SCIENTIFIC ABSTRACT MOSKVICHEVA, V. N. - MOSKVIN, B. M.
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CIA-RDP86-00513R001135330010-4
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S
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100
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Publication Date:
December 31, 1967
Content Type:
SCIENTIFIC ABSTRACT
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Body:
S/207/63/000/001/027/028
2202/z420.
PTHORS:.' Zhinkina, V,B#, Malonkov, I.G., Moskvicheva, V.N,.
(Novosibirsk, Leningrad),
TITLE: The effect of geometrical characteristics of perforated
plate on the entrainment of heavy component during
bubbling
PERIODICAL; Zhurnal'prikladi2oy makhaniki i tekhniche6koy fiziki,
no.1, 1963, 155-157
TEXT. An investigation of the effect of velocity and conditions
of entry of the light component on the removal of the heavy
component, particularly in the-supercritical region. Experiments
were carried out usin5 a rectangular transparent column 2000 mm.
high and 200 x: 200 mm4 cross section. The light component was
introduced into the layer through interchangeable perforated
plates with different geometrical parameters.. The diameters of
the openings d, were 2,3,5'and,8 mm and thei-open cross section
area of the plate (p were 2,3,4.5,5,8 and'12.5%. All the
experiments were carried out on the water-mercury"system with a
given height of the layer h' 72 mm. Mercury concentration in.
Card 1/3
S/207/63/000/001/027/028
The effect of geometrical E202/E,420
water was determined chemically since the mechanical separation of
mercury was thought not sufficiently accurate. The samples were
taken during a steady reduced velocity of the lighter component
reached in a steady supercritical condition,of bubblingo It was
fouad that the geoihetric characteristics af.the perforated plate
has a very complex effect on the entrainment of the heavy
component. The curve relating the relative entrainment w to
the relative open cross section of the perforated plate y had
at w.= 0.06 m/sec a well defined minimum at (pmin
The main difference of the two component streams in the suberitical
and supercritical regions lies in the difference of structure of
the bubbled layer. In the subcritical flow this layer comprises
a stable turbulent mass of the heavier component with separate
droplets of the light component. In the supercritical region of
flow the roverse is true. The change of structure takes place
when. the critical value,of the light component velocity is reached.
Three types of ertrainment were obso*rved* 1) foam entrainment,
characteristics for low velocities.and small separating volumes;
2) "dust" entrainment and entrainment of very fine droplets for
Card 2/3
The Offect Of go ometrical ... S/207/63/000/ool/027/028
E202/E420
which the ve'lOcitY Of fall of the'drOplets'does not exceed the
velocity of the entering streams.and 3) splash entrainment which
takes place as a result of mechanical breaking of droplets of a
larga size which Is observed in separators the height of which is
smaller than the height of splash of'the droplets The second
mode of entrainment was most effective. It was ;lso found that
at low values of y the light component enters the layer wIth-
relatively high velocity, the number of 'centers of entry being
distributed along the surface of the perforated plat6. The flow
of such streams takes place without-noticeable interaction and
displaced droplets of mercury fall freely in the space between
-these streams. Strong water streams-penetrated the layer,
forming in it separate channels'through which passed a continuous
flow of water. There are 4 figures.
SUBMITTED:, September 15, 1962
Card 3/3@
ACC NRj AT6021839 SOURCE CODE: UR/0000/65/000/000/0110/01241
AUTHOR: @utaleladze, S.-S.; Leontlyev, A. I.; Mamontovs, N._N,;
iMoskvicheva, V. N.; Shtokolcv, L. S.
