SCIENTIFIC ABSTRACT VARTANYAN, A.T. - VASILYEV, A.V.

[West-'A44, Mosk 16, iWOW? d, C.A. 45.37MC-rie elyts werv dtpWttd -1 .0 0 on quarts Orm ak. goins. with a Alm tkkt" of 0.1 oistes carrying Au or Ft elecirodes I mm. apart and treated io wxv at tool. Tlw %pft-W dark cond. of phtbalocyankm 10-4 (Mir phthalocyanine 1.4 X 10-40-1 Virlb.'excrPtion of free Whalocyanbse in dak. ciond. of d 14 sensitive tot); ibis Sensitivity inciftses in Histut Ca aim and dtcmi& in crystal vkkt wW methylene FOS r1no Is pumped out. tin Initial wasilivity is rt- eitabliobedL The cond. in a flaftr iruw1ion of the upplird Am and has a Pos. temp. cown. in the inta-va 2D-tor 311-200' for phthalocynaJines). The activation encru is of "he ordrr of 63,4 to 12 cv. and depends on the dye and the gaq 10m. Dolt). Most otber dyes have dark resistance > 1(Y$ U. ~a Mrxe the resistance is decivased by right. A StAtionartr coadition Is obtained In Rhodamin 6G In approx. 2D inin, and Its 11ods In M-30 we.; at Increasing temp%. the all dyes with the euvption of pbeco- wwala drerrAses Its "hwther. rbotachorns. action is reopoosihic for the de- ciftee of photacurrent after the maw. it reached for wnw dyes such as cyanim and antal violet under certain condi- tions of wave Length vid temp. The spv,~Val d"" Curves dtPOW - the thickam of the fihn; the mat, of photocoad. Is skittly shIW to kaW wSve kggtU w PMftd to tbG a". of absorption, It drop to my swall -kW at wavt length > W-W ma (tlw now, is at &w) - in trivadowine am at w and w m. in Mgd oft). pwomd. is Itscrevard with temp. Accurdwe to the formula Ai - 0-61t; this (a attributed to an bKrftw to the a.. .1 c-rien Under tbd 1"JIMUM of therfaill affiry. The W. fit- - taostly flectrons, Oka want of The MA. is rarrim b'T hok$- The Photocond. Ai - W. Where L Is the in. IcalitY Of HIM. a and k con%L-Lnts. For hi#b4nertin dy" A < 0.3; for low4nerila dyes 0.5 < k < 1. At idiom obmws VA" UP to lkkls Of 5M Y-cm.-'; the tuvpdms mvdtw tothe beating Of the film bY JOUle best. 0. 1. stud ifCCh vapor quench photocond. of most dyes stronglyeven at Pressures 0.01-0-0D1 mm. and the film. However the Pbot- d. of I .-tby-dn, Bengal Rome, and trips, B&Tiw is Increased by 0 but only in the prrse. ot liot td '.ertala vMvt length The - Of sensitivity is shlitett to U14" Wirth d;;Mdi"9Mxth# duration of Wuminaticm ) Pressure avording to the formula &~_ - &j - F01ra" +-910).. S. Nks-  VARTANYANs &.T. II r`x Chemical Abstraote Vol. 48 No. 5 Mar. 10t 1954 Eleotrbnio Phenomena Lu"Ce 0 w of M f At' -vapor on thejktWaadmWxA#y of solid fitins; of dyes. hisr, Pis. Khm. 27,272- 5,37EFJi. In-ortirr to test the hypoth- esis of Te, lin (P. *,olorh4mifstry vt Dyes, 1947. sect. 26; C.A. 46, 5978e) that the first stc~ in,the photochem. de- compri. of a dye is the addit. of a mol. of 0 to form a hiradi- cal, films of tal violet (1), Rhodamine B (11), and Rho- damine 6j ( M, purified by niany rccrystus.. %verc deposited ofl[ a quartz surface which bore Pt electrodes set I mm. apart. An e.m.f. of-22 r. was applied to I and 270 v. to 11 and 111; the " -rent was observed by means ofa mirror galvanometer Z ~(serisitfvity 0.3 X 10-11 anip.), each filan being exposed to *-J' light of different wnve-length ranges between 275 and 700 m;s from a 250-w. high-pressure quutz-1lg lanip. The films and Spectra were tested ift vacuo and in the prmnee of 11-0 vapor (1-2.5 mm. pressure) successively for periods of G(~-160 min. Expil. data are presented graphicaNy. In the wave-leiigth range 600-700 mg the effect of H,O vapor on the photocand. was independent of the wave length. When 1120 vapor was admitted to I (luring exposure to (M-700-ing light, the cond. fell immediately but fullv recoveretl within 2 firs. after the. HO was removed. Railiation'of 300-400 rnis causes de- comprit. of I in racuo; this is inhibitcd by 1110 vapor. 11 and M are less affected by 11%0 (as regards photocomd.) than 1. At H20 pressure approaches the point of condasi$&tion on the dye (about 5 rarn. for IM. its effect is complicated by heating caused by adsorption, increase of *photmond.. and incipient electrolytic conduction. It Is concluded that H20 vapor re- Tersibly decreases the photocond. of solid dve films as a re-, sult of electron capture and That Tervnin's ls~pothesis is cor- rg, Jr. J. W LowcbL - - - _.j  U&CIR/Physics Spectral analysis Card 1/1 Pub. 43 - 53/62 Authors I Vartanyan, A. T. Title Absorption spectra of leuco base dyes in solid state Periodical I Izv. AN SSSR4 Ser. fiz. 18/60 731-732s Nov-Dee 1954 --Abstract - 1--A study of the absorption spectra bf leuco base dyesi Lauth's violet, niethylene blue, thionine blue, capri blues green malachite, crystal violet, etc., in solid state showed that the presence of gaseous hydrogen sulfide results in the conversion of many solid dyes into an achromatic compound. The rate of reaction of the dye was observed t-D be increasing with the in- crease in temperature. Such achromatic compounds sublimate rapidly at tem- peratures above 500C. The solid leuco base dyes regain their original color when exposed to atmospheric air. Graph. Institution : .......... Submitted t ..........  VARTASTAN, A. T. -USSR/Chemistry - Photo-Conductivity Authors : Vartanyan, A. T., and Karpovich, I. A. Title : About the photo-conductivity of colored organic films during il-lumination with vioible light .Periodical : Zhur. Fiz. Khim., 28, Ed. 5, 856 - 864, May 1954 Abstract : Exneriments to determine the photo-conductivity of colored collodion films -during illumination with visible light brought only negative results. Photo-conductivity could not be.revealed. The increase in electrical conductivity during illumination odth visible light, as observed by many researchers, is not due to the internal photo effect but to the heating of the colored film as result of the absorption of the light energy in the natural color absorption band. Arguments in favor of the electrolytical nature of thn electrical corrfir~tivity of colored collodion films are pre- sented. Fourteen references: 943SR, 2-Hungarian, 3-USA. Table, graphs. Institution Submitted Sept. 21, 1953  vtmfluaare of hydr*gan'on the photoconductivity of e;ffd dye Elms. A. T.Vartany". DokWy Akad. Sauk 5 S.S.R. 94, 82?-3V7751 )f Prfriklalr, .4 14, 013) un the mfluenct J It -r~ Itnt , If fd&si. f. . . ut, w,A -17 t-me d-t- i m Im. erm dem. of its api~.X. ~M-~  -Yel - ----------------------- - ------ clat~?tcft of Ituca baces In acid 4d iiii is 1. The tw-4 - add oxazi" d=.". A. T. V-4-rt"Yan. Zlifir. F"-. 29. 1304-10(1056).~~-Tha app. efmAttlettil fif tbc Pfoilactl(M Y In a forra suitable for att"Ptiou Intasurements Is, Tftesolkitti6iiaraf3dotatitictlyti or =reduced by Saiteutis 1W to lite team baevi. (fit r2tc Ation of V%likit. iutrc-Ates will& the t'MP. Three kucu box$ are ~0)11;11ed fit vocuum Willi ;in (A)q4tvabIt yrf"Kily at trail). CA Bit' till d blither, Its a 0AM110 dwy3roconvrited in the "restm4ing th-cs i~y oxh6tion (dehydruCtnat ion?), fit I, It -11 coindde with the absorption s tM of, tion vpcctru (A WhIL Uie dycs in acid soln. Dtujug such conyerjkm of tr. Ciipc;, BI a lcucot base, Lite steric tffcct of the methyl group tit aa = Ia position to file (litnethylurnhut qroup It not inani(estal, apkiareuily due to i4n Hjual pabibility ef the proton axfdn~ to the mutrat N (itom z% to the dinicUtyl amino group N. M Leuco bases of tripheny1mothans dyes, 16U. IM3- 61-11it method of producing sulid 1e coint. developed for oxaztue and t iazine dyes wa,t tit triphenyl- madiane dyes. Ile inveitigation of the spectra of solkL purafuchsin, Tralz%cidte green, -,n(t crystal violet wtre' similar to the absorption spectra of thtir ~Ic. SONS_ but the in" axe dispLaced by abcut. 10 mA. The foug-yeilye. 11I)SOVP603 b2nd Of tbL tripheji~!mdliane dyi kitco'cornks., at 300 mo was found to be Um triplicnybuttliant: bAnd. displaced by the introduetk)n of dituctitylainillo groupv, and the short-wave ZGU Fuj4 band is ajused by, the dimethyl- I amino Croup, The k-ucrj,-base so(W filrns are only partially waverted Into the dyes by exposure to qualiRnt in the air. The cotivertilon Is incoinplete,and a Whig of -.tit regeuemted dye Cato Wallel Willi Its reginemtion. W. M S.  VARTANW, A. T. -.. -. , , I Z- - _-._ ~,--, L.- . Absorption spectra of leuco-base dyes in acid solutions and as solids. -Part 2. Leuco-bases of solid thiazine and oxazine dyes. Zhur.fiz.khim. 29 no.8:1447-1455 Ag 155. (MLRL 9:3) (Byes and dyeing--Chemistry) (Absorption spectra)  \j R R~T AN-\/ WVn A -7- USSR/Phyeical Chemistry - Wlevxle. Chem:Lcal Bond, BA Abst Journal: Referat Zhur - jDimiya, Ni_-, 19, 1956, 60753 Author: Vartanyan.. Institution: None Title: Absorptio,.)n Sp!~-c:tra r.f Lzti:: -.-Bases of Dyestuffs in Acid Solutions and in Sol�d Sta!~-,. "D::~. Leuc~-Bases cyf T$*phevylne-UE']3W-8 Original P di i l - qlv_ f Zh fi kb 1 ~ 6 er o ca : . z. .Lm .., 1 " _ 955' 9,- 5-15 3 Abstract: Measured were tht -tiltravi., diet absc)rptivn spectra (AS) of s,:7,1.id films of (LB) ~f the triphenylmethane dyes parafuchsin M, malachite ('.U) and crystal violet (III) prepared by sublimati-on in ~mvxl= isee C-mmmicatlon U, Referat Zhur - Khimiya~ 1956, 35001.) ~L' w ell. as by reduction of solid films of the dyes v4ttk gatiie2~~Ls IL S p, c an C at 1000 (12 and 111) d 1.-I 00 (1) Compar:~scm AS -X alc-, h~-.'Etc Boluti,,ms of LB prepared by dissolutf_n i,.f s7.1-A ff'.