SCIENTIFIC ABSTRACT TEREKHOVA, G.M. - TERPILOWSKI, J.

MIKHAYLOV, N.V.; STRAS1910VA, T.T.; TERMOVA, G.M. Method of determining phosphorus in polymers and fibers based on them. Khim. volok. no.4;66-67 163. (MIRA 16%8) 1. Veesoy-uznyy nauchno-issledavatellrikiy institut iskuset- vennogo volokna.  TERPIM, N.I.; AI;GOtSXi.YA, M.A., direlctor. Hicrosco,'pic stiidy of the dynamics of extraction of alkaloids from the tiaeues of the belladonne~ plttrt. AT)t.delo no*4.-27-)O JI-Ag 13). (MLPA 1. Kharlkovekiy nauchno-ionledovatellokiy khimiko-farmutse7ticheskiy ilisti- tut. (Belladonaa)  TERPIW. 11. 1. Problem of improving of the processes for extracting medicinal vegetable rav material. Med.prom. no.2:32-35 Ap-Je 155. (HLRA 9:12) 1, Khortkovskiy nauchno-inaledovatel#ekiy khImiko-farmatsevtIchaskiy instituts (BILLLDONU, extraction of alkaloids)  TXRPILO, 11.i, Microscopic examination of pruning material from the tea bush. Apt.delo 6 no.6:26-28 N-b 157- (MERA 10:12) 1, Is Xharikovskogo nouchno-iealedovatellskogo khimiko-farmateevti- cheskogo institute, (TEA--ANALYSIS) (GAYYXINS)  TROPP, M.Ya.; TER 11 Purple hellebore. Apt.dalo 7 no.2:60-65 Mr-Ap 158. (MIRA 11:4) 1. Is Khar1kovskogo nauchno-issledovntellskogo khimiko-farmntsevticheakogo instituta. (HELLEBORE)  TIRPMO N PROKOPSIMOO A.P. M M A~, Oaltivated carrot ([Daucus ustivus (Raffm.) stoch]) Ig & now medicinal raw material. Apt.delo 9 U0.1885-91 4-7 160. (MIRA 13:6) 1. Is KharIkovskogo nattobno-Iseledovatel'skogo lchimiko-farma- tsevticheekogo instituta. (CAnM-THMUjPZM IG USA)  TERFILOt N.I. Microscopic analysis of raw Anabissis in the process of extraction. Med. prm. 14 no.7:47-50 Je 160. (MIPA 1338) 1. KhArIkovskiy nauohno-issledavatellskiy khimiko-farmatoevtiaheakiy inotitut. (AIMMIS)  TERPILO, 4astaslya Ivanog~a kand. biolog. nauk; VISYULINA, Ye.D., - -p-CHU-M PAK$ V.D., tekhn. red. (Anatomic atlas of medicinal plants] AnatomicheBkp- atlas le- karstvenrjykh rastenii. 2.., perer. i dop. izd. Kievp Gos. mod. izd-vo USSR, 1961. 361 PO 041RA 15:3) (BOTANY, MEDICAL)  TIR-PIIO. R.N., inzh. Rationalization of electric lighting of farms. Svetotekhnflm 5 no.2:24-26 F 159. (KIRA 12:1) I.Ukrainskly institut makhanizateii i alaktrifikataii sellskogo khozyaystva. (Electricity in agriculture)  TERPIL09 N. N.v CAND TECH SO It "4-*#zlrr"" AIND D VELOPMENT OF A RATIONAL SYSTEM OF ELECTRICAL I:-fQ"4)W -FOi CATTLE FARMS,#$ Moscowt 196 (JOINT SCI COUNCIL OF I" ME0J4AtlIZATIO" OF AoRICULTURE L- N')ON SCI RES lH4T 11VIM11 ELtCTRIFICATION OF AGRICULTURE "VIESKii"), (KLI 3-61t 220). 270  L 45182-66 Ili) ACC NR~ APG026460 SOURCE, PO/0038/66/011/002/0163/0176 AUTHOR Terpilowski, Janusz-Terpilov6hi, Ya. ORG: Depar,nient ofPhysicochewical St,vucLu.-,,al He8carch, PAN Wroclav" sti-uktui-*'a-'In--y*cfi--kANY---- TITLE: hermody amic properties of liquid metal solutions. The Zn-In-Cd and In-Cd systems SOURCE: Archiwuin hutnictwa, v. 11, no. 2, 1966, 163-176 TOPIC TAGS: EN11F, zinc indium cadmium system, indium cadmium system, liquid solution, liquid slystem, thermodynamic potential ABSTRACT: Thermodynamic investigations of Zn-In-Cd liquid solutions and indirectly of In--Cd liquid solutions ~vere carried out by the method of measuring the electromotive forcus of concentration cells of the following type: (O'bil LICA + 0,42 Xuj + 0;0~' 7.10A, Zn-In-Cd rneltell Wt-- liquid %oluUon Card 1/3  L 45182-66 ACC N" AP6026460 The subject of investigations were 15 liquid solutions of Zn-In-Cd In the temperA~ ture range 430 to 580C. In the reproducible limits of the readings, the values of.~'J EMF in cells varied linearly with temperature. The compositions of the investi- % r.- 14 gated solutions were expressed as atomic fractions of zinc (Nl), indiurn (N2), and.. cadmium (Nd. The EMF of the cells at 500C as (E500) and their temperature coefficients (dE/dT) are given in a *table in the original article. The values for the integrals of equations were determined. The results of the excess molar thermodynamic functions of mixing for the three-component liquid system Zn-In-Cd and for the binary one of In-Cd are presented. The author stated that the activity of zinc in liquid solutions of Zn-In, Zn-Cd, and Zn-In-Cd at 500C has a positive deviation from the Raoult law. The values of the activity coefficients for zinc are highest for the Zn-In liquid system, intermediate for the Zn-In-Cd liquid system, and lowest for the Zn-Cd liquid system. The Zn-In-Cd, Zn-In, Zn-Cd, and In-Cd liquid systems are characterized by positive values of excess molar thermodynamical potentials and enthalpies7of mixing for any one concentration of the components. The values of excess Imolar entropies of mixing are equal -to zero for three-component Zn-In-Cd liquid solutions with low indium concentration and for binary Zn-Cd liquid solutions. In Card 2/3  L 45182-66 ACC-NRt AP6026460 the liquid phase of Zn-In-Cd, the maximum for '.,dG- (excess molar thermo- dynamic potential), 'd~- (excess molar entropy), and I'Aii!- (excess enthalpy) appears at the 'same ratio of the atom fractions of indiu'' and 'c;%Ldmium m N2_IN = 1. The values of molar enthalpies of mixing for the In-Cd liquid system 3 .1 1 obtained in this work and determined by the calorimetric method approach each other (0. J. Klepa, Acta Metallurgica, 6, 1958, 233; F. E. Witting, E. Muelle., Z. Metallkde, 51, 1960, 226). Orig, art. has: 5 figures, 11 formulas, and 5 tables. [Based on author' a abstract] [NT) '�~DB CODE: 07/ SUBM DATEL 31Dec64/ ORIG REF: 006/ SOV REF: 002/ OTH REF: 015/ AM ird 3/3   : ~-, -, 1~ ".- -,, -,- , , ". :I r,,-: ~, ~ I ~~ ~~ i-1-11_1111~ I." ill .... .. 4' ~. ~ I ~ "-% I ~1-11 -12-1 , ~ , ~ ~.' i'. ~, ~;:, ..-- . A  ROM  I L i5w&-66 E4T(J)/EWT(m)/rWP't)/EW?(b) XJPW JD/JQ ACC NR: AP6001647 SOURCE COEE: UR/0051/65/019/006/0936/0tiSS AUTHOR: terpilovskiy, D. V. ORG: none TITLE: Afterglow in aqueous solution. of gadolini-.Lm salts SOURCE: Optika I spektroskopiya, v. 19, no, 6, 1965, 936-939 TOPIC TAGS: gadolinium compotaid, fluorescence, nonradiative transition, f4tvv'edds I I L) - r)- ABSTRACT: The auth considers fluOres 6cte In strongly dissociated aqueous solu- tions of radolinium%=s to determine the time of afterglow. A theoretical model is proposed for calculating the probability of normadiative transitions. The lan- thanonion is can-.3idered together with a hydrate stell whose vibrations are modulated by Brownian motion. Nonradiative transitions am possible due to the interactions between electron motion of the ion and the vibrations of the water dipoles. A formu- la is derived fox, luminescence attenuation. Calculation gives a reciprocal for the afterglow tim of 464.8 cps, which agrees well with the experimentally observed val- ue of 500 cps. Satisfactory agreement was also observed in the case of temperature .Card 1/2 UDC: 535.372  L 15oo8-66 ~:ACC NR: AP6001647 1~2- relationship; the experimental ratio of afterglow time at 200C to that at 950C was -6.06, while the theoretical value tras 5.64. The data indicated that the prcposed mechanism for nonradiative t 'ransitions in aqueous solutions plays an important part .for the trivalent gadolinium ion. The author is sincerely gratefu-I to S. A. Al't- ,shuler for guiding the work and to A. M. Leushin for valuable consultation. Orfi-.