68709 0 C-4) S/069/60/022/01/021./025 ,6 7 Id c2 0 D034/DO03 AUTHORS,-, -Yurzhenko, A-I.,, Ivanchov, S.S. TITLE: The Effect of Fatty Acid Salts on the Process of Sty- rene Polymerization in Emulsions PERIODICAL.- K 11 'd zhurna.1, .1960, Vol XXII, Nr 19 pp 120- 0 0 1 n S 1 (U 27 R ABSTRACT. The authors report on a study of the effect of sodium salts.of.fatty acids (from sodiu%.formate to sodium palmitate) on the o1 merizationikinetics of stZ Ze. _ne in an emulsion. This selection permitted study of the effect of the hydrocarbon radical of the anions of the added-salts-on the polymerization process and eva- whigh is luation of their growing'surface activity., - of practical value. The technical emul.sifiersKof the type of fatty acid salts as used in the synthetic rubber industry often.represent a mixture aff salts of various Card 1/4  68709 S/069/60/022/01/021/025 D034/DO03 The Effect of Fatty Acid Salts on the Process of Styrene Polymerization in Emulbions higher and lower acids. For their investigation the authors purified the styrene specimens from inhibi- tors by processing them with a 20%, alkali solution and subjecting them to a subsequent threefold vacuum distillation. Nekal served as emulsifier, and potassium persulfate as initiator of the polymerization. The sodiiim salts of different acids (propionic, lauric? etc.) were obtained by neutralization with sodium ethyl- ate according to the method of W. Harkins tRef,, 8_7. Polymerization was carried out in a dilatometer with magnetic mixer, as shown in Figure I (diagram). In contrast to the dilatometer proposed by V.A. Puchin and T.I. Yurzhenko ~'Ref..9-7, the capillary of this device had a free exit for gases which in an inconsider- ,able amount could form dur ing disintegration of the Card 2/4  68709 S/069/60/022/01/021/025 D034/DO03 ~The Eff eat of Fatty Acid Salts on the Process iff Styrene Polymeriz-at-i on------ An Emulsions initiator (K2S 2 08) in the polymerization process. The investi ation has established that, according to their effect ~regularly changing with growing length of the hydrocarbon radical) on the process of styrene polymeri- zation in an emulsion, the fatty acid salts fall into two groups: group 1 -,salts of acids higher than capry- lie, continuously increasing the speed of the process when introduced into the reaction mixture; group 2 salts of acids below caprylic, weakening the polymeri- zation process. An analogous effect of the investigated Onlt;n on the rate of initiation of the process and the ffiolooiular welt~,.hf-. of tl)o . formlvg polymers Could be observed, the salts O'.f group I DOI-ts' of group 2. after some initial increasing, blow dowti Card 3/4  68709 , S/069/60/022/01/021/025 1)034/D003 The Effect of Fatty Acid Salts on the Process of Styrene Polymerization in Emulsions the rate of initiation and diminish the molecular weight of the polymers. The indicated facts are connected with a change in the reaction zone, calied forth by the adding of the salts. The zone enlarges on inLrcduction of salts of the group 1. it narrows on introduction of salts of the group 2. Such an assumption agrees with the data concerning the change of the colloidal state of the emulsifier and the dispersity of obtained synthetic latexes, which take place in the presence of the in- vestigated salts. There are 1 diagram, 7 graphs and 11 references, -7- of which are- Sovietaqad 4-English. ASSOGIATION.i -1vana-Frailiko-t Kaf edra.- fiziches-- koy i kolloidnoy khimii (L_LyDy-5niv6:i~qit, -imeni Ivan Y Franko -'Chair, ~df Physical- AndJ- Chemi stry) - TT ED 61 Card 4/4  IHSKKO# G.7- I TURZ alcohols on the sol. ooege ry aliphat"m n sts9zate solutions* aqv.QO~Ls sodW (mm .7) ,fis,ct prim 13 ition to-nPleirature of 460. trans shur. 22 w.3.376-3U W-je Wedra Koll. su,4&rstveI- Iuniversitet im, 1,1vank0e 1 161VO-Wakiy CD 'Wimitio (Stearic acido fizicheskoy J kollOlAnO (Colloids) (A.1cohols)  82293 S/079J60/030/0017/002/020 B001/Bo63 A Sukmanskayaq I* V-9 Yurzhenkof ILUTHORS' d Activity as of the Thermal Stability an ides InvestigatYOn onlof the Di TITLEt the POlya~r ~.atlo InitiatOrsVin - ! 0 Acids (I vdrocinnami.:~ of the CinnamiO and 11 Vol. 3o, No. 79 pFRIODICAL: Zhurnal obahohey khimii, 19609 pp. 2108-2112 are,the thermal se of the present paper to COMPI he benzOY1 It was the purpo 'Of the diacylperoxides Of t s in- TEXT one another* The author stability and the initiating activity - and .he cinnamic and hydrocinnamic acids with the of t -CH-CH particular to explain the effect of groups and the Phenyl tended in tween the group -0-0 -CH -CH 2-9 Whi ch were 11 introduced be .es. The 2 d properties of the diacyl peroxid at n the above-mentione d s in chloroform radicalt UPO tion of these peroxi e - Icinetica Of the thermal decompOsl tion of the groups -CH=CH- the and 600 shows (Table 1) that the introduo 0 peroxide group lowers 70 dioal and th and -CH2-CH 2- between the phenyl ra Card 1/3  92293 Investigation of the Thermal Stability