ORG: Institute of ThormoRhi'sics. SibeEjan BEPnch AX.3_5S
I
tepl-oflilki SO AN SSSR)
TITLE:'.,,HZdrod@M&mio theory of the heat transfer crisis in
of a builing liquId. The crisis ot big@ flow ratos and 9
@content G-the flow
(Inatitut
forcod flow
zero vapor
SOURCE: Teplo- I massoperenos. t. III: Teplo- I m9asoporenos pri
fazovykh prevrashchenlyakh (Heat and mass transfer. v. 3: Heat and mans
transfer in phase transformations). Minsk, Nauka I tokhnika, 1965, 1
118-124
TOPIC TAGS: boiling, beat transfer, hydrodynamic theory
ABSTRACT: From the theory of the limiting friction laws in the
turbulent boondary layer It followu that when the Re7nolds number
approaches Infinity, the critical ln@ection In a homogeneou3 flow
equal to /1-P = 2c,,VW,-
Card 112
Is
L 408-31-66
ACC N'- AT6021839
le assume that the amount of llry,ld oJected from th() 'Lloundary 1'37,)r
,egion In the moment of crisis is
i, - 2 cl. y'W, (I - T,), (2)
there is the volumetric vopor content of the boundnr7 layer rovlor,,
nd the enarg-y required for th13 njoction comes from the lois of kinetIc
nergy from the vapor st ream, that is
j! = --!!!Iq V'. (3)
y T. f Y"
Then q- =2cj0T.(1 -(p.)r;l Y, N"
"a
On the above basis, the article con.91dars mathomptically the affect of
underheating of the core of the flow up to the saturation temperature,
and the effect of the vapor content of the flow. Orig. art. has: 19
formulas and 3 figures.
SUB CODE: 201 SUBM DATE: Moo65/ ORIG REF: 016/ OTH REF: 009
KUqATELADZE, S.S.; LEOI;'I'YEV, A.I.; RUMSOV, N.A.; GOLTSHTIK,
-U
V.A. ; VOI CHKOV, E. F.; DAVvDCVA, V. ; Dil MIND7, S.A.
KIRIUOVA, N.N.; I-ALI,7 'Ll"OSKVICiEW., V.N.;
MIROIIOVY B.P.; V.UKHIN, V.A.; !-TKHINA, N.V.; C-EROV, A.r.;
FEDOROV, V.K.; KHABAKHPASHEVA, Ye.l-',.; SHTOKCLOV, L.S.;
SHFAKOVSKAYA, L.I., red.
(Heat and mass transfer and friction in a turbulent
boundary layer] Teplomassoobmon i trenie v turbulentnorr,
pogranichnom oloe. Rod.-izd. otdcl Sibir-
skogo otd-niia At! SSSR, 1964. '1106 p. (1-1,1RA 18: 1)
I-10s"'IrICIFL-VAO V. V.
UW/Telephme TorninaU an 1946
Telephones - Parfoi@nance
"Organization of Exploitation at International
Telephone Stations," V. V. HookvIcheva, 11 pp
"Yeatnik SVaz1 - Elaktro Svyazl* No 1 (70)
Telephone stations at Kraanodar, Ufa, Baku and
several others were given monetary prizes for
their excellent work. The article discusses some
of the methods used at such stations as Kiev,
Stalin., Krasnodaryand em2hasizes the affect of
close personal supervision by the head of the
stations.
19M
, *S SAKOMOTO D.A.; ATARASlyly, 0tv6t9tvGnW
KOSKVjcjMyA,_.yj
or, BILIKOW. B.S., radaktor; TSTRTUUB, L.B., tokhnichookly
redkator
(The long-distance telephone operator] Telefonietka machdugorodnot
telefonnot staatell. Mookwa. goo. ttd-vo lIt-ry po voprosam oviazi
I radio. 1951. 171 p. (Kicroftlal NLRA 7:10)
(Telephone-Operators' manuals)
;'V;
AID P - 5586
Subject USSR/Aeronautics - computers
Card 1/1 Pub. 135 - 25/27
Author Mosk,vin., A. I., Eng.-Col., Dr. of tech. scl.
Title Computers in aviation
Periodical Vest. vozd. flota, 6, 92-94, Je 1956
Abstract The author, on the basis of foreign literature,
describes the use of various, mostly electronic, com-
puters in aviation.
Institution None
Submitted No date
AUTHORS Getman A.D., Matorina N.N., Moskvin A
1 89-10-4/36
TITLE Detertkination of the Compos@iloi@-Wn@ n tability Constants of Pu*3
i
Oxalate Complexes.
(Opredeleniye sostava i konstant nestqrkosti oksalatnjkh kompleks-
nykh ionov Pu+3) - Russian).
PERIODICAL Atomnaya Energiya , 1957, Vol 5, Nr lo, pp 3o8 - 313 (U.a.S.R.)