-Lms and als,~ of synthetic LB shows that the ar o band-i - f ~ic,lit films are d-qsplaced tw-ard Card V2  USSR/Physical Chemistry - Molecule. Chemical Bond, B-4 Abst Journal: Referat Zhur - Xhimiya, No 19, 1956, 60753 Abstract: longer waves by 900-1,000 cm-1 and the short wave band of alcoholic solutions of I# II and LB III reveal a weak oscillatory structure which is $PseA in the solid films. In the LB the band 300 mu constitutes a displaced band of phenyl groups of triphenyl methane, while the band 260 mu is caused by the presence of dimethyl amino groups and constitutes a band of the latter displaced from the far ultraviolet region. In the dark on contact with air films of LB of triphenylmethane dyes are stable; under light in the presence of oxygen the dye is r*Prated but due to theittneurrent process of photochemical oxidati;~ of the dye a complete coincidence is not attained between absorption,Orves of pure dyes and dyes regenerated from LB. AS of products of photochemical fading show characteri8- tic absorption bands with a A(maw) of 358 mu in the case e.. I and II, and 450 mu in the ca6e of III. Card 2/2  \j fi " PHASE I BOOK EXPIDITATION 81.1 Akademiya nauk SSSR Sbornik posvyashchennyy panwati Akademika P.P. lazareva (Collection of Articles in Memory of Academician P.P. Lazarev) Moscow, Izd-vo AN SSSR, 1956. 374 P. 1,600 copies printed. Resp. Ed.: Shuleykins V.V.0 Academician; Editorial Board: Shuleykins V.V.s Academician, Deryagins B.V.s Corresponding Member, Academy of Sciences., USSR, Frank, G.M., Corresponding Members Academy of Medical Sciences, USSR., Volarorich, M.P.., Professor,, Yefimovp V.V.p Professors Maslov, N.M.,, hUzinj A.M.,, Professor; Ed. of Publishing House: Kuznetsova, Ye.B.; Tech. Ed.: Shevchenko, G.N. PURPOSE: This compilation of articles is published in honor of P.P. Lazarev. COVEAAGE: The collection consists of three parts; the first group of articles deals with general physics, the second 'With biophysics and physiology, the third with geophysics. In the Table of Contents, the date on vhich the article was received follows each title. TABLE OF CORTENTS: Card 1/6  Collection of Articles (Cont.) 811 PART I. GENERAL PHYSICS Andreyev, M.N., Member, Academy of Sciences. Comments on the Thermodynamic Theory of Electrostriction (January 1953) 5 Arkad'yev, V.K., Corresponding Member, Academy of Sciences (Deceased). Simplest Form of Solid Bodies of Greater Then Limiting Volume (June 1953) 11 Botvinkin O.K. On the Variability of Some Physical Constants in Industrial Glass WY 1953) 27 Vartanyan.. A.T. Photoelectric Phenomena in Pigments (January 1953) 30 11~ Vershinskaya., V.F. Relationship Betwen the Height of a Mound of Loose Material and Gravity (June 1953) 51 Volarovich, M.P. Investigation of the Uniformity of a Stress Field and Study of the Process of Formation of Cracks in Double-sheared Samples (January 1953) 57 Deryagin, B.V., Corresponding Member, 1cademy of 3ciences, Karasev, V.V., card 216  Collection of Articles (Cont.) 81l Zorinp Z.M. Boundary Phases as a Particular State of Aggregation of Liquids (June 1953) 65 Predvoditelev., A.S.., Corresponding Member., Academy of Sciences. On the Heat- conductivity and Viscosity Coefficients ,of. Liquids and Compressed Gases (June 1953) 84 Rebinder, A., Member., Academy of Sciences. On the Nature of Plasticity and Structural Formation in Distributed Systems (September 1953) 113 Rosenberg,, G.V. On the Problem of Reflectivity of Tinted Turbid Media (July 1953) 132 Tllinaiy A.A., Rosenberg, G.V. Experimental Investigation of the :Feflectivity of Tinted Turbid ~Ledia (July 1953) 143 Tolstoy' D.M. Sliding of Liquids and Distributed Systems Along Solid Surfaces (April 1953) 159 Shuleykin, V.V.j Wenber, Academy of Sciences. Cause of the Bluish Tint of the Sun and the Moon (July 1953) Card 316  Collection of Articles (Cont.) 811 SECTION 11. BIOPHYSICS AND MSIOIDGY Aladzhalova., N.A.., Maslov., N.M. Immediate Changes in the Liver due to the Effects of X-rays (February 1953) 2ZT Asratyan,, E.A.., Corresponding Member., Academy of Sciences. Effects of Transverse Cutting of the Rear Hald of the Spinal Cord in Dogs (Contribution to the Physiology of Spinal Shock) (July 1953) 236 Demirchoglyan,, G.G, On the Initial Stages of the Visual Process (July 1953) 254 Yefimov, V.V., Ollshanskayay N.M. Quantitative Determination of Elasticity of Relaxed and Tensed bftscles and of Diseased Muscles While Bathing (on the Para- doxical Relationship Betveen Relaxed and Tensed Muscles) (July 1953) 274 Xovalevskaya., L.A. The Pover of a Moving Fish (July 1953) 281 Xuzin,p A.M.j, Sayenko,, G.N. On the Effect of Fermentative Poisons on the Various Phases of Photosynthesis (June 195.3) 267 Card 4/6  Collection of Articles (Cont,) 811 Nasonov, D.N., Corresponding Member, Academy of Sciences, Ravdonik, K.S. Effect of Strong Sounds of Explosive Character on the Condition of the Fratoplasm of the Nerve Cells of the Spinal Ganglia of the Rabbit (June 1953) 296 Rzhevkin, S.N. On the Analysis of the Sound of a Singing Voice (July 1953) 305 Seletskaya, L.I. Influence of the Size of the Inductor on the Course of Nerve Processes in the Visual Analyzer (Nicol prism) (January 1953) 319 Cherkasova,, T.I. Investigation of the Chrona.V and Pesslorn Frequency in the Neuro-muscular Apparatus of Man (From the Vievpoint of the Ionic Theory of P.P. Lazarev and the Doctrine of TAbility of N.Ye. Vvedenskiy (July 1953) 325 Shekhtman, Ya.L. Deviations from the Reciprocity Law in Radidbiology (Septem- ber 1953) 332 Yarbus, A.L. On the Problem of Visual Estimation of Distances (January 1953) 341 Yarbusp A.Lp Recording of Eye Motions in the Process of Reading and Examination of Two-dimensional Pictures (January 1953) 344 Card 516  Collection of Articles (Cont.) 811 SE M-ON in. GEOPHYSICS Kolyubakin., V.V.., Ozerskaya., M.L., Fetrova., G.N. Field Apparatus for Deteimiining the Magnetic Properties of Rocks (.Tuly 1953) 351 Lyapunov, A,,A. On the Interference of Seismic Vibrations (JulY 1953) 363 AVAILABIX: Llbrar7 of Congress IsIsfm 1-26-59 Card 616  VARTANTAN, A. T. Acadoilcian A.N. Terenin; an his 60th birthday. Zhur. asuch. I prlkl. fot. I kin. I no,4:310-312 Jl-lg 156. NLRA 9:10) (Terealn, Alskmandr Hikolaevich, 1896-)  V n (-- ~(Ao~An, A. -I USSR/Optics Spectroscopy K-6 Abs Jour Referat Zhur - Fizika, No 5o 1957, 13013 Author Vartanyan, A.T. Inst Title Nature of the Absorption Bands of Leuco-Bases of Thiazine Dyes. Orig Pub Optika i spektroskopiya, 1956, 1, No 4, 478-489 Abstract The absorption spectra of solid layers of leuco-bases of thiazine dyes (thionene, methylene blue, azure 1, methy- lene green GO, toluidene blue 0, thianine blue, and neo- methylene blue), obtained by direct reduction of the solid dye in an atmosphere of H2S at 100 -- 1700, were measured. Comparison of the absorption spectra of the simple aromii, tic amines of leuco-bases of triphenylmethane and thiazine dyes has shown that the long-wave band with a maxinnim of 335 -- 338 millimicrons is due to absorption of the phenyl group, vhile the bandwidth and maximum at 255 -- 268 mali- microns is due to the amino group. Card 1/1  USSR/Optics Optical Methods of Analysis. Instruments. K-7 Abs Jour Referat Zhur - Fizika, No 5, 1957, 13099 Author Vartanyan, A.T. Inst Title Obscure Reactions in Dyes. Orig Pub Izv. AN SSSR, ser. fiz. , 1956, 20, No 4, 448-454 Abstract A spectral investigation of sublimated layers of dyes has shown that while methylene blue (1), crystalline violet (II), and rhodamine 6G do not experience substantial chan- ges in the process of sublination, rhodamines B and G ex- perience partial change, there being formed an uncoloted substance, which is characterized by bands with clearly pronounced maxima at 318, 277 and 235 millimicrons. In the aqueous solution, the uncolored substance changes in- to a corresponding dye. Upon illuminating the uncolored substance in air, there also takes place a regeneration of the dye. At temperatures above 100%, 1 and II Card 1/2  A-11 USSR/Optics - Optical Methods of Analysis. Instruments. K--7 Abs Jour : Ref Zhur - Fizika, No 5, 1957, 13099 interact with water vapors, forming uncolored compounds. A spectral photometric investigation has shown that the resultant compounds have properties of leuco bases. Card 2/2  VARTANYAN, A.T. Temperature depenclence of the electric conductivity of organic ser-d- conductors. Isv.AN SSSR.Ser.fiz. 20 no.12:1541-1547 -D '56. (MLRA 10:3) (Semiconductors)  VARTANYAN, A. I . Interaction between solid dye malts and water vapors at temperatures over 100*. Zhur.fizokhim.30 n9.2:424-436 T 156. (MLRA 9:7) (Dyes and dysix&-Chemistry)  , , - . -7 El , . i. ;A . . lmmmmm~~~~  M~  oz VRir,!19f-K0, A-F 24(7) 3 PHAU I BOOK IXPLOITATION SOV/1365 L'Yov. Vniv*rmytet J, Matarisly X Vs*Sryu;m,>S,) ~"ewichardy* po spektrookopil. t. Ii Malskulyarmaya spektroaknpiya (Papers of the 10th All-Lvdon Conference o.. Spa-:trjacrp7. Vol. Ii *31saular Spectroscopy) IL-voy) Isd-vo LIvoyakago 'inly-ta, 19J7. 499 P. 4 000 copies printed. (Seruss Its Ir-17k, 17P, 5X) Additional Sponsoring A&-vsa*ji AWvmlya nauk 3338. KONISOIY& Pa gpektroskopil. 9d.1 jaser, S.L.j Tech. 14.% Urw-quk T Editorial Boards L&,visterg, O.S., AoAdeatclan (Fleep. id.:VD'~;d*&s*d)' Reporent, B.S., Dontor or Physical and MathavAtical Sciences, Pabtlinakir, I.L., Dootor of Malcal and matheatatleal 3clences, F&bVjk=t, V.A.. Dootor of Ph7slaal and MatheMatIGILI SOLOnOGS, Y, S.M., KomitskIr. V.0.. Candidate of Tec!uiioal Soleness, ftyaki Candidate of FrqmIcal anI MathematLoal Saismcee~ Klimovakiyp L,K,, Candidate of Physcal &r,4 Mat~.ematlcal Soleamo killyanchuk, V.3,* Candidato of W&W&I &--A Mat-herAtical. Sciences " Glauborman. 