and S/079160/030/007/002/020 Activity as Initiators in the Polymerization BOOI/R063 of the D140y1peroxides of the Cinnamic and Hydrocinnamic Acids atability of the peroxide and speeds up its decompooition. The activation energy ol" the process decreases in the following order: benzoyl peroxide> > cinnamic acid peroxide > hydrocianamic acid peroxide.This indicates that the -0-0- bond is weakened in the same order. The authors of the present paper believe that this weakening is due to the weakening of the induction effect caused by the phenyl group. The diacy-1 peroxide is to be considered to consist of two dipoles which are interlinked and repel each othert Z/O 0-" R-C-0-0-C-R. Due to this fact, the -0-0- bond is weakened the moret,,-~ + the more the excess negative charge is localized at the oxygen atoms of the peroxide group. As a,result of the electrophilic character of the phenyl group, this charge in lower in the case of benzoyl peroxide and thus increases its stability. The introduction of the group -CH,CH- and especially the group -CH2-CH 2- reduced the effect of the phenyl and thus weakens the -0-0- bond. Consequently# the stability of the peroxides is .also reduced. A comparative study of the initiating activity of the Card  82293 Investigation of the Thermal Stability and 3/079J60/030/007/002/020 Activity as Initiators in the Pol~merization BOOI/BO63 of the Diacylperoxides of the Cinnamic and Hjdrocinnamic Acids peroxides examined was carried out by the polymerization of styrene, which was initiated by means of the above-mentioned diacyl peroxides. It was found that under equal conditions, the rate of polymerization of styrene-I increases from benzoyl peroxide to hydrocinnamic acid peroxide (Ta-b1_e__2~_ just as is the case with the thermal stability. It may be seen from Table 3 that hydrocinnamic acid peroxide shows the most rapid reaction course on initiation, which fact is Jmportant to the synthesis of poly- merized plastics. There are 3 figures, 3 tables, and 12 referencess 5 Soviet# 1 German$ and 2 USe ASSOCIATIONs L'vovskiy meditsinakiy institut (~Ivov Medical Institute) SUBMITTEDs July 3, 1959 Card 3/3  S10791601030100910011015 220 BOOI/Bo64 AUTHORS: Kucher, R. V., Yurzhenko, A. I. TITLE: Oxidatio~ of But' ' ------n-e-a- -and' E-thyl Benzene in the Liquid yl Benze Phase in the Presence of Alkali Lyes, Cobalt Stearate, and Auramine PERIODICAL: Zhurnal obahchey khimii, 1960, Vol. 30, Ko. 9, pp. 2796-2604 TEXT: The present paper deals with the effect of caustic soda upon the rate of accumulation of hydroperoxides formed during the oxidation of a mixture of secondary and isobutyl benzenes, as well as of ethyl benzene in the liquid phase. It was shown that for butyl benzenes an amount of 0.1-0.2% sodium hydroxide has the highest efficiency; as for ethyl benzene, the optimum amount of NaOH is approximately 50%. Addition of cobalt stearate results in a higher rate of oxidation of the above hydrocarbons, with the highest possible concentration of the hydroperoxides, however, being reduced; this is mainly due to intensified decomposition of the hydroperoxides in the presence of cobalt stearate. The oxidation of ethyl Card 1/2  Oxidation of Butyl Benzenes and Ethyl Benzene S/679/60/030/009/001/015 in the Liquid Phase in the Presence of Alkali BOO1/Bo64 Lyon, Cobalt Stearate, and Auramine benzene and butyl benzenes is accelerated by a slight addition of auramine, the highest possible concentration of hydroperoxidea thus being reduced. The authors thank L. A. Baranovskiy for his assistance in experimenting, and mention papers by K. I. Ivancv (Ref. 3)and U..M. Emanuel' (Refs. 6-8). There are 6 figures, 1 table, and 16 references: 13 Soviet, 1 German, and 2 US. ASSOCIATION: Llvovskiy gosudarstvennyy universitet (Lfvov State University) SUBMITTEDi 1959 Card 2/2  3/06~/61/023/006/003/005 B119/B101 AMHORS s Ivanchov, S. S..,_Y4rzhenkc~~A,._j_._ TITLEt of salts of low aliphatic acids on the dispersion Effect J. of the emulsifi er solution and synthetic latexes prepared on their basis PERIODICALs Kolloidnyy zhurnal, v. 23, no. 6, 1961, 706 - 711 Nekal solution (sodium dibutyl naphthalene sulfonate) was mixed TEM V. with sodium salts of formic, acetic, butyric, caproic, lauric, and palmitic-acide in 'Various amounts (up tOC40.1 moles/liter) in the pres- ence and absence of potassium persulfate as initiator (0.4~',). On the emulsions obtained, turbidity measurements (photometer of the type ~M (FM) with nephelometer attachment) were conducted, as well as the d,etermi- nation of the surface tension according to k. Z. Kotukov and Ye. I. Lototskiy (Zavodsk. lahoratoriya 2, 1100, 1953), the viscosity, and solubilizing ability (on the photoelectric colorimeter MI-1 (MF-1) on the basis of the color intensity"of Sudan III solutions.and the solubilization of ethyl benzene by refractometer). The mean radius of Card 1/0 -,19  Effect of salts of low ... S/069/61/023/006/003/005 B119/B101 the latex