ABSTRACT 04-8olution of
9H20 in MqueOu@
The solubility Of PU2(C204)
K2C
,
J
the most various concentrat ne /O,ol - 2.4 Ol/ / was measured
1,
at constant ionization of the solution and at a temperature of
2oOC. Forming of Pu+3 complexes was proved and the follow
- tng ion
complexes were formedt [Pu(C
' [PU (C204)3] - 5 and
04)2] LPIU(C204
T)
J
with the instability constan a, -
4,9-1o-10i 4,1o - lo@10 and 11.9.1o-11 respectively.
The solubility Of Pu2(C20 )3-9H20 in an aqueous (IFH4)2C204-solution
i
at an ammonium concentrat
on of O,OT -0,7 mol/i at a temperature of
7oO C was also measured.The following ion complexes with the in-
stability onstants were foundt
IN C204 2
1 . .............. 11,6.1o-9
LPU C204
@
@
3 -3 ....... 5,6.io-9
*
'
*
'
rpu
c 0
V- - 2 4
4@ -5::0
1
:
....... 2.5-10-9
1
There are figures, 3 tables and 7 Slavic references.
lu'91ffffl.
AVAI AJJL ftguar 1P,8
9RI
f
Card 1/1 ra r
ress.
0
GELIKAY. A.D.; MOSXVIN. A.I.
Spectrc4a6pic" -@tudiee of Pq 3 complex formation and stability.
Atom.energ, 3 no.10:3114w316 0 157. (MIRA 10:10)
(Plutonium compounds)
AUTHORS: Gellman, A. D., Matorina, N. N. and 20-1-23/42
Monkvin, A. 1.
TITLE: An Investigation of the Formation Conditions and of the
Stability of Complex Oxalate Compounds of Pu (III) in
Aqueous Solutions(Isaledovaniye usloviy obrazovaniya i
prochnosti. oksalatnykh kompleksnykh 3oyedinenly Pu (III)
v Yodnykh rastvorakh).
PERIODICAL: Doklady AN SSSR, 1957, Vol. 117, Nr 1, pp. 88-91 (USSR)
ABSTRACT: From other publications it is well known, that Pu (III)
shows much less preference for the formation of complexes.
The authors studied the stability of solutions of oxalate,
carbonate, citrate and ethylene-dianine-tetra-acetate
complex compounds of Pu (III) against oxydation by the
oxygen of the air by spectral photometric methods. It
appears, that Khindmen was correct with his assumption,
that complex formation cannot cause a noticeable modifi-
cation of the absorption spectrum of Pu (III). After the
authors having established the conditions of the above-
mentioned stability, they approached 'he problem of the
Card 1/4 determination of the composition and of the instability
An Investigation of the Formation Conditions and of the 20-1-23/42
Stability of Complex Oxalate Compounds of Pu (III) in
Aqueous Solutions
constant of the complex ions of PTJ (III) with various
complex constituents. Two methods were employed: a) the
method of solubility (at pH 8) and b) the method of ion-
exchange (at pH ~ 1'4 - 310). a) At first the solubility of
PU 2(0204 )3 - 9H20 in aqueous solutions of K 2C204 at 200C
and at a constant ion density of the solution was
determined. Pu (III) was protected against oxydation by a
nitrogen jet. The plutonium contents of the solution were
determined by radiometric measurements. The results are
given in table 1, from ffh1ch the composition and the general
instability constants (reference 6) of the oxalate complex
ions of Pu (III) were determined or computed, respectively.
In the range of concentration of K 2C 204 under investigation
complex ions are formed (more exactl a relation between
Pu (III) and the C 204-ion): /Pu C 204V_'1PU(C204)5 /I and
Card 2/4 /PU(C204)4/5-, the total concentration instability constants
An Investigation of the Formation Conditions and of the 20-1-23/42
Stability of Complex Oxalate Compounds of Pu (III) -.n
Aqueous Solutions
of which ("obahchiye kontsentratsionnyye konstanty -10
nestoykostill corresponding to 4,9. 10-10; 4,1. 10
and 1,2. 10-@b, are equal. The dependence of the concentra-
tion of the ions in question on the concentration of the
complex constituent is illustrated in figure 1.