- art. has: I figure, 4 formulas. !SUB CODE: 20/ SUBM DATE: 28Sep64/ ORIG REF: 003/ OTH fEF: 005 ~Card 2/2  4T--~lpll,onsny, ]-.F., (;7.nd Tech '.ci -- (dir's) "stildy of th,~, jp:-~rfoT-.,,,,nce in pneum--tic removnl of roprocessed ndllinj~; pe~~t .I' ;Ansk, 195~,- 15 PP (1~iii of HiL,:her -rducation USSR. Belorur~:7-i.-!n Poly- tech Inc', i:.. I.V. Stalin) 1'10 copie:-, 109)  ~,TZRPILOVSKIY, X.F. operation of the intake section of the nozzle of a pneumatic Peat harveg ter. Trud7 ins t. torf. AN :3SSR 8:281-297 159. (KIRA 13:12) (Peat-Harventing)  TIRPILOVSKIY, X.F. Design of the nozzles of pneumatic heat harvesters. Trudr inst. torf. AN BSSR 8:298-308 159. (HIRA 13:12) * (Psat-Harvestir4s)  T -!,, -,. F I L ON S KUY, K,~- . k!~- Ronlatanco of a nozzle of a piloir.~Itic peat Yarvoa ter lurin : ,IC f lr,-,r of air and of peat-air mixture. Trudy Inst. torf - A2, :;33., 9:13- '6 160* (Peat machinex-r) ('el,11A 1/,:2)  lato o' t'.,e ovc -i'- o a atic 9: ]_,"'7_' 1 C:1.1A (F at !.,.ac:.i,.ir-,ryi  PIUNOVSKIY, I.I., kand. tekhn. nauk; ZHIVOTKO, B.I.,, kand. tekhn. nauk; RUKTESHEL', S.V.., kand. tekhn. nauk; SHTOMPEL', B.N., kand. tekhn. nauk; BUTVILOVSKIY, F.A.p lnzh.; KORZIEMSKAYA, R.A.9 inzh.; LDGVINOVICH, I.P.j, inzh.; UTEVSKkYA, L.I.p kand. tekhn. nauk; RUNTSO, A.A.j kand. tekhn. nauk; NAGORSKIY, I.S.p kand. tekh-n. nauk; TERPI;p , 4j.. kand. tekhn. nauk; LOSEV, V.I., kand. tekhn. nauk; YAROSHEVICH, A.A.p kand. tekhn. nauk; KATSYGINj V.V., kand. tekhn.nauk,, red.; BOROVNIKOVA, R., red. (Problems of the technology of mechanized agricultural produc- tion] Voprosy tekhnologii mekhanizirovannogo sel'skokhoziai- stvennogo proizvodstva. Minsk,, Izd-vo "Urozhai." Pt.2. 1964. 336 p. (MIRA 17:7) 1. TSentrallrqy nauchno-issledovatellskiy institut mekhani- zatsii i elektrifikataii sellskogo khozyaystva nechernozemnoy zorq So.SSR.  KUZNETSOV-FETISOV,,-L.I.; TMILOVSKIY, N.1r, laborator7 ultrasonic unit for physicochemical Investigantion-s. WTI no.17:63-68 152 [Publ. '531. (Ultrasonic testing)  "  111.1%; L.I. M.:m-ea in proj,ir'lioc j--' i'rill!nr, rud"s subject,~,-' to ullrnsonic W.Wfs. Trur!-7 MKI-M no.18:100-106 153 ~publ. 154.1. 12:11) (Oil well drilling fluids) (Ultrasonic wov3s-InCustrial a,)Plicatlons)  A, P. P A, 1926 Stud f jlcctrg=sl&lliWQv of mel4ld in on All. U$ irkand li Tui 'I il,Inil , I no. P-%1111198, Mechanism of the cff~ct of ultrasonic vibratiatu on clec- trodtposition was studied. Diagr2ms, graphs. 4 ref,  ~, .7~:- . ".- z~,, A'M  0 A z'i I fox Paz' A 91111 f C 1 6 14 IN, Ita d d  SOV/1 ,,6-'~6-4-43/49 AUTHORS: Kochergin, S. M., Terp,'.Iovskiy, 11. lie, Vyase1e-,rr,, G. TITLE: The Influence Exerted by the Ultrasonic Field on the Gas Content During the Eleotrnlysis (Vliyaniyo ulltrazv-akovogo polya na gazonapolneniye pri elektrol~ze) PERIODICAL: NauchDyye doklady vyssh-ay ahkoly. Khimiya i khimicheqkaya tekhn-~Icgiya, 1958, Nr 4, PP 77c,-7161 (USSR) ABSTRACT: Experimental data were givan the influence exerted I-,y ultrascnic vib7atilor.3 on the gag ccntent during the electrolysis and NaCl as wel'. as NaCH in order to obta`n H )f H 23o4 2 02 and Cl 2* The electrolyaia indicated in tablq 1 was carried out by means of sperially metnlifa,~tured apparattis. Th-, nod--ficat-Jon ,.f "he eleotrolyt.? ~*esist,ancca factor in dependerze cn the gas ocritent at the ultra2onic field was nvestigated. The depondence of the gan ccnteTit ra t-.Ime under influence exerted by nltrasonico (in thr,, e1tirtrolyte 'Nan i-aventiglited. A root~vtlori uf -,%ho gtiv -.-jntint jjureuntrigt! taken in the ultracrn-1n -field due to a cletrease, of the ohnic resistance during the analysis. 1-.ri the of a extended electrc- Card 112 lysis -Ln the ullv_rascni:~ field the percen-.age cj' gas content  The influence Exerted by the U-1, --'.-a-7oni ~, F--'--, -1 !",as cc'n- the Electrolysis beCOM83 constant. In order 'zo Gbtaf-ri hydr-ogor. and ohl,)ri-ne by apFlicatitn of iiltras'~n-`-.,~ a ~---a-:~vtause _4 r. el-l"',~rL, P'."Ner consumption takeF F-lace. There ar,: 4 figu.-Li and 10 references, 8 -,47 whinh arr! Sovict. ASSOCIATION: Kafedra khimii Kazanvikogo kog.-. inst-it.-ata (Clrai-- of Physirp.1 C'r-k.,mit ;-.ry at '.:hr,- K~Z,~nl SUBMITTED: may 31, 1958 Card 2/2  500) AUTHORS: Neemelov, V. V., Maminov, 0. V., SOV/153-58-6-19/22 Lebedeva, N. M., Danyushevskaya, R. G., Tervi1Q-YakiY,JL-N- - TITLE: Continuous Oxidation of Paraffin in Foam State in Apparatus of the Rotor- and Bottom Type (Nepreryvnoye okisleniye parafina v pennom soetoyanii v apparatakh rotornogo i polochnogo tipa) PERIODICAL: Izveatiya.vysshikh uchabnykh zavedeniy. Khimiya i khimicheakaya tekhnologiya, 1956, Nr 6, PP 108-114 (USSR) ABSTRACT: The interaction between gases and liquids is very intensive in foam state (Refs 1,2). In the present paper the results of the oxidation mentioned in the title with molecular oxygen are discussed. Thie process belongs to the complex chemical heterogeneous catalytic processes with a chain mechanism of the reaction. The best results were obtained when the whole initial material was transformed in well mobile foam. The rate of process depends on the height of the foam in the oxidation column. However, completely satisfactory outputs of the foam apparatus can only be obtained in the case of a Card 1/4 continuous process. The authors investigated two methods  Continuous Oxidation of Paraffin in Foam State SOV/153-58-6-19/22 in Apparatus of the Rotor- and Bottom Type of foam production from paraffin: 1) use of the centrifugal force in a rotor apparatus; 2) exploitation of the kinetic energy of the gaseous reagent, i.e. air which is blown through a perforated bottom and forms a support in order to maintain the foam on the bottom. The extended laboratories in the Kazan' neftemaslozavod (Kazan, Petroleum and Oil Rofinery) were used for the experiment. B. Ya. Konovalov, Director, and A. S. Moi9eyeva, Head Engineer, collaborated in the experiment; A. A. Aleksandrovskiy, Assistant of the Kazan' Institute of Chemical Technology imeni S. 14. Kirov, M. S. Khaykin, V. V. Levandovskiy, A. V. Matuzova and V. P. Solov1yeva, assistant chemists, collaborated in the experimental part. A rotor apparatus worked out by V. S. Nikolayev, Docent of the Kazan' Institute of Chemical Technology imeni S. M. Kirov (Fig 1) served for the experi- ments; paraffin of Groznyy, Drogobych, and Novolmybyshevsk was used as material. Potassium permanganate and soda were used as catalysts. The following conclusions were drawn: 1) the following facts are very important: a) The oxidation Card 2/4 is imperfect if the paraffin is kept longer than 100 seconds  Continuops Oxidation of Paraffin in Poam State 807/153-58-6-19/22 in Apparatus of the Rotor- and Bottom Type in the apparatus b) The initial temperature of the process is below 140 , o The variation of the air consumption does not influence the time during which the paraffin is in the apparatus. Two processes take place at the same time: oxidation and distillation. e) An intensive resin- and mud formation