particles was determined on the basis of,the light scattering of the dilute solutions. Resul"W's: According to their effect, the added aliphatic acid salts may be divided into two groupst (1) with low chain length up to and including Na-caproate; (2) with longer chains. With inoreaoing chain length as well as increasing concentration, the salts of tho first group oauae a turbidity increase and, thust an increase of the micellar weight of tho omulaifior Polution (partial precipitation of the emulsifier taking place at concontrationo of 0.1 molen/liter). The viscosity of synthetic latex also increases, whilre tho ourfaoo tonoion Ard rate of solubilization decrease (rate of solubilization without addition 8 - 12 hr, with 0.2 moles/liter sodium acetate 23 - 25 hr), The critical concentration of the micellar formation (CCU) of Nekal decreases with increasin,5 salt concentration (sodium acetate 0.01 moles/liter CCU . 7'9 10-;'~; 0~1 moles/liter CCU :,4-1o-3%; sodium butyrate at 0.01 Moles~liter CCU - 7.6-10-3~' at 0 moles/liter CCU - 3.7-10-3%). The solubilizing ability increases with increasing chain length of the salt, but shows a maximum for salt concentrations between 0.03 and O~05 ilq'oles/liter. The particle size increases with the salt concentration up to a content of NO.08 moles/liter, and then remains constant. The C.urd 2/6 ? ,7  Effect of salts of low... S/06Y61/023/006/003/005 B11 9 B101 salts of the second group lead already in smaller amounts to stronger turbidities and, thus, to an increase of the micellar weight, but they are only slightly increased at further additions~ Likewise~ the surface tension isstrongly reduced already at a low salt concentration, and remains completely constant at higher concentrations (over ivO.01 moleq/lite'r~ The solubilizing ability increases UP to M0.04 moles/liter with increas- ing concentration, and remains unchanged by further additions. The particle size of synthetic latex decreases with both the concentration and the chain length. The dispersion of the synthetic latexes is determined by the dispersion of the emulsifier solution used. Thus, the dispersion of latexes is variable within wide limits by suitable addition of aliphatic acid salts. There are 6 figures, I table, and 8 referencesi 7 Soviet and 1 non-Soviet. The reference to the English-language publication reads as followas H~ B, Klovens, ChOm. Rev. 47, 1, 1950. ASSOCIkTIONs L'Yovskiy universitet im. 1. V. Franko, Kafedra fizicheskoy i kolloidnoy khimii (L'vov University imeni I. V. Franko, Department of Phynical and Colloid Chamiatry). Odoaakiy universitot im. fdochnikem, Laboratoriya VyEjakomolekulyarnykh soyedineniy (Odessa University imeni Mechnikov, Laboratory Card 3/0'1' of High-molecular Compounds)  29118 s/on N, B1037B1 10 AUTHORS: Ivanchev, S. S., Xurzhenko, A. I., and Solomko, 11. 1. TITLE: Characteristics of the kinetics of,styrene polymerization initiated by tert-butyl peroxide and tert-butyl Derbenzoate PERIODICAL: Akademiya nauk SSSR. Doklady, v. 140, no- 5, 1961, 1079-1082 TEXT: The rate of styrene polymerization was studied at concentrationL between 0.01 and 0.12 9-moill of tile monomer, and at various concentrations of tert-butyl peroxide (BPO) or tert-butyl Perbenzoate (BPB) at temperatures _,1je1./__ and 119 0C. For comparison, the styrene polymerization was e'eudlod ~,'i tile presence of benzoyl peroxide (BP). Polymerization took place in tkie,~ Julk of' the monomer) and also in an emulsion stabilized with a O.2;-j Solvay solution. The kinetic conditions in thovo two canon wore identical. The,O.ependence of polymerization degree on time was found to be 'Linear only with'a low degree of polymerization of BPO and BPB (up to 20 - 30/~,). With a high degree of conversion, however 0self-acceleration of the proces,-setsln. At a polymerization temperature of a; C, the rate constant 3of the thermal decomDosition of BP dissolved in ethyl benzene, is.4-4-10- ; for BPB: Card 1/4 Y  2?~18 S/020/61/140/005/014/022 characteristics of the kinetics ... B103/B110 6.1-io-4. Under these conditions BPO is decomposed extremely slowly.. The dependence of the intrinsic viscosity [Ttl of -the polymers on concentration and nature of the initiatLors, decreases, as expected, i34 the sequence BP - BcB - BPO. With BP and BPB, the molecular weights of the polymers decrease, an the concentration of the initiator increases. In the case of BPOt the molecular weight does not depend on the concentration. The I TZ I of tile pol mers slightly increases with DPO concentrations between 0.01 and 0.10 mole 1 of the monomer. This contradicts the rule sayin6 that the molecular weight of the polymer decreases due to an increase in the initiator concentration. in polymerization initiated by BPO, ('q] of the polymers decreases bY 5&;f~ due to a temperature rise from 85 to 1050C during thp process. The polymerization rate, lioweverg increases by one order of magnitude. With a EP conversion of up to 5Wo, ETZI is increased