168a fiouna.m. A. Ys.. Candidate of Physical and Mathemat C=-d 1/30 Shatalow, A.A. Speatral Study of the Colloidal Coagulation of F-centers In Alkali Halide Crystals 146 Flaakovskeya, O.V. Infrared Absorption Spectra of Anthraceno 251 Vartanyan, A.T. Absorption Spectra of Sublim4t~4 Dye rAym- 154 Melankholin, N.M. Absorption Spectra of Thlazine-dys Crystals 157 rrlbrtkova. N.M. I and L.s. Agroskin. Study or the optical Properties Of some Dyes in Large Swiss by the Method or Mirr.7r Reflection 158 Mddkova, 2.V., and Yu. X. Buss. Study or the Street r Dispersion " Mature of the Ad- 0 0 = 3peetral Absorption Curve, of Absorbed t n: 3ensItIsod Dy a : 161 Card U/30  VOTANW Absorption spectra of sublimed lavers of dyes. 71z. abor. no*3: 154-156 '57; (Pinacyanol-Speotra) (MIRA 110) (Ehodamine-Spectra) (Auramine-Spectra)  V, Jq 'C' SUBJEM USSH~Luminescence 48-4-15/48 AUTHORt Vartanyan. A. T. TITLEs Semiconductor Processes in Organic Dye Layers (Poluprovodni- kovyye protsessy v sloyakh organicheakikh krasiteley) PERIODICALi Izvestiya Akademii Nauk SSSR, Seriya Fizicheakaya, 1957,Vol 21, #4, pp 523-524 (USSR) ABSTRACTs Investigations of electric and photoelectric properties of dyes have shown that they can be considered as a class of organin semiconductors, Temperature-dependence of electroconductivity for many dyes is described by the formulat 6. exp where Er is activation energy, which has the following values for various dyes: 2.28 for trypaflavins, 2.13 for eosine, 2.15 for erythrosine, 2.08 for phloxin, 1.8 for pinacyanol, and 1.6 ay for phthalocyanin. Photoconductivity-temperature dependence obeys also to an ex- Card 112 ponential law, but the values of activation energies are  48-4-15/48 TITLE: Semiconductor Processes in Organic Dye Layers (Poluprovodni- kovyye protseaay v sloyakh organicheskikh krasiteley) several times lower than those for electroconductivity. Under vacuum, the dependence of photocurrent ip on illumination intensity L is expressed by the formulas i9b =a/-", where n is a constant for a given layer, having values between 0.5 and 1. The photoconductivities of eosine, erythrosine, phloxin, phthalocyanin and some other dyes increase in the presence of oxygen. The values of optical activation energies for some dyes were determined by means of a "photoelectric straight linea" method. The obtained regularities and activation energy values can be used for further studies of photoelectric properties of organic phosphors activated by dyes. No references are cited. INSTITUTION: (presumably) Institute of Physics of the Estonian Academy of Sciences PRESENTED BY: SUBMITTEDs No date indicated. AVAILABLEi At the Library of Congress. Card 2/2  W--. ma'-.0,510  V AR,_T _)(_~ rl Y /~ I I j -) 1~ ~ T. AUTHOR JARTANYAN A.T., NARPOVICK I.A. 20-5-20/67 TITLE on the rhatooo Uotance of the Violanthrone (?) and of the Pyranthrons. (0 fotoprovadimosti violantrona i pirantrona.- Russian) PERIODICAL Doklady Akademii Vauk SSSR 1957, Vol 113, Nr 5, pp 1020-1021 (USSR) ABSTRACT The paper under review prosents the results of the investigations of the photooonduotanoe of layers which are obtained by rubbing-on of the powder of the violanthrone (dark blue indanthrene YO M) and of the pyranthrone (golden-orange indenthrene G (?)). The investigation was oarried out with the aid of an devSoe that had already been described in an earlier paper. The layers (oPa thick- ness of 0.1 to neiiMAIniorons) were applied to a 'quartz finger' containing platinum electrodes. The photoconduotance was investiga- te& in vacuum, although the presence of air does not affect the results in any considerable way. A tungsten incandescent lamp of 100 W was used as source of light, and the light was decomposed by a mirror monochromator with vitreous optical system. The distri- bution of energy with respeot to the wave lengthes was determined by means of a thermoelectric pile. The current intensities of the order of magnitude of lo-13 a were measured with the aid of a direat-ourrent amplifier. CARD 113 Several sooonds after the layers have been exposed to light, the  20-5-20/67 On the Photoconductanoe of the Violanthrone (?) and of the eyran- throne. photoourrent becomes constant and then deacreases almost equally fast if the exposure to light is terminated. If the obeeryation is car- ried on for longer periods, an additional increase in the Dhoto- current will be frequently noticed. If this long-period exposure to light is suddenly terminated, the photocurrent first of all quiokly deoreasesp but there always remains a remanent photocurrent which decreases only slowly. The photocurrent obeys the Ohm's law,at l4aist at field strengthes uP-to 4000 V/om. The dependence of the phots- current It on the intensity L of the exposure to light Is described by the mathematical relation it - & , with a and n denoting constants. In the layers under investigationt n always remained below 1 and amounted to 0.7 to 0.9, depending on the thickness of the layer and on the intensity of the exposure to light. A. diagram enclosed to the paper under review shows the spectral curves of the photosensitiyity S of the thin layers of the TiOlantrone and of the pyranthrone. The optical activation energy was determined with the aid of two different methods, and the results obtained by the authors of the present paper are twice as high than the Yalues CARD 2/3 given by other authors. This phenomenon probably is caused by  2u-.-)-Ljo/67 On the Photoconductance of the Violanthrone (?) and of the Pyranthrone. a change of these coloring substances a result of multiple sublimation. (2 reproductions) ASSOCIATION: not given. PRSSENTZD BY: A.R. Terenin, Member of the Academy, 10-9. 1956 SUBMITTED., 14-9. 1956 ATAILABLIB: Library of Congress. CARD 3/3  On the Problem of the Valve-Like Plitoelectroinotoricul Power 01- 20-1-14/42 the Photoelectric Cells With Dyes. where A and B denote con4tant2. A further diagram illustrates the volt-auLpere dependencer. of the dark current and the photo- electric current for a photoelectric cell of the type I with pinacyanol. This dependence gives evidence of the existence of a barrier lajer.The photoelectric current increases together with the tension in the pass direction and tends towards a sat- uration;in the barred direction it winks towardG nil.In the case of a photoelectric cell of the type II the pass direction and the barred direction change their parts as against the cells of the type I and vice versa. A photoelectric cell of the type III does not show any rectifying properties,the dark current at small tensions responding to Ohm's law.Thi5 result confirms the lack of a barrier layer. The here found results are also valid for photoelectric cells with orthochromine T and with crystalline violet, but they hardly agree v;ith the assumptions on the valve- like nature of the photoelectromotoric power. There is no cau2a- tive relation between photoelectromotaic power and barrier layer. So far the iitructure of the barrier layer and the mechanism of the rectifying at the contact dye- metal have not been explain- ed. The photoelectromotorical power excluuively develops from the asympletry of illumination of both electrodes, it does not Card 2/3 depend on the kind of the contact and of the electrode material.  On the Problem of the Valve-Like Photoelectromutorical Power of 20-1-14/42 ,the Photoelectric Cellj With Dyer.. There are 2 figures, and 6 referenceu, 3 of which are Slavic. PRESENTIDt June 1, 1957, by A. N. Terenin, Academician SUBMITTED: May 24, 1957 AVAIIABLE: Library of Congress Card 3/3  A- K T- V 1,4 N rq I'v- - 7- 76-1-27/32 AUTHORSt Vartanyan ^A T Karpovich, 1. A TrTLE% The Semiconductor Properties of Phthalocyanino (PoluDrovodnikovyye svoystva ftalotsianjr~ov) I. Electro- and Photoconductivity of Plithalocyanines in Vacuum and in Oxygen (I. Glektroproyodno3t' i fotoprovadimost' ftalotsiani-nov v vakuume i v kislorode) PERIODICALs Zhurnal Fizicheskoy Khiraii, 195U, Vol. 32, Ili, 1, 1)?,.178-1,97 (USjR) ABSTRACT: Ifere, the investigation results already given by the authors in re- ference 10 uro treated in a more detailed manner. The apparatus, by which the investiCations were carried out, has been described already earlier (reference 11). Phthalocyanine without mQtr-l (Ft) and phthalocyanine of copper (Ft - Cu) of zinc (Ft - Zn) and of magnesium (Pt - Mg) were investigated. 1. Blectroconductivity. ) The Ft - Cu- and Ft - Zn layers obtained bj means of distillation in the vacuiim and subaitted to an a3ditional degas:3ing at 200 0C, show an ii5initely small electrveonductivity at room te2perature. - ' - < 10 ohm ). Here, the dependence of electroconductivity of ( 0 such layers on temperature in the range of about from 60 up to 1600C is shown in a diagram. The variation of electroconductivity Card 1/4 accordinG to the temperature can be expressed by the following U  76-1-27/32 The Semiconductor Properties of Phthalocyanine. 1. Electro-and Photoccnductivity of Phthalocyanines in Vacuum and in Ox-jgen Qquationt 0' a 6' exp(- E /2kT) . At Pt and Vt - CU 1,7 � 0,1 eV and at Yt - Zn 0 F_ - 1,0 + O'l OV. hough estinateo [in application of extrapolation zhow in the casj of the specific con- ductivity of these phtbalocyan nes at 000 teupeiature values of the order of maGnitud i - -15 -1 - 0 of 10-1 10 ohm cm . 2t - Me, layers under equal conditions show a conductivity being almo3t 1000 times greater. Values of about 1,2 eV were obtained fo--- the activation energy. As it is shown in the following Yrork this value is srualler than that one obtained for the optic activation energy. It is ex- pected that the conductivity of the Pt - Mg layer at the experi- ments carried out here, was an impure one. In the presence of oxy- gen the conductivity of the Ft - Cu-, Ft - Zn- and Ft - 111g, layers increases. The sensitivity of the Ft - MC; layers in relation to the oxygen is as great that a pressure of 0,1 mm of mercury is suffi- cient to cause an essential increase of the clectroconductivity. At room temperature ths electroconductivity of the layers treated in oxygen at 150 - 200 C is almost by 1o4 1 105 tiLies Ureater than in vacuum. At a temperature rise the conductivity increases ac- cording to the law: i!r T exp(- E,/2kT). However, the value E is essentially smal%r 1han the value FE , which was obtained Card 2/4 in 1he vacuum. The value El depends on the oxygen pressure. The  76-1-27/32 The Semiconductor Properties of Ynthalocyanine. 1. Electro- iind Yhotoconductivity of Phthalocyanines in Vacuum and in.lDxygen behavior of phthalocyanine complexes in oxygen proves the occur- rence of an impure conductivity. The increase of the activation energy of Ft in oxygen is to be attributed to the increase of the energy threshold at the boundaries between the microcrystals. 