takes place at temperatures above 150 . f) The optimum paraffin consumption amounts to 10-20 I/hour. g) The maximum rate of oxidation is reached at 740 rpm. However, a transparent model shows that an intensive foam formation takes place only at certain places of the apparatus. The time t4e paraffin remains in,the apparatus must be at least five times longer in order to obtain a better oxidation intensity. This would increase and complicate its structure. Howev rp the rate of oxidation in foam oxidation apparatus (Fig ;) with bottoms in after the increase of the acid numbers B-12 times and after the increase of aliphatic acids (Table 1) 20 times higher than in periodically working apparatus of the bubbling type. The capacity is 2-3-5 times higher. The oxidation proceeds mainly under the formation of carboxylic Card 3/4 acids. Higher temperatures did not deteriorate the quality  Continuouc Oxidation of Paraffin in Foam State SOV/153-56-6-101/2? in Apparatus of the Rotor- and Bottom Type of the products, Thus the oxidation may be intensified,. Rotor apparatus have a lower capacity, are, however, well nuitable for the formation processes of neutral oxygen-cortain- ing products. In foam oxidation apparatus heat conditions are easily regulated. There are 2 figures, 2 tables, and 2 Soviet references. ASSOCIATION: Kafedra obahchey khimicheskoy tekhnologii, Kazanskiy khimiko-tekhnologicheakiy institut imeni S. M. Kirova (Chair of General Chemical Technology, Kazan' Institute of Chemical Technology imeni S. M. Kirov) SUBMITTED: November 10, 1957 Card 4/4  50 1 3) 5 AUTHORS: Maoino,,, 0. V., V. V., Lebedeva, N. M., Danyu9hovskaya, R. G. TITLE: Scme Characteristic Features of the 1~ydrodynamics of the Foam Layer of the Paraffin - Air System (Nekotoryye osobennosti gidrodinamiki pennof;o sl9ya sistemy parafin-vczdukh) PERIODICAL: Izvestiya vysshikh uchebnykh zavedeniy. Khimiya i khimicheskay tekhnologiya, 1958!'Nr 5, PP 149-153 (USSR) ABSTROT: Paraffin oxidation is an exothermal process. The atmospherics oxygen is absorbed by paraffin by entering certain chemical reactions with the latter. In this case the mass exchange bet-6-~--- air and paraffin depends to a high degree upon the hydrodyna--ic working conditions of the apparatus. The mass exchange is to 4 high degree influenced by the degree of turbidity of the gas and liquid flow (Ref 1). Under certain conditions of the motiez. in the turbulent range the gas becomes a disperse medium distributing within the liquid phase. The contact surface is enlarged and is rapidly renewed. These hydrodynamic conditions cannot be produced in the usual bubbling columns with periodi.:- Card 1/4 drive. The capacity of such columns is extremely insufficient.  SOV/153-58-5-25/28 Scme Characterist_~c Pea-ures of the E1ydrcdyna=.1cs of the Foa= Layer of "he Paraffin Air System In the foam apparatus as devised by Pozin and his collaborators (Ref 2) there are, however, very favorable conditions. To u--.--- this apparatus for paraffin oxidation Leveral constructional modifications were necessary, like, installation of electrica. heating, cooling coils etc. Experiments have shown that paraf- fin can be oxidized continuously in a foam layer. The rate of oxilation increases thereby by the 8-12 fold, since high lurz)idity is attained. Table 1 (p 151) shows the influence exerted by different air velocities and different types of raw materials ipon the foam formation and the degree of oxidation as well as the losses of paraffin. The oxidation was carried oiit for 15 minutas at 1600 and in the presence of manganese dioxide as catalyst. The results tend to show a dependence between the foam formation and the efficiency of the oxidation process. The m--re of the liquid is transformed into foam, and thE "higher the foam layer is the more perfect the oxidation pxccess takes place. Pure paraffin without additions is very difficult to transform into foam at temperatures up to 1600, even at higher air velocities. Above 1700 this takes place Card 214 O_a1S-_e::, but then again the ouality of the oxidation products  SC;V11 Some Characteristic Features of the Hydrodynamics ol zhp 7c~= Paraffin Air System suffers. The addition of regained paraffin or of 2-5% oxidized paraffin increases the foam formation rapidly. Then the surfac:e active substances (alcohols) contair,ed therein play a positljv,!~ rolo. High air velocities (higher than 0.2 m/sec.) are un- favorable for the transformation of the whole paraffin into foam. The intensity of the oxidation is decreased, a heat 'supp-, becomes necessary, and finally reaction products are carried along by air and are removed. The air velocity of Oel mlsec~ optimal. A system in which the catalyst is distributed in the form of colloidal particles favors the foam formation. Perfo- rated bottoms with openings of 1-2 mm covering 80-906 of the total surface are good for the foam formation. There are I table and 3 Soviet references. ASSOCIATION: Kazanskiy khimiko-tekhnologicheskiy institut, Kafedra obshchey kh-imichaskoy tekhnologii (Kazan' Chemo-Technological Institute, Chair of General Chemical Technology) Card 3/4  F- kp I V -S K NESMILOV, T*T,- TIIRPIIoOV�-KUA-",-..KAMINOV, O,T~; LUBEDAYA, N.M,; DOVihFXWT~A, R.G. Continuoun oxidation of foaming paraffins by mnlacular oxygen, Kh1h. naulm i prom. 3 no.1:130 '58. (MM lily) 1, KAzanskly khimiko-tekhnologicheekly institut im. S.M. Kirova. (Paraffins) (Oxidation)  Ai, -3 r N NESMZLOV. V.V/., kand. takhnonauk; IPMZVA. U.K., kand. khin. nmuk: - G.;~ Itand. tokbn. noult; MAMINOTj O.T., kond. tekhn. neuk Continuous oxidation of paraffin in a foamy state. Kael.-zhir. prom. 24 no. 6:20-26 158. (HIIU 11:7) 1. Xavanoldy khimiko-takhnologicbemkiy inatitut Iment, S.M.Kirove. (paraffins)  MSMELOVO V.V.; WXWOV, O.V.; TERPILOVSKIY, N.N.: ISMUZVA, N.M.; DAWMHU,-,KAYA, R.G. Problem of foam formation during the oxidation of paraffin in bubble coluaw and in a continuous fosm oxidizer. Trudy URTI no.26:15-18 059. (MIRA 15:5) (Paraffina) (Wdation)  MSMELOV, V-V-- TEUIWVSKIYI N.N.; LEBEDEVA.. N.M.j DANYILHEVSKAYA, R.G.; 0 MOUNOV.9 -0-.v.- Study of tho oxidation of Novo-Ufiwk paraffin in the foaming state in the presence of manganese dioxide. Trudy KKHTI no.26: 19-22 159. (MBA 15 -.5) (Paraffins) (Oxidation)  NZSlf2WV, V.V., lmrtd.takbn.nauk,- IJBIDIVA, N.M., kand.tnkhn.nauk; TWIIDVSKrT, N.N., kand.tekhn.rALuk; KAXINDY, O.T., kand.tekhn. nauk; XUCIV7' kand tekhn.muk; DAMSHITSKATA, R.G. Oxidation or paraffins in a foaming state, Kael.-shirsprou. 26 no.1:13-18 JA~ 160. (KM 13:4) 1. Kazanskiy khimiko-tekhnologicheskiy Institut imeni S.M. Kirov&. (Paraffins) (Oxidation)  BESMELOVI V.V.; RUIINOV, O.V.; TMPILOVSKIY, N.N.; LEWDEXAI N.M. Alteration of certain physical properties of paraffin in the process of its oxidation in the foamed condition. Izv. vys. ucheb. zav.; Ithim. i khim. tekh- 4 no. 2:283-286 161. (MIRP, 14:5) 1. Kazanskiy lldmiko-tekhnologicheskiy institut im. S.M. Kirova. Kafedra obshchey khimicheskoy tekhnologii. (Paraffins) (Oxidation)  KOCHERGIN, S.M.j. TERPILOVSKIYp_~~,.j~.; VYASELEVA, G.Ya. (Kazan$) - I AAadic dissolution of copper in an ultrasonic field. Zhur.