but slightly. Above this degree of polymerizationi [?Zj remains constant. With BPB and especially with BPO,C-qlincreased evon at high degrees of conversion. if the polymerization temperature was maintained for some time after the process,['q] still increased considerably, even though the monomer was used up. This did not occur with BP. Such results are related to the high activity of the radicals Card 2/4  29118 _S/020~61/140/005/014/022 Characte-riaticc of tho kinatioc ... B103/B110 CH3 cil C-O* forming during BPO.and BPB docomposition. They int'Oraot W101 tho oil3 tertiary C atoma of the iiolymer chain: CHS CHS -~-CH2-+CHS-J- CHI- +ICHS - Thus f re e go lymer- -rad i c al s' -are- f o rmed -w hi ch cont inue growing- ~'n t he - presence of the mon omer. If themonomer is absent, the.free radicals combine and yield a.polymer of higher molecular weight. Unless the temperature is extiemely high, the initiator amount required will Still be pronent after the polymer-ization io fininhed duo to the higrh thormal stability of poroxidoo. A high tomporaturest bho initintor may bo u(jod up Card 3/4  29118 5/020/61/140/005/014/022 Charactorlutiou of tba kinetics... B103/B1 10 at the end of the process. In this case, heating does not affect the molecularweight, and C-1j] in thiu proceEts -will be changed but slightly. The high "initiating" activity of BPO and BPB is due to a kind of graft homopolymorization. There are 3 fieures, 1 table, and 5 references: 2 Soviet and 3 non-Soviet. The four most importantreferences to Engli~h- language publications read as follows: W. P. Hohenstein, 11. IIIark, Polyme!~ .Sci., 1, 127 (1946); E. Tromsdorf, E. E.-Schildknecht'? High Polymer ' 1.01 69 (19_~ P. Perry, M 21 . ~j6); R.' K. P. Seltzerg lodern Plasticbq.~Yj No. 39 7 . 1947"; J. H. Reley, F. F. Rust I W. E. Vaughan, J. Am. Chem. Soc-, 70,88 1(448)1; N. A. Milas, D. M. Stirgenor, ibid., 68# 205, 643 (1946). ~ ASSOCIATION: Odesskiy gosudarstvennyy universitet im. 1. 1. Ylechnikova (Odessa State University imeni 1. 1. Mechnikov) PRESENTED: Ijay 19p'1961tby B. A~. Kazanskiy, Academician SUBMITTM lvlay 11 , 1961 card 4/4  29822 3/020J61/i40/006/021/030 Bi03/B101 AUTHORS: X=henko, A 1. Ivanchev, S. S., and Galibey, V. I. TITLEt Thermostability and initiating activity of diacyl peroxides of par6ffinic and phenylearboxylic acidB PERIODICALt Akademiya nauk SSSR. Doklady, v. 140, no. 6, 1961, 1348-135t TEXTo The authorn atudied the dependence of the initiating aotivity of diacyl poroxided In homologoua .doriooi A) of Paraffinic acide on tho length of the organic radical, and B) of phenyloarboxyli6 scida'on the number of methylene groups between the phenyl ring and the peroxide.group on polymerization of 1~ styrene and 2) methyl methacrylate. Therefore, .peroxides.of 14 acids a) - n)) were:synthesized according to the methods of Ref". I _(seq_ below) see Table I and the legend below). The polymeriza- tion rate of 1) was studied_(dilatome-tricallv -mails and-in suspension, ) in and that of 2) in mass. Table 1 shows the rate co'natants and activation energies of the decomposition of a) - n), which were determined based on Card 1/5  29822 S/020/61/140/006/021/030 Thermostability and initiating... B103/BIO1 the rate of their thermal decomposition in ethyl benzene. Based on these data, it'has been found that the thermostability of A is only alighthly changed by lengthening of their hydrocarbon radicals. The differences in thermostability are, however, remarkable in aeries B. d is the most stable, whereaa the next pomber in the agriesp ap is..the least stable and decomposes rather quickly at low temperatures. Further on in the aeries, the stability of the peroxides increases. Thus, c is.closely related as to stability to the peroxides A, which corresponds to its structure. These data were compared with the kinetics of the polymerizatioa initiated by n) The rate of.generation of free radicals is a'function of the decomposi-tion ra--te-o-f the effects more rapid polymerization, whereby the molecular weights of the polymers decrease. Since the radicals are of analogous structure, their activity is, presumably, similar. To 1)t The polymerization rate does not vary analogously to the thermostability of the peroxides. The A are much better initiators for styrene than d. Although a decomposes rapidly, it is but'slightly active in the polymerization of styrene. A different 3 mechanism is assumed for the thermal decomposition of a. While the K-10 Card 2/5  29822 S/02 61/140/006/021/030 Thermostability and initiating... B10NB101 remain practically the s ame for A# the polymerization initiated by A does not proceed with equal rates. The rates of polymerization and thermal decomposition of the peroxides do not vary consistently. For instance, the molecular weights of the polymers initiated by d are the lowest in spite of the slowest polymerization. The molecular weight of the polymerd increases, whert passing to-b. The most rapid polymerization is effected by-A, the molecular weights being equally- the highest. These data do not agree 1/2 1/2 [K] 1/2 (1); with the equatipnas V = [k incr /k~ rbak] - kinit k~ /2 k1/2j.