2.) Photoconductivity. An illumination by visible li~;ht of plitbalo- cyanine layers carefully dcgassed with high isolation properties causes an essential increase of the conductivity. The oxygen also increases the photoconductivity. In layers with oxygen generally does not form a space-charge. A noticeable retardation of the sta- bilization of the steady photo-current and its decrease after stop- ping the illumination is observed. The photoconductivity of the layers with oxygen is essentially hi.-her, than that in vacuum. The layers of phthalocyanine free from oxygen have an inertialess pho- toconductivity. In this case the photoconductivity is linearly re- lated to the intensity of illumination, and exponentially increases at a temperature rise. Some repults point to the presence of tran- sition resistances in the phthalocyanine layers which weru obtained by the sublimation. Taking into consideration the essential in- crease of the photoconductivity in the layers Ytith oxygen the con- Card 3/4 clusion is drawn here that besides the recombination (which causes  76-1-27/32 The 3e.Ticonductor Properties of Pbthalocyanine. 1. Electro- and ilhotoconductivity of Phthalocyaninos in Vacuum and in Oxygen the linear dependence of photoconductivity on the illumination intensity) a direct reconbination of electron3 of the free iLone takes place with the holes, and causes the "nonlinear" photocon- ductivity. It is assumed that the light absorption in the molecular crystals of organic compounds are accompanied by a fornation of the exitons being movable in the crystal. There are 9 fiaures, and 13 references, 8 of which are Slavic. SUBMITTED: September 20, 1956 AVAILA13LE: Library of Congrese Card 4/4  76-32-2-8/38 AUTHORSt Vartanyan, A. T. Karpovich, I. A. (Leningrad) TITLEt The Semiconductor Properties of Phthalocyarines (Polupro- vodnikovyye svoystva ftalotsianinov) II. The Spectral Dependence of the Photoconductivity and of the Optical Activation Energy of Phthalocyanines (II. Spek- tral'naya zavisimost' fotoprovodinos"i i opticheskaya ener- giya aktivatsii ftalotsianinov) PERIODICAL: Zhurnal Fizichakoy Khimii, 1958, Vol. 32, Nr 2, pp. 274 - 281 (USSR) ABSTRACTs The spectral curves of the photoconductivity of phthalocyani-. nes as well as the values of the optical activation energy are given. The method of investigation is already described in Reference 1. The authors investigated phthalocyanine without metal, as well as copper-zinc-, and magnesium-phthalo- cyanines. It is shown that: 1) - The thickness of the layer and the non-linearity of the photoconductivity in phthalo- Card 1/3 cyanines exercize an essential influence on the shape of the  76-32--2-8/38 The Semiconductor Properties of Phthalocyanines. II. The Spectral Depen- dence of the Photoconductivity and of the Optical Activation Energy of Phthalocyanines spectral curve with regard to the photoconductivity and the results in the determination of optical activation energy. 2) In thin layers the spectral curves -' the relative photo- conductivity calculated by taking into account the non-lineari-, ty of photoconductivity show good coincidence with the ab- sorption etves. 3) The introduction of oxygen into the phthalo- cyanine layer on the one hand essentially increases the total photoelectric sensitivity, but on the other hand does not exercize any essential influence on the spectral distribution of photo-sensitivitY. 4) The A 1/2 method and the method of the "photo-electric straight line" show close values for the optical activation energy of the phthalocyanines when thin layers are used and when the non-linearity of photo.. conductivity is taken into account, 5) The optical activa- tion energies obtained for phthalooyanine without metal as well as for copper- and zinc phthalocyanines well agree with earlier determined thermal activation energies. 6) The re., sults obtained here coincide with the earlier investigated scheme of the energy levels in phthalocyanines as well as Card 2/3 with the conception on the primary formation of the excitons  76-32-2-8/3~ The Semiconductor Properties of Phthalocyanines. II. The Spectral Depen- dence of the Photoconductivity and of the Optical Activation Energy of Phthalocyanines in the case of light absorption. There are 7 figures, and 11 references, 6 of which are Soviet. SUBMITTEDt September 20, 1956 1.,Ph~4algayanine,s-rPhotoconductivity 2. Phthalocyanines--Spectra 3. Phthai&cyan'i'i~es--Photosensitivity 4. Phthalocyanines--C)ptical properties Card 3/3  76 32-3 bV43 ALITHORSi Vartanyan, A. T, Karpovisb, I. A. TITLEa Blectrlee"LC,, tj,~.jtyane Ev~-V,?conductivlty of Plpa-.yanol arid Orthochromium T kElektraprovodnostl i fotopx-~vodiscstl pina tsianola I ortokhroma T" PERIODICALt Zhurnal Fizlohe8koy Kh.'MiivI958-,Vo1 32,.Nr? 3,PP 543-553 (USSR) ABSTRAM Already in preceding papers A. T VaIrtanyan (Raft, 1'. Z~ 3) determined the photoconductIvIty'of phuto raphic isenOtizors and deRensitizers. Ye. K. Patnefto (Ref Z irvestlf:ared the photcele-etrin, sensitivity sf a number ctf sensitizers by means of the condenser method. The xesults obtainod by Noddanlr, and Meier (Refs 5., 8) aaccrding to the methcd vf the "ph,.i+-r;-- electric. atraight, line" for pina,%yanol, as well as bj Nelsen. (Ref 9) in datevaining the photo-~-.ond,xctivitj A a num'~,er Cf cyanine dyes., nontradict-Lons ., wbicli :-.an be explained by the results of the prerading paper,. The investigatz.c.rs mentiored in the title were performed in vacuc... as we---'L as in the presene-a rif oxvgen and steam.. Data on the expexicent-al Card 1/4 procedure are mentionel. The investiga-f-Jona in -rhc-.  7 3.1 -8/43 3 Electrl,zl C,~.a6uc-,' and Photczondactivity of Pinal:7ang! and Or! 11 , C- 11 A UriT showed a s;ecifj-1, i-_--rLjqra& of ',~e order of majn_~tude 10 and '10 ~2-**~-;r' av-2 thermal aoti7atlon enerej c)f :r 2,)05.L0.` eV -tively. The rhctocunda_-+,_-v1ty 7.::nslder?~bly fr,-~reases .111uminati on., and irks t,!mparafurp, depurdenvi: .3 S,.,bie I. J 'I xc exporentia' la%.. c_ -ept f temioratt~res ~elovr 4 -tcv~+, va.3 nz~t Th r f the apentral euvre vf depinla ,,,i 1~,, f*ni nees J the layez of dye, as we',I. as -~n t1le, t,,altv- a L~i tha eq~aati,.n aLr (Relf 11). THa c.;ar- be vent'~-n-wil as ain e-x planation,,tt :,~t C! (Re! for the olta;,ned "rapsd" zoivyonen* ,7yanoln ~.:)nporen-t on the illuntinat.,_or. wh,~tr-a. tvtwei;-ar. the course has +o be :;onsider-3d (al3u in otseiving Ifel aon's vestiCations) . A:;nording 4,0 (Ref 13))th,- opti.:~ acts').'.. tion ener.-y iar be deteTvined from the spectral --,ur,rea photo. sersiti-v-.'ty, in th.,Ln layers from the "Icng wa~-. as well aa a-:C,)rd1116 1;-j 'rN. stratgtt method, of Lang-~ (Ref `4), Th~ cbtaln-~!-resul,~a assr--) well, with ea:Ah other. ar, we')l a,-;, with the tha=al '.n J;nc Card 2/4 gies, whereat. fiie lal,t;.,,r ranez,,t a-xac-.tI,-f be de-F~x-_,.'ned I uy;:]  76-,32--3-5/43 Electrical Conductivilyand Photoconductivity of Pinacyanol and Orthochromium T the other hand, show somewhat higher values because of the effect of the transition resistances on the micro-crystallite boundaries. Dry oxygen has no effect upon the darls.-con-. ductivity;h%wwar, ~t &'xinjohao'he photoconductivity by means of a chemical reaction with the dye. Experiments on this problem are still to be performed. Steam produces an electdc- al conductivity, in Uhich case the influence upon the photoconductivity depends on the preliminary treatment of the layer. The investigation with moist oxygen showed a phenomenon? apparently analogous to the Becquerel -effect, o'f photo-electrochemical nature under formation of an electro- motive force. The hoto-electromotive force observed by Noddack and Meier Nefs 59 8) on solid layers can difficult- ly be identified with the obtained results of this paper. There are 8 figures, 1*tablep and 20 references,.12 of which are Soviets Card 3/4  tivity 76..32,3-8/43 .Electrieal Conduc-/ -in dPhotoconduotivity of Pinaoyanol and Orthochromium T SUBMITTED# September 20~ 1956 Card 4/4  r Lu- a 3 o i . i i Ol Le no WT ;L~4 do -0 01~ 0 1 3 I. .2 va- u rv - E J-0 13 - -t~ '4 =~'ko 0 .1cm 17 L.0 in  IX THOER-S Lyzina, L_-~. ard Vartanyan, i-T. TITLE; Absorption Spac~;ra o-r-D-y-e-Layers in Vacuum (Spektry pogloshcbeniya sloyev krasiieljy v -,rakuuma) Fl~,jUODIGAL; Optika i Spektrtos~:opiya, 19D, Vol 6, Nr 2, pp 172-180 (USSR) ABSTPACT: The paper describ3s a technique for production of solid layers of dy3S by sublimation 7,nd subsequent measurement of their absorption ~ru- in vacuum. A s o-3 cial glass c a 11 , shown in Fig la, was us ad -to prepare dye lay-_rz; and to mutLsure their spectra. A solid layer of dy.-- r.;as deposited from solution in a. cup-like extension 0 (Fiv- 1b). fused quartz plate Y vas placed above the extension 0. The cell was hold horizontally, evazuated and the dye layer in 0 was hoatej extanaally by M"ns nf a amall electric furnace. This produced a sublimatod layor on .1p. The C031 ms then placed in a vertical position (Fir, la or 1b) and the plate ? dropned to the position 1 in Fig la, whera two quartm windows were provided - bimansions of the c a 11 wire such that it fit~,od exactly in the holdor of a SP-4 a pectrd photometer, which was usod for measurements. Measurements were carried out with the a all S ull evacuated and iiamodisitoly after deposition of a dye layer. In card 1/5 sublimation of dyo;3 the authors used Vartanyan's data (Ref 3). They  Absorption Spectra of Dye Layers in Vacuum SOV/51-6-2-8/39 found that to avoid overheating the initial, deposited from solution, layer of a dye should, in general, be thin and uniform; only rhodamine B layers should be iticic. It was not possible to obtain an undecomposed layer of malachite green using the ca 11 shown in Fig 1. Be;t results were produced by rapid sublimation. To check that the sublimated layer is free from decomposition products the authors measured absorption in the ultraviolet region which was sensitive to impurities. 