the bridge balanze in the relative suppression of a. m. Then, defining the co- efficient .)f relative suppression of a. m., lie investigates the possibility of improving this coefficient by means of adequate dynamic variations of the parameters, of the first and the second circuit of the phase-shifting transformer. Emphasizing the necessity of an increased suppression of a. m. at the eldges of the working frequenoy band, he proves that this result can be achieved owing to the compensation of the a. m. effect by a dynamic va- riation of the effecti-~-e attenuation in the second circuit of the phase- shifting transformer. He finally reccmmends as suitable and expedient the use ef a separate control device for the dynamic suppression of a. m. There are 6 figures, 4 table and 4 references, I Soviet and 3 non-Soviet.. SUBMITTEDi March 31 1960 Card 2/2  czst~,~a~'-ior; ol' tl~c Dertmcti(- 0- pi:7~ -L tons in an Automotive Two-Cycle Diejel Enll,-,.-~ne.ll 'Clandl 'fr~ch &ci, :toscow Autombile and Roa,~ insi, :L7,enj. V. :,TO '1010-I'lov, ~Iin Hi,