In an analoguous way the solubility of Pu2(C204) 3' 9H20
in aqueous solutions of (NH 4)2C204in the range of concentration
of the ammonium oxalate from 0'07 to 0'7 Mol//l at 700C
was determined (table 1). In this process complex ions of the
same composition are formed, the total instability constants
of which for Pu 2(C204 )21-1 1,6.lo-9, for /Pu(C204)3/3-5,6. 10-9,
and for Pu+(C20 4)4 /5-2,5. 10-9 are equal. The heat of
formation of the complex ions in the case of the reaction
Pu 3+ + nc 011 /PU(C 0 ) /3- 2n (1)
2 4 2 4 n
Card 3/4 was also computed. It was found, that 410 equals 1300 Kcals
An Investigation of the Formation Conditions and of the 20-1-23/42
Stability of Complex Oxalate Compounds of Pu (III) in
Aqueous Solutions
for the /Pu(C 204)2" ion. The data on the complex formation
of Pu (III), obtained with C O'l-lons by means of the method
2 4
of solubility, were confirmed by the method of ion exchange.
Finally, the distribution of Pu (III) between the I molar
olution of NH 4Cl and of "cationite" KU-2 (reference 15) was
:
etermined with respect to the pH-value of the solution
(table 2). There are 2 figures, 2 tables, and 15 references,
6 of which are Slavic.
ASSOCIATION: Institute for Physical Chemistry All USSR (Institut
fizicheskoy khimii Akademii nauk SSSR)
PRESENTED: June 24, 1957, by I. I. Chernyayev, Academician
SUBMITTED; June 13, 1957
AVAILABLE: Library of Congress
Card 4/4
lonsv1IT' , A. T . , Gand ',her, -- f Iiss) 11"t@ljdy of %':(t
cninj lex "or-rnLion of tri ,jrjrj t(,tj-:jVjjvrj*@q pj,jtr)rjj jrj
wit,@i tne arions, of rert. i!i r-i(-.i - ir@ wiiwo i :;c) I . L i ( , :; . 11
Vos , P -it) 1@r, ise of' Auad '@ri @13 1@/ , 1'@Y- , Ili i,i, ( Acao
.,r i I n.; t o f - hY i c -i I xiden ut I (,.!" i ; _ r " ) 1 1 (-) r- n i # @ ,@
(K,L, @1-1- , I -L`)
- JH -
CUMISTRY P11D PHYSICAL GEM41STRY OF FEACTOR 14ATEPIAIS AIM PROCESSES
"Determination of the Composition and Dissociation Constant for Oxalate
Complexes for Pu 3 by the Ion-Exchange Method, " by A. D. celiman, N. N.
Matorina and A. I. Moskvin. Atomnaya Energin, No 1, January 1958, pp
52-56. 1----------
The method of ion exchange is used to study the oxalate complexes of
Pu3 in th pH Interval 1.4 to 3.0. It is established that in this pH
region, there are formed the complex ions CPU(C2q4)27 and
f7PU(HC204.)g , wholl instability constants are KI - 71 x 10-10
and V I - 1* 1. x 10- . The value of the instability constant of the
complex ion f-Pu(C204)2 _7 is in satisfactory agreement with the value
of the instability constant of the corresponding complexion, obtained
by the solubility method.
Bibliography of 15 titles.
30Vi37-59-12-27231
Translation from: Referativnyy zhurnal, Metallurgiya, 1959, Nr 12, p 212 (USSR)
AUTHORS: Likhanhev, V.A., Moskvin, A.I.