-fiz, khim. 35 no. 4:917-919 Ap 161, (MIRA 14:5) le Kazanskiy khimiko-tekhnologicheskiy institut im. S.M. Kirovao kafedra, fizicheskoy i, kolloidnoy khimii. (Copper) (Ultrasonic waves)  BURMISTROVA, T.P.; TERPILOVSKIY, N.N.; NESMALOVp V.V. Influence of certain factors on froth-forming process during the oxidation of p-xylene. Trudy KKHTI no.30t289-295 162. (MIRA 16slO)  L 413;i9-661) E'.',T(n)/EP--(c)/T Pr-4 DJ AP3000501 8/0065/63/000/005/0018/0022 AUMOR: Sedachij,_Y~. M., .11comeloy, V. V.; Moyseyeva, A. S.; Lebedav ap W. M.; -Kuznetx4ti~tL.'1-.-M.; -;~atypo R.-*S1j-.j-1Tjrj~j lava kir, H. N. f 'TITIF,l Oxidation of paraffin In the foam state SOURCE: Kh1miya i takhmologlys. topliv i maselt nov 5. 196% 18-22 TOPIC TAGS: oynthetic lubrican continuous oxidation, bubble column, paraffin traction, paraffin oxidation ABSTRACT: The Kazan' Synthetic Lubricant Plant in cooperation with the Kazan' Xnztitute of -Cfievd&!'Tcchnologj, has developed a nw process for oxidizin-g &f6iV- fo,amed par affin up.t6-carboxylic acids. This continuous process van adopted on a pilot-plant scale in 1961. The new continuous foam process increases the yield up to 270$ as compared vith the previous; process. The author gives the processing i data and diagrams of equiymant used, as vell, as a breakdowa of the p"*aff in fracw tions and their specifications. The lossic operating parameters am: tempersture, i125 130*Cj air consumption, 1 a-'O/kg of o3ddized paraffin; a,aid number of oxidAta, 150 60 ag oC ME. In order to obtain good air dispersion, the use of screm In I Card 1/2  L 41352-65 ACCESSIOI( IM: AP30M501 the bubble COIU= is roc=wnW. The final product met& the r*quirwent, placed M synthetic yetrole%u yrodwtg. Orig. art. hu I tablas and 2 diagram .ASSOCXATXOgt ;SUBM=Ml 00% MOM 00 BUS 0=1 00, Is ;no MW Sov 000 OTM: 000 COrd 2/2  lia Bodies L Con,jersiOn '11 So of Solids pbsse piziksy No 2.4 195Bt NO 3484 Abs JOUr Ee-f ZLIar I or last Title -za amwwski ja ,nusz teristica Of Ag Ural Cbarac Not Give" and. Struct No li, 3-40 T~aer~od~ cl.2 19561 politeabn- wro orig pub P,bstract W& UMIX. Ono of 59 Z01' * jnve5tI-6&t' LC Percent ,ts electrochemical 8? 4 stomJ tion rom 28.4 to . ,,~tli 0, compos, ,uthor reVO 4n9 f tious %fare M_,Ln ranf alloys -A-a-ZU tiga so alloys ACI The inveg re- an& of fl-le liqent Of zinc. temperature Of zinc) tomic perc Bf 0 of bigh , 10.8 83-01aUremelat Of the e1 on the basis Of the meals (liquid-) tYVe * (a) partial base& On the za calculated.* -potential' elis of t1le ,owing vere nic alloys versible c the f0 ftermody"I solid dat86 obtai'16 he isobaric U ad Zinc .solution Of Zinc A. LatiOns Of t f di aissolution of liq ti-jer- molar v&e- and. entlla'-Py O.Proresa Of I the Isoberic Ol:LCI eUtrOWY 'I also of tle ~ entbalryp tion of s Ag.zxly an -za alloys. (b) 'Mt py Of forma (C) PCtivity Ag and the entrol - liqad nt 06t Modynamic Potentials compone 6 Ag-ZA alloys from 601a 1/2 POZ C!a of 8021 da, Abe p Ottr Rer z,4, - hase COn','e PI In and coeffl., no -" -1958, aoltd Bodt ajuovs at en t Of P1O 31484 Cheelcea 00C. acttvjt,~, 6 -PeITO., -roz the t 21,e of C Ag_,, ed. Xt ejVe is omponen rat, Q~e~ te 4tur, 'a-1`8tew h cottfl., aat ., of the sol't d ayste a , 2he 4 Ve a Ag.Zn Ag-Za ent 0 Is CU. ed tht th ch the dl krobJer4 01"dered ,t., e g and expe Sire t. Vas "R~ of Sc4a8ed Of Ozde,,l Ctur Zjz*nts "2'e rozzaa .0a -Phases Of the ti tartin ng Of e at hI 9 Wit on of soi fh t a Ph,, ghe-r te d al., Z 'Y8 e caa e of t 4 ,h Pe, f.po. cUa t, e Ag_,, soil 0 . d -~ Of th-  POLA14D / Physical Chemistry@ Thermodynamics. Thermochem- B istrys Physico-Chemioal Analysis* Phase Transition, Abs Jour: Ref Zhur-Khimiya, No 110 19561 35384 Abstract: following has been determined: 1) the phases P12 Au-Cd,% a Ag-11.1g; Cu-Zn and Y Ag-Cd belong to the Daltonoid gro'T ;.2) the phases J'Au-Cd; ?3f#.80Z Cu-Zn; A I P j V Ag-Cd; r.. r~, Bi-Tl; f9 Pb-Tl; J%Z Ag-Zn belong to the Bertholoid group6 The Bertholoids have a disordered structure; the vari- ations of AG, AS and -Z-H within the limits of these rhagoo are insignificant and gradual. On the other handp the Daltonoids offer a low degree of irregularityy the variations of Z-G,, AS and ZH_ within their limits are considerable and occur intermittently, forming an inflection point in the vicinity of the Stoichlometric compositions See also R Zh-Khimp 1956) 77515; 1957, 50724 Card 2/2 9  rhermodynande Properties of Liquid Metallic 891011.1"& 1 A' " W -- WW' -the Ht in 4 Th R ,WlasnoAct termodynaaritcane eteklych ;941wor6w metall. It Wad bmn-. i~~twurn- Htea*twa (P"), No. 3, Wrrszawa, 1058. pp. 227-237, 4 figs., 5 Wx In 4his work the H~-In sysWt tA hiAherto unknown thermodyna- tnicat pt(Vertlvs was Investloted b:r the qo4cd of rneasnrW t4ectro- motive forces. Dming these Investigatlo", 'ij?,wevsible elenx.nts of the following type were applied: Injjq. j(0.0 I~ft + 0.4 KBr) + 0.1 InDri 131~ In Tests were carried out w*, 11 alloys of 5 to 95 ptarrit 4A of Indiurn In the range of 380 lo~W*C. The rtsuits of menum- ments of the elfvirernrAlve fOr"s In these tYPW Of elments w"e dl- rectly, recalculated On changes Of Partt&t MOkr therf"dYnarnical va- lim for indium: POtentkd (WA01.), entmPY (&SW and . enthelpy (Alfin) at 00T. sod activities (aiz~ and the coefficient of acti. vity (fln) for Indhvn In alloys at 430* sod 500T. lAter as in a prevkms work of thia serfee, the wathor ca)mdAed the cbanges of p*rtJ*l molat thermodynamical =4ues for hismuth: thermodynam" Potential (kill), m&*Iv (ASoi) and enthr*y (AH91) at 400'C. and the activitles (a,j) and the ac*vity voeftkiaAs if 9j) for bismuth in atloyi at 00* and W*C. The chenges *1 the fcflo*kV tbermodynamiM t-notions %vr* also calculated: thermodynamical potential (AO), onAropy (AEO and en-' y (AH) during mfxft of txze liquld,tottals 4nto liquid allnry~ at i mp  14000C. The results of measurements and calculailorn are given In ta- ~blm mid presented In, diagrams. The liquid wyotan BI-In Is chsTamcierl-' ~zed by a negative dellmCon from. the Raoult's law, decreasing with in- s of the efr(halpy uhanges are negaliWe gmaing temperaUne. The valuie for the teffwrrAuye 400'C in 4he WWe -60MPOSIHOrk TaMe, and they attain - 504 cal for the alloy BlO.sTnq.$. The liquid soMfons B14n be- _NSgj and AS In rela, hafe as m. i-regular, because Abe courne Of 'NSiA, tion to the canporttion may be expres" by equatsons.  T& K 7 Distri We 7. 'off P-!phx qk!~~%e of the s I 7F Wriviam., Ckm No. 4. SLInintary).-E.m.G., S, of cells Nlg(~,lid)jL'Cl + KCI tutectic mixt. + JdgCl!jAg-?ilU~ (v4id allay) %Ytrc nic-asurcd (cf. T CA St 1-73-d&) at Im , i , !"(X) -611P. i-lic solid 11"Iny compil If at. 5,C), E at 6W0 (mv.), teirip. c(~eff. dEldT (;iv./d;Cree) were found: 42.0, 205.1, -25; 44.0. 19-1.0. -28; 45.5. 197.9, -30; 47.0, 18,1 Z. 1, -27; 41S.1. 184,5, -21; 49.3, 17,0.9, -6; 50.5, 167-9. +7; M.3, 145.7. +20; A1.7, M53, +.W; MA. 159 S, +32; 54.2, 152.0, +40; 56.7. 144,0, +37; 57A,, 143.6, +3G; 61 1 134A and +33, resp. The partial 'Itiolar heats, colt 11~t.a .