'the absorption spectra of sublimated layers of twelve dyes are shown in Figs 2-7 in the form of optical density curves (thickness of the sublimated layers was not measured and no correction was made for reflection). Figs 2-7 show also the spectra of dye layers proauced by deposition from solution and spectra of solutions of the same dyes in water, alcohol, benzene etc. For scme dyes spectra of sublimated layera measured in air are also given. The curves of Figs 2-7 give the spectra in the visible re6ion; data on absorption in the ultraviolet are giv-3a in a table on p 178. Fig 2 showc thu spectra of triphonyloothane dyes.- (a) fuchain and (b) crystal violet; curves 1-6 represent, respectively, 3ubliinated layers measured under vacuum, dilute aqueoua solutions, concentrated aqueous solutions, Card 2/6 alcohol solutions, layers deposited frem soiution and benzene solutions.  Absorption Spectra of Dye Layers in Vac-xum SOV/51-6-2-i:/33 Fig 3 shows the spectra of acridine dyes.- (a) rhoduline orange and (b) trypaflavine; curves 1-6 represent, respectively, sublimated layers measured under vacuum, dikate aqueous solutions, concentrated aqueous solutions, alcohol solutions, sublimated layers measured in air, layers deposited from solution. k1g 4 shows the spectra of azine dyess. (a) phanosafranine and IN) safranine 0; curves 1-6 represent, respectively sublimated layers measured under vacuum, dilute aqueous solutions, concentrated aqueous solutions, alcohol solutions, layers deposited from solutions and benzene solutions. Fig 5 abows the spectra of xanthane dyess. (a) pyronine and (b) rhodaminas 6G and B; c,.xrves 1-5 represent, respeotively, su'ilimated layers measured under vacu-im, dilute aqueous solutions, concentrated aqueous solutions, alcohol solutions, layers deposited from solution. Fig 6 shows the spectra of auramine 0; curves 1-4 represent, respectively, sublimated layers mwrur6d under vacuum, aqueous solutions, alcohol solutions, layers deposited from alcohol solutien. Fig 7 shows the spectra of thiazine dya5.- (aj thionine and (6) methylene blue; curves 1-5 represent, respoctively, sublimated layers measured under vacuum, dilute aqueous solutions , concentrated aqueous solutions , alcohol solutions , sublimated layers measured in air. Fig 8 shows the dependence of the absorption of Card 3/5  Absorption Spectra of Dye Layers in Vaa--= SOV/,51-6-2-8/39 arramine 0 on the solution concentration.- (a) alcohol solutions (-b, dichloroothane solutions. In all the twelve dyes absorption by sublimated layers measured under vacuum differs considerably from absorption by layers deposited from alcohol solutions. This difference is the same in all the dyes considered; in the visible region the sublimated layers absorb more strongly at longer xavolen&ths ttian do the layers d6posited from solution. The converse is true for short wavelengths in the visible range. The differences may be due to the fact that the layers deposited from solutions are more continuous than those prepared by sublimation. Moisture affects strongly the absorption spectra of sublimated layers-, the absorption curves are different for sublimated layers measured in vacua and those measured in air (a.-. Fig 3 curves 1: and 5, Fig 7 curves 1 and 5). The spectra of the sublimated layers measured in vacua differ also from the spectra of solutions. Tnis difference is smallest in auramine 0 spectra, where only some broadening occurs due to stronger interaction of the dye molecalas in the solid state. In the case of the other dyes the differences between the spectra r,ard 4/5 of subli=ted layers measured in vacua and the spectra of solutions may  Absorption Spectra of Dye Layers in iacu,= SOV/51---2-e/39 be due to adsorption farz5i; between the sublimated layers Pnd the quartz plates on wnich they are deposited. There are 8 figures, I table and 6 references, 5 of vihich are Soviet and 1 English. SUBMITTED: March 4, 1958 Card 5/5  24(7), vr(s) 0OV/51-6-4-N/29 AUTHORSs Lyzina, L.A. and Vartanyan, TITLE: The Effect of Water Vapour on the Absorption Spectra of Sublimated Dye Layers (Vliyaniye parov vody na spaktry pogloshcheniya vozognannvkh sloyev krasitelay) PERIODICti.L: Optika I Spaktroskopi.A, 19.59, Vol 6, ",r 4, pp 484-491 (USSR) ABS TV, CT In an earlier paper (Ref 1) the authors showed that the absorption spectra of sublimated dye layers measured In vacuo differ from the spectra of these layers exposed to air. The differences are due to structural changes due to atmospheric water vapour. These changes were the subject of an Investigation reported in the present paper. The method of preparation of sublimated layers and the call used for measurements of their absorption spectra measured under vacuum wrre ti:.-. same as described in Ref 1. After the absorption spectra were meAsured in vacuo, water vapour of known vapour pressure was -Amitted into the call containing samples. The spectra were then re-measured after 20-30 mins from the moment of admission of water vapour. The following dyes were Investigated.- rhoduline orange (Fig la), trypaglavine (Fig 16), crybtal violet (Fig 2a), fuchsin (Fig 2e), Card 1/2 phanosafranine (Fig 3a), safranine (Fir, 34). thionine (Fig 4),  SOV/51-6-4-12/29 The Effect of Water Vapaur on the Abaorption Spectra of Subljm~ited Dye Layers auramine (Fig 5), rhodamine 6G (Fig 6a) and rhodamine B (Fig 66). The rosults obtained are interpreted as follows. The dye layers prepared by BublJ18-AtiOn in vacuo are originally amorphous - In the presence of mter vapour the dyes aggregated to approximately the same de6rea as In concentrated aqueous solutions. In some dyes water vapour induced irystallization (auratitine, methylene blue, thionine). In solid layers of dyes, depending on the exturnal conditions ivacualt, water vapour), there may exist different types of absorbing centreu, in the form of "frae" molecules, molecules affected by the substrate, aggregated molocules and microcrystallites. The form of the absorption. curves is detmrmined by the proportions of these absorbing contras. There are 7 fl6uras and 7 reforences, 5 of .-YhIch are Soviet and 2 3nZl1sY SUBMITTED: April 23, 19.% Card 2/2  24(3) AUTHORS: Vartanyan, A. T.t. Rozenshteyn, L. D. SOV/20-124-2-14/71 TITLE: The Photoconductivity of indigo (Fotoprovodimost, Indigo) PEPIODICAL: Doklady Akademii nauk SSSP, 1959, Vol 124, Nr 2, pp 295-297 (USSR) ABSTRACT: As far as the authors know, the electric and photoelectric properties of indiCo have hitherto not been investigated. The present paper shovis that indigo possesses photoconductivity and is a typical organic semiconductor. Indigo is nearly insoluble in the usual readily volatile solvents. Therefore layers were investigated which had been produced by sublimation of the dye in a vacuum ("10-5mm) at a temperature of 130-1400 C. -2hese layers were located on the surface of a quartz vessel upon which platinum electrodes had previously been fitted. Amperages were measured by means of a direct current amplifier, and the light was monochromatized by means of a mirror monochromator ISP-17A. The relative spectral distribution of the energy inciding upon the layer was measured by means of a thermopile. Dark conductivity increa3c.9 with increasing temperature, The Card 1/3 temperature dopondence of' the (lark current, which was determined  The 1hotoconductivity of Indif;o SOV120-12ilt-,~-1,11'(l zaati-sfic-2 t,:e ecuation within the intervalof 40-1100 C, im 0exp(- EM/?kT), ..hich holds in the casi) of Liany dyan and pigments. Under wwuum condition.- 11-11,,e activ-.tion en,,~r,-j has the value FE M ~ 1-75 ;1- 0-05 ev , agrees satir- Pactorily Yith '%,-;-,e -absorption spectruo of a solid indigo layer produced by sublimation. Under vacuum, conditions the exposure of indigo layera by meann of visible lit;ht increases conductivity wi thin the rttnge of absorption. In the case of exposure with monochromatic light conductivity may be increased by tile do--en- or hundredfold. Also if oxygen is supplied, indiLo conductivity increases, in which case the increase depends on the pressure and the duration of the action of the Gas. In a vacuum as well as in an oxygen atmosphere the time necesaary for the development of a steady photocurrent during exposure (and for the decrease of the photocurrent in the dark) is less than the time constant of' tile amplifier circuit. Card 2/3  The Photoconductivity of Indii_,o SOV/20-124-2-14/11 The temperature coefficient of the photocurrent is raositive. The shape of the spectral curve of photoelectric sensitivity depends to a considerable extent on the thickness of the indigo layer. The optical activation energy is -o1.79 ev, which agrees well. .,rith the thermal activation cnerL-y of dark conductivity. Th~.-re are 2 figures and 12 references, 7 of which are Soviet. PRESENTED: October 2. 1958, by L. N. Terenin, Academician SUBMITTED: September 25, 1958 Cal~-d 3/3  .. . I 1) 4. '? ? 