[M]/[ff]1/2 (11), where V is the polymerization [kincr/ lreak-' ini rate, [M]the monomer concentration, [IJjthe concent-ration-of the.initiator, kbreak , ki nor' -kinit are the constants of the breaking, increase* and initiation reactions, and F is the average len6th of the polymer chains (on ~re'aking by-radical recombination). This discrepancy is explained by the change of the breaking of the polymer chains on polymerization,_although, the total character of the free radicals is the same. The change of the Card 3/5  Thermostability and initiating... 9822 S/020/61~.140/006/021/030 B103/B101 concentration of the free radicals is determined in the stationary process as, follows i 'dR/d tk LIT] - k[RO12 - k [EM RI R, k [M012" where R 0 3 n 0 are primary radicals, M R polymer radicals, k , k k k constants of the n 0 2 39 4 corresponding reactions. Thus, the breaking of the chains may occur on interaction between primary and polymer radicals (benzoyl peroxide) and between the polymer radicals themselves. This is thecase for paraffin peroxidee, where higher rates and molecular" weights develop. To 2) Here, the kinetics agree completely with the two equaiiona and vary consistently with the.decomposition rate of the peroxides.' The're are 4 figures, 1 table, and 6 referencest 1 Soviet and 5 non-Soviet. The three most recent referencze to English-language publications read as follows: Ref, 5S L. S. Silbert, D. Swern, J. Ala. Chem. Soo., 81, 2364 (1959); D. F. De Tar, L. A. Carpino, J. Am.:Chem. Soo. 77, 6370 OT5_5); W. Kern, K. Kossmanp M. Rugenstein, Macromol. Chem., 1.~, 122 (1955). ASSOCIATION: Odesskiy gosudarstvennyy universitet im. I. I. Mechnikova . . (Odessa State University imeni I. l.'Mochnikov) Card 4/5  29822 S 020/61/140/006/02 1/030 Thermostability and initiating... Bl03/BlOl PRESENTED: May 19, 1961 ,by B. A. Kazanskiy, Academician SUBMITTED: IMay 10, 1961 Table 1 TaUe Is Rate constants XAOI npg 5 apu and activation energies ' UePCKKCb of the decomposition 3 5 73'. "G. C n,5. S5.0-C reaction of the peroxides. 4 no m i 4 44 2 31 n3K' 4 6 17 7 30 7 Legends (1) K0103 for; qnIPYK ' 2,8 (O'C) , 36.0(25*C) , 22.0 HKJIK , 4,3 , 19,7 , 29,0 kcal/mole; (3) per- (2) E c nFKK n-VMK 5.0 3 0 20.3 14 8 30 1 3t:o nnK H 4.7 46 t9,3 1 29,7 , oxide a hen la etio , enMK , 4 1 . 7 16 Q O t nK K nil 4:6 9,0 t9 0 30.1 1 30 c ; y p p , , ~ , , . b) hydrocinnamic, c)pherkyl- fnBK 4,1 16,5 30,0 ,nnnaK 4,7 19,7 30,0 butyric, d) benzoict nKAK 4,t 17,4 30,7 ogrICK 4,6 18,9 29,9 e) butyric, f) valeric, - -------- caproic, h) enanthic, g i caprylic, J) pelargonic, ~ k) cap rie, 1) lauric, m) palimit ic, and n) steario acid peroxide. ,Ca~rd 5Z5  5/069/63/025/001/co6/dca- B101/B186 0 F., Yurzhenkol,' Av-~I- AUTHORS. Storozh, G ------- TITLE: Effect of aliphatic alcohols on the polymerization rate of atyrane in emulsion FERIODICAL: Kol,'Ioidnyy zhurrial, v. 25, no. 1-, 1963, 77-81- IAEXT: -The purpose oftthis study was to explain the effect of organic Pkditives on the mice~lar structure of soap and thus also on the emulsion pplymerization of hydiocarbons. Styrene was polymerized in a dilatometer at 200C and a ratio of-hydrocarbon : aqueous phase - I : 9. Sodium s~earate (0-05 moles/1) or sodium oleate (0.1,moles/1) were used as A ed~igator. The reaction was initiated with,040,,~*' potassium persulfate calculatedfor the aqueous phase. The polymerization rate and the moleo-~ ular weight of polystyrene were determined. The effects of propyl#,butyll amyl, and hexyl alcohols in t~e presence of sodium stearate were studied At a certain concentration, a maximum of polymerization rate and of molecular weight occurred for each alcohol The"optimum concentration wit's 0.87 moles/1 for propyl alcohol, 092 moles~i for amyl alcohol# and. -Card 113  S/069/63/025/001/006/008' Effect of aliphatic alcohol~ BIOI/BI86 '0-147 molos/I for haxyl alcA61. The effect of chain length of the alcohol radical on the polym"aiization rate and molecular weight of the 'polymer was found to be the"same also in the presence of sodium cleats. The data Civen are optimum alcohol ooncentratioA'(Molea/l), maximum per min), and molecular weight.of the polymer: polymerization rate (,,3 Methanol 1.87, 0-95, 78750;.propanol 0-12, 0-90, 794501 hexanol 0*009p 1-47s 888401 ootanol 0.00751. 1.63, 104200; decanol 0.00199 2.05$ 123710- The colloidal properties of"the alooholic-aqueous'solution of soap, such as viaoosity, electrical conductivity, oriti6alconoentration of micelle formation, eta. change in the same way. Conclusions: The surface of the! alcohol - soap micelles is decreased by addition of small amounts of alkanols, Thusp the solubility of the.monomer in the micelles increases as well as the polymerization'rate.. Low ooAaantr tions of alcohols vihiah'_ a are surface-active substances intensify the stabilizing effect of soayj -but higher concontratio~q change the structure. A trupp nonoolloidal soap.