~d_thC1v3odYn=lc potentials of crit-resixmiding to villoy GyrurAtion front solid components. Uctivity and activity cot1s., ate caliA. directly. Equa, C tion.1 fit Wagner and S--twt1ky (C.A. 25, 1131) fitted Iliq C, curm (if E uml dEldr vs. compn,, if a suitable dcgree (if ,it disotda, (0,03)o was assumed. Thus P-p'rA&c ut Ag-his; qys~ UAu is almost completely ordered. 6teckj_ Aj  Distri: E2 c IV f and degree of order of the 0- Thsrm_z;~ bA" systege'l fallml '17C " I I ph"a 01z" & 110 1 ro(law, WrMIM 6 --tv-07 I o. 4, 13-23(1958)(Ungl6j, .nnninary); cf. preceding abstr.-E.M.fs, E, uf cell 44111 Lict + KCI Cultectic Illixt. AuAI 1 4 "W3, for _14 erc nicasure at 4 -5Z +ZnCl ") jruilta it R I lit 3W -119" for tile wild one. Ilquid ZEnE c _EEKIE!NjP The following alloy compit. (Zn at VI) R at 500* (mv.), v'T w~rc found, resp.: and temp. cotff. dEldl' (,uv.ldcg; e 43.8, 239.3, -96; 45.1, -08; 45-5. 10-113, -90; 40.8. 220.1, -7102; 47.5, 225.4. - 103; 48.7. 218.3, - 100; 49.0, 211.3, -117; 5U.1, 203.3, -1:315; 50.2, 2014, - MIA; 60.8, 103.4. -135; 50.9, 193.2, -136; 51.2. 187.9, -140; 52.3, 177.7, -146; 52.0, 17-1.9, -147; M.0, 168.0, -148; 54.0, 160.2 -149; '54-8, V18-7, -1 '10; 64.9, 157.8. -150. The tent:; . coeff. dEjdT tot s,,Iid Z11 clCC- .2, and trode, was -48, -91, und -05, f-,r -17.5, 51. , /V Zn alloys. Tile caled. lieut -if hv;ion of Zn 6 1.79 kcal /g. atom, in agreement with blander (C.A. 27, 4175). The partW, snolar heali, untroijiff-and thermodynamic poteii. tials of Zu crrru5lion(M,:i_g to transfer of liquid U tio ~,Iid alloy,wer~ccalcd.dirtxtly. differed from th.,;c calcil. theoretically after Olandcr ( C,J. 27, 4473) fur cithcr %litchily ~r completely dii,)rdvrC,l phaw'. Probably the Rupp-Ncumillin rule ii invalid too, X-ray diagrams f(,r th(: idbly contg. 50.1 at. % Zn, -is %VC11 its tile rhangrs of Oval-Ayllmllic flim"tiolli with c(IIIII)II, illdicate that tile zu- kit ;?-jjh:t,C i-i 11"t a typical "I'lltouide. Con- biderable dii-micring 6-gin, at maiit; 40". Stecki  POLAND / Physical Chemistry. Thermodynamics. Thermo- B chemistry Equilibria, Physico-Chomical An- alysis. Phase Transitions* Abs Jour: Ref Zhur-Khimiya, No 24, 1958, 80625. Author Trzebiatowski, W. Inst :Not given. Title :Thermodynamic Characteristics of Intermotallic Phases of the Daltonian and Berthelotian Types. Orig Pub: Arch. hutn., 1958, 3, No 2, 97-112. Abstract: Previously published data (Celader A., Z. phys. Chem., 1933, A 163, 107; A 164, 428; 1934, A 168, 274; A 169s 260) pertaining to electrochemical measurements for the de- termination of partial molal thermodynamic constants (such as the thermodynamic potential G, enthropy S, enthalp~r,y H) of the Card 1/3 14  POLAND / Physical Chemistry. Thermodynamics. Thermo- B chemistry Equilibria, Physico-Chemical An- alysis, Phase Transitions. Abs Jour: Ref Zhur-Khimiya, No 24, 1958, 80625. Abstract: less noble components of intermediate Ihases of the Ag-Cd, Au-Cd, Cu-Zn, Bi-T1 and M-Tl systems were utilized. Results of previous investigations (Ref. Zhur-Khimiya, 1959, 44009, -90924) indicate that,the order.--of determined values of . G, ~~ :.:. S and H, in the lim- Its of existence of .- - an .-phases of the AujoCd system, and also of -phase of the Ag-Cd and Cu-Zn systems, are characteristic with Dal- tonian type of phases. Whereas the order of determined values of the sAme properties in the remaining phases, ie.,/ . -" - and - 'of the Ag- Cd system; of the Au.-Cd system;,., and e: Card 2/3  POLAND / Physical Chemistry. Thermodynamics. Thermo- B chemistry Equilibria. Physico-Chemical An- alysis. Phase Transitions. Abs Jour: Ruf Zhur-Khimiya, No 24, 80625. Abstract: of the Cu-Zn system;.-' and... of the Bi-T1 sy:-tem; and .'-phase of the Pb-T1 system are charac,6~,ristic with the Berthelotian type phases, It was established that a degree of deviation in the stoohiometric comi')ositions constitutes the basic criterion that deter- mines the direction of behaviours of the in- termetAllic phase of varying composition and causes it to act either as Daltonian or as Berthelotian phase. Card 3/3 15  )e /I / j- 0 vV PoLAUP/Ator.dc and Molecular Physics - Heat. D Abs Jour flef Zhur Fizika, 111.3, 1959, 17632 Author Terpil3vski, Janusz Inst Institute for Structural Research, Institute of Chemis- try and Physics, Polish Academy of Sciences, Wroclaw, Poland Title Thermod-jamraic Properties :)f Liquid Metallic Solutions. II. The System Bi-L--.. Ori(; Pub : Arch. hutn., 1958, 3, No 3, 227-237 Abstruat : It study was made of the thermdynanic properties of the system Bi-L-i containinc; five -- 95 atomic percent of iadium, Ln the temperature range from 3W to 5200 C, by a method of measurinC; the emf. The partial molar thcri:vAynanic fuzictions of indium, and bisrxith are cal- ctLlated: the thermodyntwtic potential, the entropy aad Ca rd 1/2  POUM/Atomic nad Molecular Physics - Heat. Abg Jour Ref Zhur Fizika, No 8, 1959, 17632 the enthalpy at 14001 C of the activity and the coeffi- cicat of activity for indivii and bisuuth In alloys at 400 and 5000 C. A19D calculated were the chanr'es in t'ne therti.3dy-a-Ac poteitial, the entropy, and enthalpy (lurint; Vhe rAxinr;.of pire liquid uetals at 4003 C. The restilts of the meastixericAa and calculations are reduced i% tables anid are plotted 3n curves. The liquid system Bi-In is characterized by a ne~ptive deviation from the Paul law, diuinishinC; with increasing termperatu- re. The chanGes in the entropy are ne_mtive over the en- tire re,-;ion of compositions and reach a magnitude of -594 calories for the alloy Bio-5 Ino-5- It is shown that liquid solutions Bi-In behave like se-mi-regrular ones, inasmuch as the changes in their entropy is comiected with the coefficient P, which characterizes the delia- tion from the Nehavior of re(s%Llar solutions. Card 2/2 - 50 -  POLAND/Atomic-)and Abs Jour Author Inst Title OriG Pub M.)lecular Physics - Heat. D : Ref Zhur Fizika, No 10, 1959, 22414 : TerDilowski, gqpIlsz, Prezezdziecka, Ekilia : Academy of Metals, Wriclaw, Poland : TheruDdynamic Properties of Liquid Solutions of Metals. Part 111. Semi-ReGular Disiary S.:)lutions. : Arch. hutn., 1.958, 3, No 4, 315-327 Abstract : On the basis of calculations performed in Part I (Referat Zhur met, 1958, no lo, 2o661) and Part ii (Referat Zhur Fizika, 1959, No 8, 17633) it is shovil that liquid solutions Au-Dl, Bi-Cd, Bi-Sn, Cd-Pb, Cd-Sn, In-Zn, Fb-Sb, Sn-TI, and Sn-Zn behave like seLd-reGalar ones. The experimeatally determined values of the chan- Le in the partial wlar entr~)py for the corrponents ES1, E S 2) and the -.dxinG entrapy (S) in the entire Card 1/3 - 30 -  POuU-1D/,',t;Dmic and M.-ilecular Physics - Heat. D fibs Jour Ref Zhur Fizika, No 10, 1959, 22414 reCion of the solution concentration can be expressed by means if the followinC eq-,,,ations: zS1 =-Dij In 111; 6-b 2 = -DR In N 2 S A R (IT, III IT, -I- IT la IT Where D is a c5effictent that expresses the deviation of the solution fron ret;ularity (11 and 11, are the concen- trations of the first and seconi compoilent in the sblu- tion). Numerical vaiiies are obtained for the coeffi- cieat D and are tabulated. If one considers the solu- tion Sn Zn, Cd Pb, AC; Pb as serA-rerular, one ob- tain3 a better aGreement between the experiTzental and calculated data, then in the case of assLwain(; these solu- tions to be reGular. It is shiwn that the local orderiLt; Lifluen-ces irsit,;iificantly the value if the cL)efficient D in semi-regular soL-tioas. As can be seen frori the results obtained, there exiets a connection between the chanGes in the volume durinrg mixinL and the values Df Card 2/3  -.