00 68979 AUTHORSs Vartanyan, A. T., Rozenshteyn, L. D. 8/020/60/131/02/017/071 B013/B011 TITLEs On the Participation of the Excited Singlet State in the Electrical Conductivity of a Series of Organic Semiconductors JA PERIODICALs Doklady kkademij nauk SSSRq 1960, Vol 131f Nr 2, pp 279 - 282 (USSR) kBSTRACTt The aim of the present paper is that,of determining the electrons ' either on an excited singlet level or on a (which are situated triplet levei) that cause electrical conductivity in the dark, that is, in other words, whether the activation energy of eleotrioal con- ductivity in the dark corresponds to the height of the triplet level or of the excited singlet level. Reference is made to a new idea advanced by A. N. Terenin (Ref 8) on the nature of photoconductivity. The application of data concerning the phosphorescence of solutions to the solid state is said to be unjustified. The objects investi- gated here are supposed, on the one hand, to be phosphorescent in the solid state, and on the other hand, the distance between the triplet level and the excited singlet level is expected to be as many times greater as possible compared to the error in measurement 6M (here - 0.1 ev). The investigation was therefore made on benzo- Card 1/3 phenone, anthranilie acid, phenyl anthranylic acid, as well as on  68979 On the Participation of the Excited Singlet State in S/020/60/131/02/017/071 the Electrical Conductivity of a Series of Organic B013/B011 Semiconductors 3-acetYl,amine-N methyl phthalimide, 3-acetyl amine- X phenyl phthalimide, and 3-benzoyl amine- N methyl phthalimide. Moreover, the electrical conductivity of fluorescein as well as of some other dyes was investigated. Sufficiently thick (- 50,A) and dense layers were prepared by sublimation of the substance in high-vacuum (^,10-5 mm). These layers were sublimated on the surface of a quartz vessel. The voltage source was a dry-cell battery (560 v). In order to be able to measure the absorption spectra, the layers were applied to a quartz plate which, in turn, was fastened to a rotating faceplate. The results of measuring the temperature dependence of electrical conductivity are reproduced in figure 2. The wavelengths corresponding to the thermal activation energies CL arein good agree- ment with the longwave drops of the absorption curves. The totality of the results obtained is indicative of the followingt Electrical conductivity of the organic semiconductors investigated occurs an an excited singlet level. This also holds for thionine, crystal violet, phenosafranine, etc. The attribution of e m to the excited Card 2/3 Binglet state leads to the following assumption: This relatively  68979 On the Participation of the Excited Singlet State in S/02 60/131/02/017/071 the Electrical Conductivity of a Series of Organic B013%011 Semiconductors Blight disturbance is sufficient for the formation of a certain generalized zone within the boundaries of this state. Dark con- ductivity is found in this generalized zone. The authors thank V. V. Zelinski and 1.. 1. Reznikova for having prepared the high- purity phthalimides, and V. L. Yermolayev for having supplied the instrument used to measure the phosphorescence spectra, and also for advice given. There are 2 figures, 1 table, and 10 referenceaq 9 of which are Soviet. PRESENTEDs November 20, 1959, by A. N. Terenin, Academician SUBMITTEDt October 30, 1959 Card 3/3  7- q, 11177 g ~' /Z-/.? AUTHORS: TITLE: PERIODICAL: 83898 S/020/60/134/003/008/020 B019[BO60 Rozenshteyn, L. D., Vartanyan, A. T. A Study of the Surface Recomb~ Layers of Organic Dyes - Photoconductors Y\ Doklady Akademii nauk SSSR, 1960, Vol. 134~ No. 3, pp. 567 - 570 TEXT: By way of introduction the authors discuss the results yielded by investigatione,most of which were conducted by the authors themselves, The result Is concern the photoconductivity of inorganic and organic semi-- conductors.4he formula derived by De Vore (Ref. 6) for the photocurrent is given aTid discusned. This formula is regarded as being an expression characterizing the change in the photocurrent on a variation of sample thickness 1 at a determined wavelength of incident light. The authors wanted to carry out a quantitative evaluation of De Vore's theory for the surface recombination rate in linear photoconductors. They further wanted to determine lifetime, diffusion coefficient, and mobility of the photocurrent carrier. For this purpose, they examined variously thick Card 1/2  83898 A Study of the Surface Recombination in Layers S/020/60/134/003/008/020 of Organic Dyes - Photoconductors B019/Bo6o trypaflavine and pinacyanol layers for their spectral photoconductivity in vacuum. Fig. 1 shows the photocurrents as functions of the wavelength of incident light along with the absorption relative to the two dyes examined. Figs. 2 and 3 show the photocurrents as functions of the layer thicknesses for three different wavelengths. With the aid of a -r-meter the lifetime was found to be 1.1-10-4 see, and this quantity served for de- termining the recombination rate on the surface and the carrier diffu- sion coefficient. The values are tabulated in Table 1. The diffusion coefficient, the recombination rate, and the carrier mobility of the dyes examined were found to be smaller than those previously observed on tr inorganic semiconductors. This is partly brought In connection with a reflection effect caused by the smooth surface of the semiconductor. The authora thank Ye. K. Putseyko and 1. A. Akimov for having supplied the T-meter and for valuable advice given. There are 4 figures, 1 table, and 12 references: 6 Soviet, 3 US, 1 British, 1 French, and 1 German. PRESENTED: April 29, 1960, by A. N. Tereninj Academician SUBMITTED: April 19, 1960 Card 2/2  7ARTAWAN"..T,&,, mladshly nauolmyy aotrudnik Use of the new muscle relaxant brcmotilin in Intratracheal, ether-oxygen narcosis. Vop.rent.i onk. 6tZ73-Z78 161, (KM l6s2) (MUSCLE RWAWTS) (INTRATRACHM AHSTHESIA)  VARTANYAN, A.T.; ROZENSHTEYN, L.D. Thermal activation energies of dark conduction in organic c=poundso Piz. tvor. tela 3 no.3:713-722 Mr 161. (MIRA 14:5) 1. Gosudarstvennyy opticheakiy institut imeni S.I. Vavilova, Leningrad. (Electric conductivity) (Organic compounds-Electric properties)  U 20854 S/04816110251,jO310441047 6 13 11S) B104/B203 AUTHORS- Vartan an, A. T. and Rozenshteyn, L. D. -TITLE: Comparison of 'the thermal activation energy of electrical conductivity with.the absorption spectra and phosphorescence spectra of layers of a number of organic compounds PERIODICALi Izvestiya Akademii nauk SSSR. Seriya fizichaskaya, v. 25, no. 3, 1961, 428-430 TEXTs. This paper was read at the 9th Ccn.0prence oi' Luminescence-(Crystal Phospho3~p) in Kiyev, June 20-25, 1960. The authors determined the activa- tion energy from the temperature dependence.of the electrical conductivity, which is described for organic semiconductors by the formula 6' 6' exp(-f-/2kT), where t is the thermal activation energy. Fig. 1 0 T T shows the temperature dependence of the dark conductivity for a number of substances. Table 1 compiles the results of measurement for a great number of compounds. The spectral range (indicated in Column 5) in which the longwave drop of the spectral absorption curve occurs corresponds, accordi-rz Card 1/5  20854 S/048/61/025/003/014/047 Comparison of the thermal ... B10A/B203 to the authors' opinion, to a singlet-singlet transition in light absorp- tion. 71-9 energy corresponding to the shortwave edge of the fluorescent band is givon in Column 6, and parmits a dotormination of the height of -the triplet level in that state of the compound in which it was investigated. A comparison of results shows that the carriers parti- cipating Ln dark conduction are produced in singlet-singlet electron transitions. There are 1 figure, 1 table, and 6 references: 5 Soviet- bloc and 1 non-Soviet-bloc. M9aaXHTOBWA eeneitufi Apunfk iseneuuIl: (Dynemn J(pjjeTanAjjqeCHHA ~HonoTODUfi BOAliuli roay6ofi YPORUN 903H11 Card 2/5. SPHTP031M YqncTon Anan- Onepriin, cooner Temnepsyyp- V 5:L nonnBolsoro cliogn coem. c7syman wopo-, nownsoBon rva- COWHellfle Bug vu"pnz. C O 7, He ranhaoft lipir- Bilge nonocu V>&, c Bog nornolue- 1popecgeugoBt HaR Tnepiaro L i6epitoro emon. v Caen. MI e 2 3 4 5 110-012 1,65 749 655-i.-750 66-4-110 t,71 722 659-~-740 40-1-- 85 1,79 690 580-000 63-000 1,78 604 OW+-710 19-047 1,75 700 610-050 54-053, 2,05 603 510-i-605 60-+.154 2.30 536 520-1-590 64-+-161 2,22 566 530-1--600  S/048/61/025/003/044/047 Comparison of the thermal ... B104/B203 Legend to Fig..1: Temperature dependence of electrical conductivity of solid layers. (1) (Upper axis of abscissas) benzophenonel (2) anthranilio aoid, (3) phenyl anthranilic acid, (4) 3-aoetyl- amino-N-methyl phthalimide, (5) 3-acetylamino- N-phenyl phthalimide, ~6~ 3-benzoyl-amino- N-methyl phthalimide, 7 fluorescein, -(8) uranine, (9),phosphine,.(10) indigotin, J11) soluble blue. -za t. Y P-135 35 17 JP J9 10' IT .1 f 7 7 .17- MO. fie, '80 49 , 2S 26 27 18 IS 30 JI 3219417  20854 S/048/61/025/003/044/047 Comparison of the thermal... B104/B203 ,Legend to Table 1: (1) Compound, (2) temperature range, (3) L T in ev, WA corresponding t 'o ST in m~, (5) spbetral part in which the.longwave d:~bp of the absorption curve for the solid layer occurs, (6) energy corresponding to the shortwave edge of the phosphorescent band, in ev. Compounds in Column I from top to bottom: malachite green, bright green, fuchsine, crystalline violet$ soluble blue, uranine, eosin, erythrosine, phloxine', Bengal green, rhodamine B, colorless product of rhodamine B, rhodamine 6G, fluorescein, phenosafranine, tripaflavine, phosphine, capri blue, File blue, thionine, indigotin, pinacyanol, Ortbichrome T, phthalo- cyanine without metal, copper phthalocyanine, zinc phthalocyanine, benzophenone, anthranilic acid, phenyl anthranilic acid, 3-acetyl-N- phenyl phthalimide, 3-acetylamino-E-methyl phthalimide, 3-methoxy-N- methyl phthalimide, 3-hydroxy-N-methyl phthalimide, 4-amino phthalimide, 4 amino-N-cyclohexyl phthalimide. Card 4/5  S/04 8/61/025/ 003/044/047 Comparison of the thermal ... 1 4 B203 pnoitcxit GN-160 2,07 ?, 5 7 530-+-C,00 13enram-cunfi pwovufs 52-~-153 2,05 603 560-i-MO 52-f-100 210 588 578-1-630 rDecuBeTnu Sri UPDOJAXYVI(iT POOMI lilt a B 1004-155 3:70 334 W-050 PoAamnn 6 G 53-+-106 2,07 597 555-+-620 Mayopecrteun 51 -t-- 103 2,44 506 4!)0-+-530 (DeHocnippanim &1-1-431 2,08 595 570-~-620 T" 8"'a"u" 58-t-100 2.3 536 1111 0 55-f-100 2.26 546 I j68--l-550 0 Han u pt ennu 18-1- 70 1,67 740 700-f.-780 11,;l o r nydon jo-~-100 1,63 758 680-080 Tuounu 115-1-118 1,83 675 650-000 IWAuro 40-1-110 1,75 705 660-t-720 35-t- 87 1,00 650 (M-t--720 OpToxpou T 40-!