TITLE: Changes in -the Dimensions of Aluminum Specimens Subjected to Cyclic
Temperature"@Action
PERIODICAL: Nauchno-tekhn. inform, buyl. Lentq @.ol in-t _l8, Nr 12
PP 56 - 69
ABSTRACT.- The authors Investigated basic regularities of irreversible changes in
the dimension and shape of Al (99.7% Al) subjected to a periodic tempe-
rature action. The authors investigated the dependence of these changes
on the number of thermal cycles, the heating and cooling rate, the tem-
perature range, preliminary plastic deformation, grain size, dimensions
and shape of the original specimen. The cyclic temperature action was
brought about by transferring the specimen from one temperature zone Into
another one. The time of transfer was two seconds. It was established 1_
that an increased number of cycles caused usually increased deformation"
of the specimen and that this augmentation was proportional to the number
Card 1/3 of cycles. A higher cooling rate furthered the increase in the coefficient
V/
SOV/137-59-12-27231
Changes in the Dimensions of Aluminum 3pecimens Subjected to C)rclic Temperature Action
of growth, equal to one cycle; however, higher heating rate raised the proneness to
contraction of the specimen. Ritised temperature ranges caused a noticeable increase
In the coefficient of grwoth. For annealed and rolled specimens the temperature
dependence of the coefficient of growth was different; this was particularly notice-
able within the range of temperature drop of 3000C. In preliminary deformation to
50% the coefficient of growth increased 4 times, compared to the initidl value (non-
deformed specimen). Annealing of the specimen after preliminary cyclic thermal action
entailed a considerable rise of the coefficient of growth. Different grain size caused
a difference in the coefficient of growth only under conditions of speeded-up heating
and slow cooling-off. Generally, deformation of large-diameter specimens was higher if
the InitW diameter changed during a given number of cycles, although such dependence
was rather complicated in a number of cases. During the tests the authors observed
intensive dislocation, migration of grain boundaries and sometimes crack formation. The
conclusion is drawn that irreversible changes in the shape are due to relaxation of
stresses arising during the heating and cooling process. These stresses may develop on
account of the temperature gradient along the cross section of the specimen, whose
Card 2/3
SOV1 37-59-12-272 1` i
Changes in the Dimensions of Aluminum Specimens Sub3ected to Cyclic Temperature Action
surface is at first rapidly heated up (in speeded-up heating) and then tends to expand,
Stresses may cause plastic deformations, and since the periphery is heated up more than
'the center, the specimen may turn out to be plastically compressed. In the case of
speeded-up cooling of the heated specimen, the effect of stresses is rever2ed and the
specimen may deform plastically In the direction of the expansion.
Yu.L.
Card 3/3
AUTHORSt llos?vin, A. 1. , Gel'Mall , A. D,
70-3-4-24/36
- -------------
TITLEs Invectigatian-df the Phy-gico-Chemical Properties of Aque@us
Solutions of Plutonium Oxalate (IV) arid the Determination of
'@heir jolubility Products (Isoledovaniye fiziko-khimiches1.i',.-h
avoystv vodnykh rastvorov okoalata plutoniya (IV) i opredole.-
niye yego proizvedeniya raetvorimooti)
PERIODICALt Zhurnal Neorganicheskoy Khimiipl958,VOI.3,llr 4,PP-956-961(USSR)
ABSTRACT: The solubility of plutonium-IV-oxalate in water and in the
acids H2so 49 HNO3 and HC10 4 was determined.
Based on the solubility of plutonium-IV-oxalate, the determi.
nation of the pH-valueand the electric conductivity of the
saturated aqueous solutions of Pu(C 0 ) .6 H 0 it was found
2,dL@,V_02
that the aqueous solutions of pluton zalate have aci-
dous properties. In the saturated aqueous solutio@ of 8
Pu(C20 4)2.6 H20 the hydrogen-ion concentration [H -3,96@10_
The dissociation constant of plutonium-IV-oxalate 2.7 10- 5.
The solubility of Pu(C20 )2 6 H20 decreases with the decrease
Card 1/2 of the pH-value of the s9luiion. With an increase of the acid
78-3-4-24/38
Investigation c;f the Physico-Chenical Properties of Aqueous Solutions of
Plutonium Oxalate(IV) and the Determination of Their Solubility Products
concentration the solubility increases under the formation
of complexes of %-IV with the anion of the correspondine
acid. For the determinatlon of the solubility product of
Pu(C 0 ) 6 H 20 a mixture of 11NO -(NH 4)2 C204was used, The
soluiiiiG product amounts to 4@;O-22.
This new method for the determination of the solu-
bility products of difficultly soluble precipitates in acids
is also used successfully in other systems, as for instance
with U(C 20 4)2 .6 1120' U02(C204 )'3 H20, and others. There
are 2 figures, 5 tables, and 12 references, all of which are
Soviet.