- -- . - -POLAND/I~t~~mlicand Molecular Physics - Heat. D Abs J:)ur : Ref Mur Fizika, ND 10, 1959, 22414 the coefficieiit Di. Althoud, this dependence is not proportioual one can nevertheless say that chanCes in the volume play a substantial role in the chanCvs of the coefficient D. Card 3/3 - 31 -  POLAND Chemical TechnoloFy. Che..jical Products and H Their Application. Synthetic and Natural ,~,,Iedicinal Substances. Galenical Proparations and Mediqinal Forms. Abs Jourz Ref Zhur-Khimiya, No 9, 1959, 32435. Author : Terpilowski.-J., Saiyt, K. Inst %Not,given. Title An Ap-.)lication of Ionic Substitutes in the Analysis of Pharmaceutical Preparations. Orig Pub: Farmac. polska, 1958, 14, No 13, 196-200. Abstract: A review. Bibliography of 70 titlos. Card 1/1  COUNTRY Poland CATEGORY AD-i. JOUP. 371'hiia., ~.'o. 16 1191591 . k 4,1. -100 560~1 J. and Q:Znyt, TITLS The Chelatometric Determination of Magnesium in Certain Prescriptions OR IG -PUB. Acto Polon Fharmac, 15, .-o 4, 285-292 (1958) A B r RA ~;T A i3imple, rapid, aad act.,urate chelatorne--r4c method hac buer. developed for the determination of Mq in .1, number of widely Veed vubscriptlkl,.Is. Optiwum conditions for the dissolution of varioun mixtures have been determined together willn tne most effecient waye of removing components which interfere with the determination; the 14tter purpose was achieved by the use of a colvnn packed with Amberlite IRA-400 anion exchango resin and by the use of the hydrolycis reaction (in trie case Bi salts). From &athoral summary  "Order-disorder" transfn;r:nntions In -netf,11-ic WIADR-10SCI C:-7j,'.TICZI[r-,. (Polakin Townrz,.tatwo Chemicme) Wroclnw, PoInn(I. Vr,,l. 13, no. 1, Jan. 1959. Monthly List of ast European ;~cccssions (FEAI) LG, Vol. 8, no. 8, August 19,10. UNCL  - -- I - -.-, - ---- ---' --- - --- L . . , - - - ~ - ~ - I - - r- C:p " T E_ I I L-Li -~ 5- L. . --j - j f 1~  BILINSKA, Urszula;jERPnCWSKI, Janusz Determination of phosphorus in certain copper alloys. Chen anal 5 no.1:17-22 160. (EW 9:11) 1. Katedra Chemii Nieorganicznej Wydzialu Farmaceutycznego Akademii "cznej, Wroclaw. (Phosphorus) (Copper) '49  18.9100 AUTHORSt TITLEt It'jIg 11~8 104,5 2330,7~ P/03Y60/005/003/001/002 A076 Al 26 Terpilowski, Janusz, and Przez'dziecka-Mycielska, Emilia Thermodynamic properties of liquid-metal solutions - Part VI. The IA-Sn System PERIODICAL: Arohiwum Hutnictwa, v- 5, no- 3, 1960, 281 - 290 TEXT: In order to investigate the thermodynamic properties of the liquid In-Sn solutions the results Of Mes,SUrMeAtS of the electromotive forces - emf - were applied. These forces were measured in reversible con- centration cells of the typet In (0.6 LiBr + 0.4 KBr) + 0.1 InBr inxBnl-x liquid melted salts liquid I I solution The authors investigated 10 liquid In-Sn solutions with an In content from 5 to 90 atomic %. The design of the electrolytic cell was the same as in the previous works of this series (Ref. 5: Terpilowski, J, "Archiwum But- Card 113  23303 P/038/6o/005/003/001/OC12 Thermodynamic properties of liquid-metal ... A076/A126 nietwall, no. 4, 1959, P- 355). The emf of the oell were measured in a tem- perature ran e of from 390 to 6100C and the values of the amf were deter- mined at 4009 0 (E400), 50000 (E 00), and 6000C (E600) 98 the temperature coefficients of.emffdE in-the aNve range of the temperatures concerned. tdT) Based on the results of these measurements and the Gibbs-Duhem equation the following calculations were performeds a) activities (aln, aSn) and the activity coefficients (fln, fSn) of the constituents, b) changes of the partial molal thermodynamic potentials (EUI., k-GSn), ent-r-opy (A-UIn, 3ESn) and enthalpy (A_ffIn',4ffSn) of indium and-tin, c) changes of the thermodynamic potential (IJG), entropy (6S) and enthalpy (AH) during the mixing of pure liquid metals into liquid solutions. It was stated that the enthalpy of mixing shows negative values in the whole concentration range and attains - 40 cal/gramatom for liquid alloys containing from about 72 to 62 at.% of indium. The small values of the enthalpy of mixing and the values of the activity coefficients for indium and tin, which approach unity, prove that the constituents influence each other very little in the temperature range of the measurements. The 6G curve has its extremity displaced towards hien- Card 2/3  23303 P/03 60/005/003/001/002 Thermodynamic properties of liquid-metal ... A076YA126 er concentrations of indium in the liquid solutions likewise the &H curve. The activity isotherm for tin is distinguished by positive-negative devia- Oz;nci -Ioroy.,i the Raoult'F, I-aw and Lliai. uf 1,Lu ac~JLviLy t,i, il'L,1111.1 "J~f (111 J'3 ,It i.9 possible ~juch a ciurse of those LIiLnaudji1zuiic. curve.5 in relation with the appearance of the solid phase P of a variable composi- tion in the In-Sn system. The values Of ASIn, '6SSn and AS in the tempera- ture range of measurements are not much higher than those for regular solu- tions. This results probably from the fact that both of these metals are close to each other in the periodic system. There are 4 tables, 4 figures and 20 references: 12 Soviet-bloc and 8 non-Boviet-bloo. The reference to the most recent English-language publication-reads as follows: Kubaschewski, 0., Catterall, J, A,, Thermochemical Data of Alloys, London - New York, 1956. ASSOCIAT10111: Katedra Chemii Nicorganicznej, Wydzial Parmaceutyczny Akademia Medyczna, Wrockaw (Department of InorRanic Chemistry, Pharma- (,Pi)tA(,FtI Spctinn. Medical Academy, Wroclaw) J C-ard 5/3  . TERPILOWSKI, J.; TRZEBIATOWSKI, W. Thermodynamic properties of indium antimnide. Bul chim PAH 8 no.3: 95-98 160. (EEAI 10-.9/10) 1. Department of Structural Research (Wroclaw), Institute of Pbysical Chemistry, Polish Academy of Sciences. Presented by W. Trzabiatowski. (Antimony indium alloys)  TERPILOWSKI, - AIII!-~.Zdoc.dr. On Daltonids and Berthollides among the intermetallic phWes and their tharmo-dynamic properties. Wiad chem 14 no-3:157-174 Mr 160. 1. Kiarownik Katedry Chemil ~Iieorganicznej, W~vdzial Farmaceutyczny, Akademia Madyczne, Wroclaw i Zaklad Baden Strukturalnych, Instytut Chemii Fizycznej, Polska Akademia Nauk, Wroclaw.  