- 80 2,05 603 584-f-640 (D~ranozxitauwr 6es ueTajlAa 60-!-163 1-,7 725 688-t-790 (Dranounaunn weAu 88-!-158 1,7 725 685-i--780 (Dunortirannu gnuxa log-f-I&O 1,7 725 714-f-810 Belmcl~.euoll -23-1- 14 3,34 370 331)--!-'00 2,8[61 Awrpauunoilaji Hucatlia 62-1- 86 3,38 306 342-i-400 218 OcunnauTpanvironair imcnara .87-+-119 67 100 .3,30 46 3 375 357 375-t j30 3 -P390 50 2,7 -2 9 -1- , , HultA 54-1-124 3,50 353 340-1-400 2,7 3.6cii3ounamuno-N-merii;itpTan- IMIIA 84-1. 112 3,28 377 300-f-410 2,8 3.m(yrai(eii-N-stoilin(ildnittl[IA 54+ 78 3,18 388 335-000 Card 5/5 00+- 01 3,8 325 350-000 123-i-15t 2,78 444 410+5JO ' HIIHA .7a+J00 ., . 2,90 420 375-t-440  iARTANYAN, A.T. (Leningrad) Reversible bleaching of solid layers of tripheny1methane dyes in hydrazine vapors. Zhur.fiz.khim. 35 no.10:2241-2248 0 '61. (MIRA 14:11) (Methane) (Dyes and dyeing) (Hydrazine)  AUTHOR: TITLE: 3 '16"' S/058/62/000/()04/06Z/1 60 A058/A1O1 Karpovich, 1. A., Vartanyan, A. T. Concerning "valve" photo-emf in dye phototubes PERIODICAL: Referativnyy zhurnal, Fizika, no. 4, 1962, 23, abstract IIG189 (V sb. "Potoelektr. I optich. yavleniya v poluprovodnikakh". Kiev, AN USSR, 1959, 290-300) TEXT: The authors give the results of Investigating phototubes in air. Under longitudinal illumination in air, one of the dye-layer contacts with the electrodes is seen to give rise to a photo-emf, the sign and magnitude of which are determined by the nature of the dye but which does not depend on the nazure of the illuminated contact (push or natural contact). The photo-emf (Eoo)-and short-circuiting current (I ) are assiciated with illumination intensity by the relations E-- A 1n (1 + 1Z and Io - UP. Photosensitivity is observed in the natural-absorption region of the dyes in the solid state. The rectifying proper- ties of dye phototubes are caused by the presence of a barrier layer on the metal- dye push contact, In contrast to Noddak and Meyer, the present authors found that the appearance of photo-emf is not associated with the presence of a Card 1/2  S/058/62;/OW/CO 4/062/16 0 concerning "valve" photo-emf in dye phototubes A058/Aioi barrier layer. They advance arguments in favour of the phbtoelectrochemical nature of the non-valve photo-emf that arises incident to the illumination in air of metal-dye contacts.* [Abstracter's note: Complete translation) Card 2/2  _VARTANYAJI A.T. (Dsningrad) ~j ~~ Reversible discoloratIon of BoLld layers of x-cmthene dyss 1',-: hydrazine vapors. Zhur. fiz. khim. 36 nr,.9:1890-1896 S 162. (MIRA 17tO  VARTANYAN, A.T. (Leningrad) Spectral study of the reaction of neutral groups and hydrazine. Zhur.fiz.khim. )6 dyes with phenol hydroxy no.10.-2118-2125 0 162. (MIRA 17:4)  37380 S/02 62/143/006/009/024 J)-7, 0 0 B 1 63YI3102 AUTHOR: Vartanyan, A. T. z TITLE: Semiconductor properties of blood pigments PERIODICAL; Akademiya nauk SSSR. Doklady, v. 143, no. 6, 1962, 1317-1320 TEXT: The electrical conductivity and the spectral photoelectric sensitivity of layers of blood pigments such as haematine,.heamine, and haematoporphyrine were measured. The layers were prepared between platinum electrodes on a quartz substrate and thoroughly outgassed, haemine and haematine at a temperature of 140'C, haematoporphyrine at 1000C. The currents were measured with a 3MY-3 (alU-3) d-c amplifier with- a set of input resistors up to 6.8-109 ohms. after the layers had been. kept in the dark for a lonG period. In the photoelectric measurements the direction of the illumination was perpendicular to the direction of the electric field. Monochromatic light was supplied from a H(-TT-17A (ISP-17A) mirror monochromator. For the determination of the optical activation energy of photodonductivity a C-0-16 (SI-16) incandescent tungsten lamp calibrated from the brightness temperature for 656 m1c was used. The Card 149 j 7  S/02 62/143/006/009/024 Semiconductor properties of... B163YB102 light intensity was controlled by means of blackened metallic Exids, The dark current and photo-currents were found to follow Ohm's law up to field strengths of 104 v/cm. In the investigated temperature intervals (haematine 52 to 1550c, haemine 35-1400C, haematoporphyrine 35-1000C) the conductivity a followed the law 6 - a.exp(-1T/2kT) The values LT of the activation energy measured in vacuum (haematine 2.03 ev, haemine 1.85 ev, haematoporphyrine 2.07 ev) agree well with values from absorption spectra. The corresponding wave lengths (609, 0667, 597 mm resp.) belong to parts of the absorption spectra corresponding to sinElet-singlet transitions. `Uhen haematoporphyrine is heated to 1350C, it is converted to protoporphyrine (activation energy 1.83 ev). The activation energy of haematine is considerably lower than that of haemoglobine (2.66 ev) which is thought to be determined mainly by its -rotein content. In presence of oxygen (cf. Fig. 1)t the conductivity- temperature-curve of haematine shows a peculiar form: Above 1100C oxygen has no effect, but at lower temperatures the conductivity is considerably Card 2/4  Semiconductor properties of... S/02 62/143/006/009/024 B1053Y3102 enhanced by oxygen adsorption. The dependence of tho photo-current i phot on the illumination intensity L was found to be of the form i ' aLn with phot n near to 1. For haematoporphyrine and haemine the temperature dependence follows the law i i-exp(-6 AT) at 5-800C with phot 0 phot phot ~ 0.2 and 0.18 ev resp. For haematine, log i phot was not a linear function of T_ 1 except between -30 and +300C where L phot ~ P.1 ev. The spectral photoelectric sensitivity curves of haematoporphyrin and haemine are similar to the optical absorption curves. From the experimental results it is concluded that in-vacuum the investigated blood pigments are intrinsic semiconductors. There are 1 table and 2 figures. PRESENTED: November 17, 41961, by A. N. Terenin, Academician SUBMITTED: November 10, 1961 Card 3/4  AUTHOR: "'S/0'a 63/027 '0", '01, '043 B TITLE: Spectroscopic investigation of the interaction of dyes with hydrazine PERIODICAL: Akademiya nauk SSSR. Izvestiya. Seriya fizicheskaya, v. 270 no. 1, 1963, 37-41 TEXT: Liyers of dyes are decolorized by reaction with hydrazine vapor at room te 'mperature. There is evidence for a specific interaction, different from the formation of a true leuco-base. If t-he hydrazine is pumped out and the layer is heated to 600, or it the decolorized layer is exposed to air, the original dye is quickly regenerated. This cycle can be repeated many times. Unlike true'leuco-~ase's the undyed products are in most' cases unstable intermolecular compounds, called quasi-leuco-bases.. The spectra of astraphloxin, aurin, hemine and hematine are shown in figures together with those of their quasi-leuco-bases and the regenera- U tion products. The absorption spectra of the solid layers of colorless compounds obtained from diphen lmethane and triphenylmethane dyes are y Card 1/3  S/048/63/027/001/016/043 .Spectroscopic investigation of, the B163/B100 similar to those of the leuco-base layers. They consist of two bands whose maxima are bet%een 250-270 and 290-310 mg, respectively, depending on the state of substitution in the end amino group. The spectra of the 4- quasi-leuco-bases of rhodamine group dyes consist of three bands*at about 232-238, 265-276 and 302-317 mA,, respectively. Some of the rhodamines can also be reversibly decolorized by vacuum heating or the action of "X" gaseous 11 2S at room temperator.e. The bands of aurfn (268 nm) and its quasi-leuco-base (281 nm) are close to those of phenol (270 nm) and the phenolate ion (282 nm). In the interaction of hydrazine with aurin fiuoreacin, and gallein, a reversible bathochronic shift is observed if the hydrazine vapor pressure is low. Considering the ease with wh-4ch a .number of dyes change and lose their color, one must assume that in the .Anteraction with hydrazine the p'roton is only-partially drawn off by the !hydrazine, or the electron is only partially attracted by the dye, just enough for charge-redistribution in the electron shell of the dye molecule which is characterisAic for an anion, i.e. a molecule wh1ch has lost a proton, and for a reduc,ed dye, i.e. a molecule which has accepted an electron. This paper was presented at the 14th Conference on Spectroscopy Ca~d 2/3 A  3/020//63/149 03/010/028 B102/B186 AUTHOR: Vartanyan, A. T. TITLE: ~SVca`tral distritutio~n of photoconductivity of chlorophyll,& in relation to the layer 13M. t - PERIODICAL: Akademiya nauk SSSR. Doklady, v. 149, no. 3, 963 563-566 icheskiy TEXT: Pure and homogeneous chlorophyll a, obtained from the Bo , i nstitut AN SSSR - (Botanical institute AS USSR) was'precipitated om a chloroform solution into the 0.5 mm gap between Pt electrodes i quartz 'a mpule. The layer thickness varied between several tens and zi-.r al hund in ueds of g. The spectra were investigated at room 1TM?373 both vacuo (10-5mm Hg) and in an oxygen atmosphere. For current rement an 3M9 -3 EMU-3) d-c amplifier was used with a sensitivity of -14 12 1-5-10 a with maximum resistance (68-10 ohm) . For M. YMMM g the spectral distribution a mirror monochromator (0-4-0-69) of type (,IT -17A (ISP-17A) was used. A 100-w incandescent lamp was the light :z-ii e. As Card-1/2.. 