~ solution forms in the presence of low-molecular alcoholop whereas a now soap - alcohol water~phaaa forma in the presence of high-molecular alcohols* The latter phase,,can be recognized by the-4.urbidity occurring after the addition of awyl,'hexyl,,or oatyl alcohol to the aqueous Card 0  025100119061008 51069~63 Effect of aliphatic alcohols ~ BiOl/ 16 solution of sodium-oleate. Both processes reduce the size of micelleas thus inhibiting the polymerization rate. T here are 3 figures and -1 table. ASSOCIATION:, -ve Llvovskiy uni raitet im. I., Franko, Kafedra, fizicheskoy i Volloidnoy khi:mii (Llvov Vniversity imeni I. Franko, Department,of- Physical and Colloid Chemist4) SUBMITTED: November. 20, 1961 Card 3/3  GALIBEY--V.Io; YURZIIENKO -A--I.--. IVANCHEV, SAS.- Polymerization of styrene initiated by peresters based on tert, butyl hydroperoxide and on some paraffinic-=d phenylcarboxylle acids. Ukr.khim.zhur. 29.no.12il282-1289 163. (MRA 17:2) 1. Odesskiy gosudarstvennyy universitet,,im. I.Mechnikova.  YURZHENKO.9 A.I.; VILISHANSKIY, V.A. Emulsion polymerization with surface-active initiation, Dokl. AN SSSR 1418 no.5:-1145-1147 F 163. (MM 16:13) 1. Predstavleno akademikom P.-A.Robinderom. (Polymeriziation) --(Surface-active agonts)  IVANCHEV, S.S.; URPjFN~O, A.1.1, GALIEEY, V.I. Evaluation of the initiating activity of peroxides in polymerization reactions. Dokl. AN SScR- 152 no.5:1159-1161 0 f63. (MIRA 16:12) 1. Odeaskiy gosudar8tvennyy universitet im. I. I.Machnikova. Predstavleno akademikom P.A.Rebinderom,  MKO., N.I. SOL(Y IVANCHETI S.S.; M~~M P~l ' rization of styr-ene in. em~ulsicn stabilized by a twe-=r- YMO- auro 0 ponent earalsifier mixture. xo1j. zi 2" no*6.*6'70-674 V-D 164 (MM 18-.1) 'I, Odesskiy univerditet.  IVANCHEV, S.S.; GALIBEY, V.I.; Charac teris tics features of styrene polymeri:adon at advanced stago, of convernion inltiate-d IPJ diacyl neroxide,5. VYsGkr4m. noed.*'7 no.1:74-70, -Ta ~1'65. (MILICA 28*5) 1, Odesskiy gosudarutvennyy univer-q1tet hrienl Mecbnikova.  IVANCIIEV S Sj; YURZHENKQ, A.I. (IUrzhenko, 0.1.]; ANISUIOV, Yu.N. lnfrared spectm of aymmetrical diacyl peroxIdon. Doi) All MIR no.8:1063-1066 165. iMIRA 18:8) .yy universitet.___ --l. Ode sskiy gosudarstvenn  I-r- P F c~ RM I "A,/09 7-33 -~65 1-~Q j /,)f,0 /C~60 7 14 3 1 A; 7, i: 1F S :'u-t-zhenko, A. 1. S I ra e mul s Or" Ki. ilc I F~ 6 0 3 - E. -D -4 r. i orl , !a Ic-x , a! p-l-I .,'i rile 1 1 Z d he 4~- f f 9 C. r h t i a y ~xl ~e.c on ~he k ne t f cs p o ly rn~-. r i z a t, i or i . Th i s ar-ticie I E. 3 cz t F 1, , F, I , ~ - , -, - ~ 7, 1- -jf stymne initiated by diacy ! per-,-x- Lis -:,n PC .-wric tic acils nd c ~m j n. i --api-jlic and palmy z,3'- :~In r-ate i ni t iated by ~.,:!nz(-v 1 ercy` Je ~-.:a t -,ie in diac, 11 perox,' des of al Ph at j r, ~,e a.-5s.-5 wi 11'4- an 2 enq,~--h -Df the carton ~:-hain f i g. i : f -,S T'~ es -~-2 e ]i c;pe r,3 i )i, in --)si syn-,het ic latem ch ar, e s i n t 11, e -,F Ile f c a ph-3 ~ic acids ( dibut~Y-F i and di - v i: cf r-x j -"~e F ) 7: h e L. 11 t Z-.3 r-- C I fn~e r i z a all a -re giv. at bu t as t h e r"n a c -  F, i T-,e 'i - t f a v, 3 r ab e i n t i a t o r-, c. D y me r ri - Q e-iec; 3~-e r peroxi-le and dienanth-vi. c)e-yide. - - ' ' i a-c"ivit~1 of hydroperoxide_,~ I iT - zi 4 S I r ; t , 'a Z- jj~ r -c s and I -able. T 'N 9 5 Mechrd~ova (Odk~ssa '-UB cc, DE : Oc  4 -alton The rate of t ion as a function of the cari)an ch3in length in the hydroccarbiin radical 'nined to the pemddat group  GALIBEvr9 V.I.; IVIPCILTV, Activity of f.-ee radi,:!ale f3-&g---j L7 tbe of diacylt peroxides dtrirg ehyrznr, pz;.'~rmer.~3itlcmz. Vysokemr. eced. 7 (MIRA 18s 2. Odeask-4y gosudaratvmny,  Pli V r""F1:1., V uF;,--.,7-;!,,*C1p A~ I. - ANis r-Mov, Yu.N. y n -PDZj-~C-5. ZKUr. fiZ. ~j 0 VI F;4!~ .-i" Ac? 16c:. ;nA 16, ,1., CoOftaskly gnsudarcotvonnyy unAversitch Imont Mechnikova.  ANTS13MIOV, Yu,N.~j IVANCHN7, ~Vantitatlvo deturrm4nation of diacyl peroxidea by lnfrared spectroscopy* Zhur. anal. khIm. 21 no. 12113-118 066 (MIRA 10, 21) 1. Odeaskiy gasudarstvmnyy universitet Imenl Mectmikovas  0- 'j SOURCE CODS: UR/0020/66/bO1066/1-3-42 1345 ACC NI, -AP6,023210- U'XHOR; FA Villshansk!Za, _11. 'Ia.; Yurzhenkoe At It -ORGI. ch ikov (Odesskiy gosudarstvaruW Odessa State University imo L 1. 