346e/,5 5/137/62/000/002/004/1' AO06/A1Ol /dp AUTHORS: Terpilowski, Janusz; Kundys, Emil; Slaby, Henryk TITLE: Thermodynamical properties of liquid metal solutions. VII. The Ag-Tl system PERIODICALi Referativnyy zhurnal, Metallurgiya, no, 2, 1962, 12, abstract 2A57 ("Arch. hutn", 1961, vol. 6, no. 2, 137-146, Polish; Russian and English summaries) TEXT; The authors measured emf E of reversible concentration elements of type Tl (liquid)/(0.58 LiCl + o.42 KC1) + 0.05 T1Cl (molten salt)/AgxTll- (liquid solution)+. Investigations were made of 10 liquid solutions of Af-T) containing 10 95 at. % Tl. The investigation method was described previously ~MhMet, ig6o, no. 9, 19484) . E values were determined for 950, 1,050 and 1, 15o K. The emf-of all elements varied linearly with the temperature. For elements containing solutions with 0.1 and 0.2 atom portions of TlNTI, numerical values of El 050 were'extrapolated from the linear dependence of emf on temperature. The re'sults'oPmeasurements and extrapolation were applied for the case of the Au-Tl systeth to balculate changes in the partial molar thermodynamical potentlals Card 1/2  S/137/62/000/002/004/144 Thermodynamical properties of liquid metal ... AOG-6/A1O1 of entropy (A ki, A ~Ag) and enthalpy (ART1, A RA ) of Tl and Ag, activities and activity factors of components, changes in-the fhermodynamical potential, entropy.(A 9) and enthalpy-(A H) of mixing liquid T1 and supercooled liquid Ag. Isotherms of activity of the components in the liquid range of the Ag-Tl system show positive deviations from the Raoult's law only within a UT, range from about 0.1 to 0.11. The isotherm of Ag activity is characterized by a low negative deviation.f3~om this law. Mixing-enthalpies are positive over the whole concen- tration range and show maximum values on the side of liquid solutions enriched with Tl. These maxima attain 950 cal. g-atom of the solution. A-PT1 P A -'!-A. g and AH curves have an asymmetrical shape, and a maximum on the A H curve appears on the side which is opposite to the enormous majority of other liquid metal. systems with sharply different atomic volumes of components, Values 6-9;rl' A SAf and A S for the liquid Ag-T1 system are higher than for ideal and regular solu ions. The basic cause of this fact is the great difference between atomic volumes of Ag and Tl. Liquid Ag-Tl solutions behave like semiregular solutions with coefficient D - 1.42, Information VI see R7,hMet, ig6i, 3A14. [Abstracter's note: Complete translation) Authoig summary Card 2/2  30577 ISISSO P/038/61/006/003/002/003 E07l/El8O AUTHORSt Terpilowski, Janusz., and Gregorezyk, Zofia. TITLEs Thermodynamic properties of liquid metallic solutions PERIODICAL., Archivum hutnietwa, v.6, noo3t 1961, 197-204 TEXTt Thermodynamic properties of liquid indium-lead alloys were investigated by measuring the electromotive forces in reversible concentration cells of the following type3 G QD In 1(0.6 LiBr + 0.4 KBO + 0.1 InBr InxPbl-x liquid molten salts I liquid solution Spectroscopically- pure indium, and lead of 99.99% purity were used for the experiments. Altogether ton In-Pb alloys, with an atomic fraction of indium, varying from 0.05 to 0.9, were studied at temperatures of 4oo, 500 and 6oo Oc. From the resulti obtained, the following values were calculatedt temperature coefficient of the electromotive force (dE/dT) within the temperature range studied; activities (&In, apb) and activity coefficients (fIn, fpb) of the components; changes of partial thermodynamic molar Card 1/ 3  30577 Thermodynamic properties of liquid ... P/038/61/oo6/003/002/003 E071/E180 potentials ( &GIn, &GPb), entropies (-SSIn, "ESPb) and enthalpien AHIn, AHPb) of indium and lead and changes of the thermodynamic potential (6G), entropy (AS) and enthalpy (&H) for the process of mixing pure liquid metals into liquid solutions. The activities of indium and lead indicate that there is a positive deviation from the Raoult law. These deviations decrease with increasing temperature. The liquid indium-lead solutions can be approximately regarded as semi-regular, with the values of entropies of mixing higher than for ideal solutions. This increase in the entropy of mixing is probably caused by the difference in the atomic volumes of indium and lead as well as by the effect of atomic bonds. The values of -EH-jr,,, tH,~,b and LH are positive for the whole range of concentrations of liquid indium-lead solutions. On the basis of investigations by 0. Kubaschewski (Ref.8z Z. Elaktrochem., 59, 1955, 840) it may be postulated that, during the formation of these solutions, a loosening of the atomic bonding of indium and lead, associated with the absorption of energy, occurs. The existence of solid Card 2/3  30577 Thermodynamic properties of liquid ... P/038/61/006/oo3/002/003 E071/E180 intermetallic phases of variable composition does not appear to have any influence on the thermodynamic properties of liquid indium-lead solutions within the range of temperatures studied. There are 4 figures, 4 tables and 11 references: 7 Soviet-bloc and 4 non-Soviet-bloc. The English language references read: Ref.9: 0. Kubaschewski, Trans. Faraday Soc., 45,, 1949, 931. Ref.10i W.J. Svirbely, S.M. Selis. J. Am. Chem. Soc., 75, 1953, 1532. Ref.lli R.W. Bohl, V.D. Hildebrandt. J. Am. Chem. Soc., 79, 195-7, 2711. SUBMITTED: September 1960 Card 3/3  TERPILOWSKI, J.; BARYCKA, I. Thermodynamical properties of liquid cadmim-a-magnesium solutions. Bul chim PAN 9 no.41175-178 161. 1. Department of Structural Researchp Wroclaw, Institute of Physical Chemistry, Polish Academy of Sciences and Department of Inorganic Chemistry, Technical University, Wroclaw. Presented by W. Traebiatowski. (cadmium) (Magnesium) (Solutions)  ,-TFMILOWSKIt J.'; MANCZYK, RO Complexonometric determination of zinc in some prescription mixtures. Apt. delo 10 no. 2:85 Mr-Ap 161. (HIRA 14:4) i (ZINC-ANALYSIS)  P/038/62/007/001/002/003 E193/L383 AUTHOWS: Kundys', Emil, Terpi-roi-rs-ki,--.-Janusz and Josink, Jerzy TITLE: Thermodynamic properties of liquid metallic solutions. IX. The Sb-Tl system PERIODICAL: Archii-rum-hutnictwa, v- 7, no. 1, 1962, 39 4 6 TEXT: The obj.ect of tile present investigation was to, study thermodynamic propjerties of liquid Sb-Tl solutions. To this end, the e.m.f. of revQ'rsible concentr4tion cells of the type: Z~ Tl '(0-58 LiCl + o.42 KC1) + 0.05 TlCli Sb Tl x I-x liquid molten salts liquid sol-Lition was measured. A linear temperature-dependenco of the e.m.f. was observed in every case. The other results are reproduced in Table 1. Changes of partial molar thermodynamic poteiltials entropy (LIS and enthalpy ('~-6'T i Sb Tl' /-"SSb) (~-%"T I I -L"'S b Card 1/4  w ill/o38/62/007/001/002/003 Thermodynamic properties .... E193/r:,383 wore calculated from these data as well as the activities (a TV aSI) ), activity coafficielits (f, rl,fSb ) for TI and Sb, and changes of the thermodynamic potential CLG) , entropy S and enthalpy (!~R) of their solutions. As will be seen from Fig. 11, where a Sb and a T1 are plotted against T1 concen- tration (N T1 ) at 650 OC, the activity isotherms for both metals show a negative deviation from Rault's law. The enthalpy of the solution is negative for the entire concontr,%tion range, reaching a valuo of -1190 cal/g.atom nt the TI-rich end. Thn asymptotic character of curves for the enthalpy of the solution and for partial molar enthalpy of the components can probably be attributed to the existence of an intermedi -ate y-phase in the system studied. As shown in Fig. 2 (-where ~_S TV I-S, 5b ond (cal/OC) are plottad against 'IN TI - the broken curves relating to ideal solutions), changes of partial molar entropy of the components and entropy of the solution for the entire Card 2/4  P/038/62/007/001/002/0-03 Thermodynamic properties F,193/r!,383 concentration range were found to be higher than those of an ideal solution. This effect is probably associated with . relatively large volume changes accompanying the formation of liquid solutions and with the difference in atomic-evolume of both components. There are 4 A1,1gures and 11 table3.' W- Fig. 2: d $AV-01 rA Fix. 4: 1 1 J1 I 40 1 - _ 1 10 %% % V M 0 1~, 41 to CO 0 4.9 '44 a# IV4 Card 3/4 Nn  I,/()-,j8/621/007/001/002/003 Thermodynamic properties .... E 193/ E3 8 3 Table 1: Key 1 -.Lp.