8, L  3/020/63/149/003/010/028 Spectral distribution of B102/B186 ''in a great many previous publications, it was again oboerved that there is a tight correlation between the spectra of photoelectric sensitivity of the deposited layers of chlorophyll and the optical absorption spectra of the Pigment solutions. In all cases the bands were very broad. For the layer the 673-mg band had a width of 850 am- for the solution this maximum is ~at 662 mg and has a width of 650.cm-1. The shift of the red maximum amounts to 250 am-1. The presence of dry oxygen (250 mm Hg) in the ampule raised the conductivity; the dark current remained weak. Illumination of the absorption band with monochromatic light raised the conductivity by a -factor of 101_102. Stationary photocurrent was reached after less than' drop took 10-15 sea- these times are much shorter than those 4 sec, the observed by Nelson (i.Chem.Phys�27,864,1957). The absorption spectrum.of the layer proves to be red-Aifted with respect to that of the solution. The absorption spectra compared for two layer thicknesses show a oonsider-, able difference: whereas the blue bands correspond, this is not the case for the red bands; there is a shift so that the thin layer has an absorp- tion peak where the thick one haa a minimum. There is 1 figure. PRESENTED: October 6, 1962, by A.N. Terenin, Academician SUBMIT-TED: -September 26,A962- -2/ 2- Ard C  S102 63/149/004/009/025 B104YB186 ~.AUTHOR s, Vartanyan, A. T. TITLEt- The activation energy of the dark conductivity and the photoconductivity of chlorophyll a PER10DICAL: Akademiya nauk SSSR. Doklady, v. 149, no- 4, 1963s 812 - 815 TEXT: Amorphous layers of pure chlorophyll a obtained by precipitation from concentrated pigment solutions were investigated in high vacuo and in oxygen at temperatures not exceeding 700C. Detailed descriptions of the experiments are eiven in a previous paper (DA110 1490 no. 3 (1963)). The ff., of the photoconductivity was determined by measuring the photocurrent set~up~in a layer by irradiating it with a CVI -16 (SI-16) lamp at various tungsten band temperatures (1200-22000C). Between 2200 and 16000C the nonlinearity index nT varies from 0-72 to 0-76, and.betwoon 1600 and 12000 C n varies from 0-76 to 1.01. The thermal T i Card 1/2  S/020/63/149/004/009/025 'The activation energy of the ... B104/B186 activation energy C of the electric conductivity determined from T Llemperature dependence of.electric conductivity is 1.74 ev. In an oxygen atmosphere 6T is 1.63 ev and the conductivity is ten times greater than in vacuo. The activation energy ~_ ph of the photo- conductivity is 0.1c ev. As with other organic ph.otoconductore t is ph smaller than I-:Tby one order of magnitude. The hyperbolic decay of photoconductivity after illumination is taken to imply a bimolecular B.cheme of carrier. decrease: jdi/dt _ _Y2, . There are 3 figures. PRESENTED: October 20, 1962, by A.,N. Terenin, Academician SUBMITTED: October 16, 1962~ .-,-Card .2/2  VARTANYAN, A.T. Photosemiconducting properties of meth7lah2oropbyllid-9 a. Dokl. AN SSSR 153 no.1:70-73 N f63. .(MIRA 17:1) 1. Predstavleno akademikom A.N. Terenlnym.  VARTANYAN, A.T. Spectral study of the interaction between solid layers of porphine dyes and hydrazine vapors. Dokl. AN SM 155 no.6:1394-1397 Ap 164. (MIRA l7s4) 1. Predistavleno akademikom A.N.Tereninym.  VARTMAN, A.T. Activation of the electric conductivity of dyes by hydrazlne -!apors. Dokl. AN SSSR 160 no.3:638-641 Ja 165. (MIRA 18:3) 1. Submitted July 24, 1964.  VA-"-jj'.IYEV, 2t,li4ent, LIS Morphology and optical propartll-:~,-, of phenocrys' from ort.hophyreo of thr. :.!(~an geol. i razv. 05. (MIRA 18:3) 8 no.-,t58-64 ju 1 1 1. ~bskovskiy genlogorazvecinchnyy -inatit.ut J..m. S.C)rdzhonikidze.  I ~, I 'I". . 1. 1* , ! .," . ,1,,-; r i , t, 1, . t , , . , ., , , ~ ~ .! 1 " r; ~! ; L. !~: a ~ ~. ; ~_ 7 , _ ":! , 1-3 z !-,7n f -,r r-I - i. f."n i " --(IT.?; -6 ~r.-- i ri.- I r,.71-:-.. F-L~M,. i oer, f.rv~, r-,3: I1 .1 1 - - I -, J,1__S 165. (,"41PA 18.))  V.ASIL'YEV, A.V. __ - for communication workers published in 1961. Vest. sviazi 21 no.1:28-29 Ja 161. WRA 15:5) 1. Nachallnik Gosudarstvennogo izdatel'stva literatury po voprosam svyazi i radio. (Telecommunication-Bibliography)  112-57-8-16144D Translation from: Referativnyy zhurnal, Elektrotekhnika, 1957, Nr 8, p 1Z (USSR) AUTHOR; Vamil'yev, A. V. ---------- TITLE: Investigation of Some Semiconductor Alloys for Thermocouples (Issledovaniye nekotorykh poluprovodnikovykh splavov dlya termoelementov) ABSTRACT: Bibliographic entry on the author's dissertation for the degree of Candidate of Technical Sciences, presented to Khar'kovsk. politekhn. in-t (The Khar'kov Polytechnic Institute), Khar'kov, 1955. ASSOCIATION: Khar1kovsk. politekhn. in-t (The Khar1kov Polytechnic Institute) Card I 11  VASILtYRV, A.V- ... ~ -.1---l. . - - --l''. Books for commnications men. Yest.sviazi 19 no.2:33-34 7 '59- (MIRA 12:3) 1. Nacbal'nlk-,Svyaz-'izdata. - (Bibliograpby-Telecommunication)  VILICHKIN, I.H., kand.tekhn. nauk; AKOPTANq SvIvj Icand. tokhngnauk, otv.red.; GOSTXV, B.I., kand.tokhn.nauk, zam.otv.red; VASI kand. tekhn.nauk, red.; KRISTI, MA., profqq red.; OVOT, Te.D., prof., re4; MAL&MKIN. O.M., kand.tekhn.nlnk; XUDUU IN, N.G., lnzh.,- UVARffA. A.?., tekhn.red. Dome characteristics of the performance of gas-producer engines] Nekotorys osobennosti rabochago protsessa gazogeneratoinykh dvigatelel Koskva, Goo, nauchno-tekhn itd-vo mashinostroit. litry, 1958. 37 P. (Moscow. Gosudaretvennyi soiuznyi nauchno-iseledovatellskii traktornyi inotitut [Trudy], no.16) (MIRA 12:3) (Gas and oil enginee-Testing)  ORAZMETOV, Z.; GORELKIN, L.M.; POTTAYEV, M.Te.; ZARUDI, Te.O., metodist; MITENEV, V.S.; l~ASI~,jjqj..,A.V.;,GORSHEIWOV, N.G.; RMOVSKIT, 0.0.; LMSTA~i '~i, T.Sh. Letters to the editors. Gong. v sbkole 22 no.2:72-76 Mr -Ap 15 9. (MIRL 12:6) 1. 1-ya shkola pos. Andreynvka Turkmenskoy SSR (for Orazmetov). 2. Shkola pri shakhte No.11 Karachayevskogo rayons, Stavropol'- skogo krays, (for Gorelkin). 3. AnAreyevskaya semiletnVaya shkola Penzenakoy oblastl (for Potyayev). 4. Bashkirskly institut usoversheantvovanlya uchiteley (for Zarudi). 5. Rayonnyy pedagogiche- skiy kabinot s.Kich-Gorodok Vologodsl:o3r oblastl (for Hitenev). 6. Alol-neyovskaya shkola Stalingmdsl:oy oblasti (for Vasillyev). 7. Takhromskayra shkola No.2 Moskovskcy oblaati (for Gorshenkov). 8. 4-ya shkola g.Alma-Ata (for Rutkovskiy). 9. 64-ya shkola g.Alma-Ata (for KusyapkuloVa). (Geography-Study Pnd teaching)  VASILI'YEV9A.V.; SEMENOV, A.S. Nagnetic susceptibility of soUs. Uch. zap. IM no.286:11CL- 113 '60. (MIRA 14:3) (Tlranabaikalia--Soils-44agnetic pr:)perties)  BASHKATOV, D.N.; Y~ ~ILIYE~V A.V.1 ROIRANOV) V.G. Studying the vibration drilling method for purposoo of engineering geology. Rawad. i okh. nedr 27 no.5:25-28 My 61. (MIRA 14:9) 1. Vsesoyuznyy nauchno-isaledoliatellskiy institut gidrogeologii i inzhenernoy geologii. (Boring machinery) (Vibratora) /(Engineering geology)  ABRAMOT, B.A., kand.istor.neuk; KRUGLIKOY, N.Y., kand.istor.nauk; ROZENSHTM, A.L., kand.istor.nauk; TASILIYEY A.Y., nauchnyy red.; VCROBIT--Y, G.S., red.izd-va; G~~ tekhn. red. tBrigades of communist labor] Brigady kommnnistichaskogo truda. Leningrad. Ob-vo po rasprostraraniiu polit. i nauchnykh znanii RSFSR, Leningr.otd-nie, 1959. 46 p. (MIRA 13:2) (Socialist competition) (Efficiency, Industrial)  inzhener, Reconstructing the inclined vault of a boiler model TP-230-2. Ilek.sta. 24 no.4:5-7 Ap 153. MRA 6:5 ) (Steam boilers)  -VASILtYEVj-A--i-V-i --- - - --- ---- "Handbook on Analysis of Fuel Gases," State Publishing house for E'nergetics, Moscow-Leningrad, 1954. ~Z30( The book describes the most widely utilized types of gas-analysers manufactured by Soviet industry. It gives a description of their structure abd gives the methods of utilizing them. It also- studies the methods of utilizing the results obtained by these apparatuses. Translation of T~ABCON and summary of context. D 310099, 9-Sep 55  --J-  VASIL'YEVp A. V. VASILIYU1, A. V.: "Investigation of certain intermediate alloys for termal elements.* Khar1kov Poivtechnic Inst imeni. V. I. Lenin. Kharlkov, 1956. (DISSERTATION FOR THE DEGREE OF CANDIDATE IN TECHNICAL SCIENCE). So.: Knizhnaya 14topiall NO* 15P Moscow  133-2-4/19 AUTHORS:Borodin, V.P., Darmanyan, P.E., Yudson, A.A. and Vasillyev, A.V,_(Engineers) TITLE: A Four-Period System of the Complex Automatic Control of Thermal Conditions of a Fuel-Oil Fired Open Hearth Furnace (Chetyrekhperiodnaya skhema svyazannogo avtoregulirovaniya teplovogo rezhima mazutnoy martenovskoy pechi) PERIODICAL: Stall, 1958'~Nr 2 pp 114-120 (USSR) 2 A I ABSTRACT: A scheme of automatic control of thermal conditions of oil-fired open hearth furnaces developed by the Central Laboratory of Automation and installed on the Nr 10 furnace of the above works is described. The scheme-~o.,Qarates accord- ing to four programmes corresponding to four technological periods of the smelting process. Programme 1 includes a considerable part of the charging period and two thirds of the melting period; it is switched on by a motor relay of time, operated by photorelay during the tapping of steel. Programme 2 includes the remaining part of the smelting period; it is switched on by a motor relay of time operated when a stable excess in the preset roof temperature is attained. Programme 3 includes the refining period and is switched on by a motor relay of time operated at the moment Card 1/2 of tapping slag. FlEogramme 4 includes the fettling period  133-2-4/19 A Four-Period System of the Complex Automatic Control of Thermal Conditions of a Fuel-Oil Fired Open Hearth Ftirnace. and the beginning of the charging period of the next heat. Changing of programmes can also be hand operated. The scheme is shown in Fig.l. Fuel consumption is controlled according to the timperatures of the roof and regenerators, The following parameters are controlled: consumption of fuel oill air-fuel ratio, amount of compressed air used in the atomiser, pressure of gases in the furnace, reverses, waste gas temperature at the bottom of the regenerators and draught in the waste gas flue. Characteristic data on the furnace on which the scheme was operated, operating prac- tice and operating results are briefly described. The scheme operated satisfactorily, but the final conclusion regarding the efficiency of the scheme can be made only after an analysis of operating results of a few furnace campaigns. There are 9 figures. ASSOCIATION: "Krasniy Oktyabr" Works and TsLA (Zavod "Krasnyy Oktyabr''I i TsLA) AVAILABLE: Library of Congress. Card 2/2