1% n tot) TITLE: Characteristics of the process.of R21ymerization an emulsion stabilized ~in with nonionogenic emilsifier A :50URCEI Ail SSSR.. Dokladys v. 168, no. 6* 19662 1342-1345 TOPIO TAW i omwlaion polym. rlutiionj polyntyrond ATATRACT: In ordbr to clarify the influence of the hydrophilto he Molsoula of-ionogonia emulsifiers 9n the emuls on polymerization of P" of sty-ran the uthors 'Tp as amoun ahaied p2Yq2ZCo1 athers'l (products of condensation of nony: =ondr lith various of'othylend odacle) or the general formula I' collie- (OClI'-Cll').0l!. 0- where n 4, A, 13, 30. These emulsifiers were added in various quantities to the polymerization system, and the yield of polystyrene was measured as a function of time. This yield was found to be independent-of the content of amalsUiers with n from 4 to 13- In the case of n 30, the polymer yield rose with the emulsifier Con- Card 112  L 41219-66 t ACC NR, AP6023210 tent,, and the polymerization rate increased in direct proportion to this wntents L6olymerization. i--rom n = 4-13 to n = 30 there is a sharp increase J* Indicating a latex in polymerizit-ton rate, Indicating a definite Influence of the hydrophilic part of the emulsifier molecule on the course of the emulsion polymerization reaction. The viscosity and hence the molecularweight of the polymers increases with the degree of polymerization for n = 4 to 13, in contrast to n = 30. This suggests that the change in the hydrophilic part of the emulsifier molecule causes a substantial change in the topoohomistry of the polymorizationt when n = 4 to 13, the process takes,place in a dispersion of droplets, and the emulsifier acts only as a stabilizetb- uhareas in the case of n = 30p a mice3-lar mechanism of polymerization occurs, OrU. art. hass .3 figures and 2 tables. SUB COEE: 07/ SUM DATEI 120ct65/ ORIG REF: 0051 OTH ran- 001 rnrei o  IMF Tha es(4 of d1cpdrstfM d vyuOUfr-I~h far,-,tct t0 itct d4jmadence on ths' natum tnf~ e4neentlatind bf the 0 0 Chemical Abst. Atnufath" &nd men M r, lo gnd A Callow 1 (1-1 Vol, .1.8 Nc. 1 Imff-fationj _Set C A 4-7. ?X*91( Apr. 25, -!':)54 Rubter and ---thEr Mastomers  16 052 B117/B166 AUTHORS: Yurzhenko, 0. 1., Ivanchov, S. S. TITLE: Effect of emulsifier composition on the kinetics of emulsion polymerization of styrene PERIODICAL: Referativnyy zhurnal. Xhimiya, no. 24 (II)t 1962, 829 - 830, abstract 24P59 (Dopovidi ta povidoml. Llvivslk. un-t, no. 9,, part 2, 1961, 84 - 65 EUkr.] TEXT: The polymerization kinetics of styrene in an emulsion was studied in the presence of the salts of fatty acids havinG hydrocarbon chains of different lengths (stabilizers are sodium oleate or potassium palmitate).~ Addition offatty acid salts having > 8 C atoms in the chain was shown to increase the polymerization rate, molecular weight of the polymer and dispersion degree of latexes. The molecular weight of the polymer in- creases with the number of C atoms in the chain of the fatty acid salt. Furthermore it was shown that the effect of fatty acid salts, having 7-C-atoms, on-the polymerization kinetics depends on the concentration: small amounts increase the polymerization rate and molecular weight slightly; large amounts inhibit the process, reducing the dispersion Card   s/oSlj62/000/024/015/052 B117/B186 AUTHORS; Villshanalkiy, V. A. , -f TITLE: Study on the activity of emulsifiers, substituted alkyl pyridine derivatives, during emulsion polymerization of styrene PERIODICAL: Referativnyy zhurnal. Xhimiya, no. 24 (11), 1962, 829, abstract 2058 (Dopovidi ta povidoml. LIvivalk. un-t, no. 9. part 2, 1961., 81 - 82 [Ukr.] TEXT: This is a study on theldnetics of styrene polymerization in an emulsion stabilized with pentadecyl pyridine bromide and pyridine deriva- tives-subs I~Ycro- peroxide as initiator. Pyridine derivatives: Methyl pyridine with the methyl group in positions 2,4, and 3; 2,4-dimethyl pyridine and 2,6-di- methyl pyridine; 2,4,6-trimethyl pvridine; pyridine carbonic acids .(picolinic, nicotinic, and isonicotinic acids)'and nicotinamide. It was shown that the polymerization rate using theae emulaitiors is 2 - 3 ordora of maenitude higher than that in bulk# The moot active omulnifiers wore found to be those having an amide group in position 3 as substituent Card- 1/2   /081/62/000/024/017/052 B117/B186 AUTIIORS-~ Yurzhenko, 0. 1., Zareohnyuk, 0. S., Ivanohov, S. S. TITLE: Comparison of the initiating activity of some diacyl peroxidag on styrene polymerization PERIODICAL: Referativnyy zhurnal. Xhimiya, no. 24 (11), 1962, 830, abstract 24P60 (Dopovidi ta,povidoml. Llvivalkun-t. no. 9, part-2, 1961, 86 - E17 [Ukr.] TEXT: The thermal stability and initiating activity of diacyl peroxides of the phenyl carboxyl series (diacyl peroxide of banzoyl# hydrocinnamic and phenyl butyric acids) and paraffin series (diaoyl peroxides of dien- anthyl, dicapry 1y1, diperargonyl, dicaprynyl, dilaurin, dipalmityl, and distearyl) were studied during styrene polymerizatioa in bialk and in emul-~ $ion. In the phenyl carbonyl series, the diacyl peroxide of benioyl is most active and the diaoyl peroxide of hydrocinnamic acid, least. The thermal stability changes in the same way as the initiating activity. Diacyl peroxides of the paraffin series are more active than-.those-of the phenyl carbon series:, Polymerization is faster and the resulting polymer has a higher molecular weight. The thermal.stability of diaoyl peroxides ,,,-.-,Card 1/2.-.-   YURZEMOI P.'Iw AMUOUAI dayslopstntal. anomaly of the liver. Wrurglia no,3.77 54. ?15) 1. 