= No. 2 - Temperatur a range of the measurement, a C. Card 4/4 0 I.P. JVTI Am mv dE dT j w MV11000 Zukres temp ratur pomia- r6w w OC 3 4 1 0,050 317,5 -m,a 620-700' 2 0,100 253,1 21,7 590-680 3 0,-.00 .192,2 16,3 550-700 4 0,300 151,1) 12,7 510-690 5 0,400 120,9 9,6 460-600 6 0,500 96,8 7,4 410-4690 7 0,600 71,0 4,9 400-600 8 O'NO 48,6 3,4 400~690 0 0,800 26,'Z 2,1 400-690 10 0,000 12,4 1,0 400-690  P/038/62/007/003/001/002 E193/E383 AUTHORS., Kundys, Emil, Terpilowski. Janusz and*Zaleaka, Ewa TITLE: Thermodynamic properties of liquid-metal solutions. X. Pb-T1 system PM-IODICAL: Archiwum hutnictwa, v. 7, no- 3, 1962, 233-241 TEXT: Measurements of e.m.f. generated at 400 600 'C by a reversible cell of the type: Tl (0-58 LiCl +-0.42 KCL) + 0905-TlCl PbXTI X-1 liquidl melted salts liquid solution were used to determine some thermodynamic properties of liquid Pb-Tl solutions in a wide concentration range ', Using the Gibbs-Duhem's equati 8n and the experimental 'values of e.m.f. at 400, 500 and 6oo C and the temperature coefficient of e.m.f,, the authors calculated the following properties: -,-I) -changes in the partial molar thermodynamic potential Card 1/3  P/038/62/007/003/001/002 Thermodynamic properties .... E193/F.3831 entropy /-"S and enthalpy Lk of both constituents; 2) changes of the thermodynax~ic potential, entropy and enthalpy of the solutions (calculated per g.a. of each solution); 3) activities a and activity coefficients f for both components-in liquid solutions* The results, tabulated and reproduced graphically, were similar to those obtained earlier for the Bi-T1 and Bi-Pb-solutions. The -validity of the method employed was confirmed by the fact that the values of enthalpy of solutions obtained by this method were in good agreement with those obtained by F.E. Wittig and P. Scheidt (Z. phys. Chem. NF, 28, 1961, 120) with the aid of the calorimetric method. In general, the results'6f the present investigation provided support for the view that metals occupying adjacent positions in the periodic table form liquid solutions only slightly deviating from ideal solutions. This is demonstrated in Fig. 2, where the change in the partial molar enthalpy of both components UAKT,, Z%9pb) and the~change in the entropy-of the solutions are plotted against the Tl concentration, the Card 2/3  P/038/62/007/003/001/002 Thermodynamic properties #*so E193/19383 broken curves relating to ideal solutions. -There are figures and 5 tables. SUBMITTED: September 26, 1961 Fij._2: '65"df Ivrolprop taLrd 3/3 A  8/137/62/000/012/001/085 AOO6/A1Ol AUTHORS: Terpilovski, Janusz, Staroficik, Rudolf TITLE: On the solubility of In2s 3 PERIODICAL: Referativnyy zhurnal, Metallurgiya, no. 12, 1962, 7 - 8, abstract 12A36 ("Chem. analit", Polska, 1962, V. 7, no. 3, 629 - 633; Polish, summary in English) 0 24 TEXT: The reproduction of In.8 3 solubility at 25 C, equal to 5.8-10- is determined from thermodynamical data. The concentration of In ions in satu- rated In2S3- solutions is polarographically determij~ed, depending on the acidity index. The experimentall reproduction of solubility approaches th calculated val- ues with higher acidity. This fact confirmed the formation of 104 ions-in the solution. V. Vigdorovich Card 1/1  STAROSCIK, Ru4c.Wt_-NK1LOWSj~;, JanuBs Calorimetric determination of indiira by pyrocatechol violet. Chem anal 7 no-4:803-808 162. 1. Departmant, of Inorganic Chemistryq Faculty of Pharmacyy Academy of Medicinep Wroclaw.  AU7HOR: S/137/63/000/001/001/019 A0061AI01 TITLEs Thermodynamic properties of liquid solutions FERIODICALI Referativnyy zhurnal, Metallurgiya, no. 1, 1963, 7, abstract IA29 ("Bull. Acad. poloft. sai. Ser. soi. ohim.11, 1962, v. 10, no. 5, 221 - 225, English; summary in Russian) TEXT: In the binary Mg-Zn system the presence of an MgZn2 phase, and of three other intermptallides within a narrow range, was observed. The MgZn2-PbDse has a close-packed lattice and melts congruently at 5900C; the hereditary struc- ture of the short-range order is supposed to be preserved in the melt which would affect the thermodynamic properties of the latter.. The thermodynamic pro- perties of the r4g-Zn system liquid alloys were investigated by measuring the emf on 12 specimens within a rarge of 0.035 - 0.90 atomic portions of MS. The emf depends linearily on the temperature. By applying graphical integration, the author determined changes in the partial molar values (61'Znl IA'gZn- &ITZn) and of free energy LF, entropy LS and enthalpy ~LH. Activity of Mg and Zn in Card 1/2  S/137/63/000/001/001/r,19 Thermodynamic properties of liquid solutions A006/A101 solid solutions was calculated from equations ATi RT 1n a,. It is noted that the thermodynamic properties of alloys Zn-Mg and Cd41S era similar. In both cases negative deviations,from the Raoult's law are observed. A mini=m on the concentrational dependence curves of activity corresponds to the MgZn2.phase; this proves a substantial interatomic interaction of components and the presence of a definite degree of order in these alloys. A. Vertman [Abstracter's note: Complete translation] Card 2/2  PRZEZDZIECKA-MYCIELSKA, Emilia; TERPIIDWSKI, Janusz; STROZECKA, Krystyna, Thermodynamic properties of liquid metallic solutions. Pt. 9. Archiw hutn 8 no. 2: 85-102 163. 1. Katedra Chemii Niaorganicznej, Wydzial Farmacautyczny, Akademia Medyczna, Wroclaw.  TERPILOWSKI, J.i SLIDI,H. Thermodynamic properti,~,s of liquid magnesium-thallium solu- tions. Bul Chim, PAN 11 no.683171-320 163. 1. Department of Ino:rjanic Chwistry, Faculty of Pharmacy, School of MedicJna, Preserted by W.Trwebiatowski.  JASKIEWICZ, A.; n~ILOWSKI, J. Anomalous delay effect in polycrystalline BaTiO3. Acta phypica Fol 23 no.3:407-409 Kr 163. 1" 1. Physical Institutey Wroclaw Univ6isity, Wroclaw.  TERPTILWSKI, Janusz; ZALESKA, Ewa Thermodynamic properties or thallium-tellurium liquid solutions. Rocz chemii 37 no.2:193-200 163. 1. Department of Inorganic Chemistry, School of Medicine, Wroclaw.  TERPILOWSKI9 J.; RATAJCZAK, E. Thermodynamic properties of CdSe and CdTe. Bval chim PAN 12 no.6: 355-358 164. 1. Department of Inorganic Chemistry of the Divtalon of Phamacy of the School of Medicine, Wroclaw. Submitted April 6, 1964.  ~Zvlkc-'! SLABY, It.; Thermod~nami^ -)roperties of liquid magnesium-gallium solutions. Bul chim PAN %i.e. 12] no.9:581-585 164. 1. Department of Inorganic Chemistry of the Division of Pharmacy of the School of Medicine, Wroclaw. Submitted July 6, 1964.  ctncentration