1z khItrargichaskogo otdoleniya (zav.~- dotsent P.I.Yurchanko) ablastuoy-b 01-Initer--(glav JiG 31LIVER, ;Lbnormali ties, (AWBR=I S *hnxplasi&) *liver hypoplasia)  TtMZKIIIKO, P.I.#-dots. Surgical treatment of, benign tumoro and cysto of the madiastiWim. liov.lehir.arleh. ao.5:80-84 S-0 957o (HEU 10:12) 1. Xhirurgicheakoye otdoleniye (zav. - dots, P-1-Yuzhanko) Kherson- .skoy bollnitay. Adres avtora: Kherson, Oblaotnaya bollnitsao (KEDIAST LLAM-SURGERY) (SYSTS)  4. GRITSAM, D.E.; EUCHER. R.T.; TURIHMO, R.H. Pispersed electrolytic depositions of bismuth. Nw*.rsp.L'viv.un. 21:63-60, -152~ OLU - 10: 7) 1. Wedra tizicheakoy i kolloidnoy Miati. (Bismuth) (Slactroplating)  ZENUAINSM, 11.1,1 DRAGIft B#3.; pr1nirmli uchactlyo: GOLWITEX, A.A.; YURZMIKO S.A. Synthesin of Salts of sow O.,O-diaryldithiophosphoric acids. Zhur, ob.khim. 32 no.6:1962-1966 Jo 162o (14MA 15:6) (Phosphorodithioic acid)  0 9 a 6 9 9 0 10916 to 141OUI)LIfitit/ 4 to a III V, it if X. A ijo It. 12 Is III Isk v If Jos 40 9# &i a if 4no w 11 - - % . It I Q A A J. -1- 11 IM Is T. w ft -6 X_ -t 0 OFECOrst-ts -.f, 30 The -11-0 at edtoovirs oa 'A! p"plittiss of sodium. too tAviall Mbber. S. 11. Talmud Y'll'Alicako IIKII Yu. X. Va~ikvx~ O"pulitivir 41W kul~~t- I(,, t9u, WV, 34 45-15(41icnm ft"M COA lit fistemm4isle ,it. ah-arbent all. anthracirtir W, tic. J; firm by-produevi; 14 rwitiffruni pyirr4yqA 'tight (til, %alwilt, t4"cr tar and g7ren 61) and fivint j*iroleuni-eiracteing prnce~,.es (osidized 'C ptmi-dWillatr, unoxidUrd "acking kero- moo 00, wile, polymer and Winkler-Knell w4duc%) and wirabb" 00 '3 rmitiurs "e 1"trd to the taw litilil.., ftibber I(N)s S IjIlt, 0 nerrictrallar 1.75, g&* black W p4fl% by Ill wilevir 0 2,41 411 fillrd In (itwo Otllin lot 3itfill, The VII-anitAirs artir It'i"I fill IVIIIIHO Olvolith Ittl4i Itt'I'mr. and allivir coo gills in a C."y ilven At 70, ff'r 121) him, All ft"M11.4 sit, itinlitd. Tile, Ikel",leut" Itirmfilvtv llfvpi. Ily PyTrAY41% 0*0 iffiltmviril aging; tht- tithrr prndisrli wrrv ineffective. SOW -60 Arritard KllbtrX so-all 'as If x6e '00 114111, UZ~AL Lit CLASINFIC"I" 91- 41 Ificiro 'fit 4,_ 4114 41119111241; --$Mll its 0 1 r- 1-1 -- a s I 4 ill so "j; a It ill Ott* 4 0M a oe it .1 is 0 P to &41 4114101411 sect 0 as* @is 0 0 0 00000000 0 0 0 0 0 0 4 tiosee eel o id-soo ov 0 00 0 * 0 0 0 0 9 0 0 0 0 a 10.006 000 4p so** 0 g 112  tt is m is vt 17 0 a -,Aa A v Al it a a 54 5 '16 9 it a a -o7d" -4 -- - ----- ....... . 0!" #fbClClf9f AA4 f*CVO#ift$ :*-4f U4 SIM" 00 Cd- Att 't I "t fit the tbm ubm in C04. The TIM aw. WOR k4w~ ~T" n"w to the (A 00 '00 06 '00 3t 00 F,C-, k* 0 falcla q0 041 as% T Tim -m'W"s- u x 0 0 0 of 00 00 Ise .010000000 Of W41440 0.01  U 11 w 11 18 if A? 21 bill'ot 14VA110ifilt UU Ws a U Sow 4f UU ltfar* U-W- P-L-1--k-AA -K LC'M-M.A-ii 4' a b A _& Al - I -- - - ~w . -."~ .., ~-.? -00 '!"!C -1.4 1 C, Itairle'd %J", 'j flit I sist'l It toltv 044-tr '14-twes rt" 49 00. 0 Cal d't polymerization, 11'. utzholka. 0" N, toctuffM with Istwor wtwr feflsi'le; "Ith I - ill "A. '00 00 .4 6r"nit'v-0, and V. 11. Kh3ffwr~ ". Gem. Cke"t. W.S.S.R.) attalited In 11) ltrq,, tkith It ill III hrs. le!'"ll dells'. .4 -J( (tic di.tributioa Woorcrti 11W rate th-VIIII 1. 1 hlyth wtilet, o(Ill In The Ogive 31140, -90 00 W4ter an,l forg. Cat;il"i4 sof the WyInCrigatfoo '.,Yjl (A~j c *,4rl, ( V in C.11.), the 411hility decrtmest fit t~NIRY- Still rfl-I 0`1 the toorontxnti- the wder: I (uni"K4. rate colitt, At. it? mill.. 40 9 of 'j The I er lot) olAym titlaet' were ulu'le Oil 0 itsms. Still (-tK at fill,), V (it IV (k - 0001(14% 111 an't VI -00 00 a $Wfullifek.. trillictIlyfr2rtAnot hydrou-mille (1). dillit-th- fk - W-2113 and decoolipri, complete in fa-15 00 A plelblolewbi".1 by'lo-fi;vroxide fit): SAW), (%COsr~ aLtivs- min. in 1-11.5fl, saln.). M(K of O..r- N N.'s,CO. se- -00 fl !'~ 0) (111): HIP, IIV); K's-.0. IV); and 114-lis (3-57.. ;ill. celeratc-I the rate k4 dmitnpri. lot V11 trocroct insrkelly, *0 4 11`0 ;v1). thtribulinn cfwfy4. hrtwMI Water and '\2011 ~svncwhm ItLi. '01,011 Irs't; the effect wa,, *0 C.M. walir Amt W-Tvur' An't I",., 1 %1011 art-I i,4b- tterigly rutwitIml in a 3" Na lArste -Art. In the tame prear. 'Arte dirt'l, f'T 1, Ill. IV V, at 215 snd W". rnelliurn, the title 44 dre.rinpis, to( the highly qzNr M. nc content r'f the -aler-sol. pe"'nitic'i ill the Mg. pbue Oxweop (Utch all 1) Was much I(M" than the rate of tN4y- ollooll 0 wall it,"lmt cln-t' with firac tMt fell rapifly In Ch fnmfation: for M."Xides of Mcdium stability (,,uch as r** phSc, raxtirulirly at hilgher ternp. The Wy. of V) decror"I'n. W24 faller thin poly"W"tation, for the CICIVITA-1-d With timl, ill the .vs. folme, but Increased In low-tsbility IV. much faster. RM the formot stable Ill SOW wawz I w3. ahm.1 equally di~tioihultlf betw" water and VT. twilynIcrization nf i~oprcnr wwo (OFM to U4 after andthe'Wit. ph.4'elf inthelattcr Iemrnpn. to qxr.-h xn event thAt p,4ymefix&1ior% practically zoo -~Vee 't *)" 111wil alramircilietiflI