ASSOCIATION: Institut fizicheskoy khimii Akademii nauk SSSR
(Institute for Physical ChemistryAS USSR)
SUBMITTED: July 27, 1957
Card 2/2
70-3-4-2')/38
ATTTNOR5 1.1,os)-vin, A. 1. ,Gel'nan, A. D,
TITLEt Determination of the Composition and Instability Conatnnts of
Oxalate- and Carbonate Complexes of Plutonium-IV (Opredeleniye
sostava i konstant nestoykosti d,-salatnykh i karbonatnykh
kompleksov plutoniya (M)
PERIODICA.Lt Zhurnal Neorganicheakoy Khimii,1956,Vol.3, 11r 4,pp.962-97il
(USSR)
ABSTRACT: 2he solubility of Pu(c 20 )2 6 H20 in solutions of ammonium
oxalate of concentrationi of,from 0,001 - 0,35 mol/l in the
presence of 1 mol 11NO 3 were determined.
Based on the achieved results the composition of the com-
plexes as well as the stability of thl oxalate complexes of
Pu-IV were determined , For [Pu(C 2 0 + YH - 1,8.10 9;
0 -17 2- -24
for Epu(C204)2) . 1,2,10 , for @Pu (C204) 3j 4,0-10
for [PU(C204)4 ]4- . 3,2.10- 26.
The solubility of plutonium-N-hydroxide at constant ion-den-
Card 1/3 aity in aqueous solutions of K 2CO3 0,36-3,62 mol/l and at
78-3-4-25/38
Determination of the Composition and Instability Constants of Oxalate-
and Carbonate Complexes of Plutonium-IV
a temperature of 20 0C was determined. Also the solubility
of plutonium-IV-hydroxide in aqueous solutions of K 2CO3
of various concentrations without constant ion-density was
detem ined. It was found that with an increase of the con
centration of K 2CO the solubility of plutonium-IV-hydroxide
ircreases under tO formation of complexes of Pu-IV-cmbonate
The carbona compleL of plutonium-IV has the following
compositions rpu(CO 3)] with an instability constant of
-47
191.10
With carbonate complex solutions of plutonium-IV also the ad-
sorption spectrum was determined and the existence of the
carbonate complex was proved by that. The formation of plu-
tonium-IV-carbonate complexes proceeds stepwise. In solutions
there exist several plutonium-IV-carbonate solutions of
OA various compositions. The tendency of plutonium of other
valence to form complexes with oxaltion was also investigated
The tendency to complex formation of plutonium-has the fol-
lowing orders 4+ 3+ 3+ 2+ +
Card 2/3 PU > PU ;> FU ;;, NO2 ;;, Pu 02
78- 3-4-25/38
Determination of thL Composition and In3tability Constants of Oxalate- and
Carbonate Complexes of Plutonium-IV
The tendency Of Ilut3nium to form complexe3 with different
a,niona CO 2 , C 11'0 C41140 2- has probably the same
h 6 6
order aa ht oxaiales.
Based on the instability constant of plutonium-IV with so:.,ie
complex partners the tendency to form complexes of Pu-IV-iona
can be classified as followas
2- 4- 2-
CO3 75. C204
anion of ethylene-diamine tetraacetic acid.
There are 5 figures, 7 tables, and 14 references, 11 of which
are Soviet.
ASSOCIATIONs Institut fizicheskoy khimii Akademii nauk SSSR
(Institute for Physical Chemistry,AS USSR)
SUBMITTED% July 27, 1957
Card 3 /3
AUTHORS, GAW'mn. A.D., br-i.bkInA. L.Vi. , Moskvin, A.I. -,j/.78-3-7-14/44
------------------------
TITLE- ThA D tFiYiDia&',4on of thA C unposi tion and of the Inst a t,.' i ity
Constarit-4 fJ th:i 0.-zsla@i Complex Ions of Plutoni= (VI)
Fios-tant i kor.9tant. nestoykosti oksalatrykh
kotaplek.r.,yk-h lonov pbAcv-",.y& (V'M
PERIODICAL.- Zhurnal rporgunlchesk---@y k1rilini:1., 1958, Vol 3.. Nr 7, pp 1.1416-1550
(USSR)
ABSTRACT. In th-i pi.-aim.@ paper the reiul-ts obtained in conneotion vrith the
letarmination of the composi@ion and the inetnbility constnntc of
oxalate of PtD 22+ by the solubility of pluton-4-- (VI)
in '.r.-MO3 J.r, the Fv4!senc.e of ammonium oxalate are given.
Th-? dete@,rmirAdor of the Eolubility of plutonyl oxalate in nitric
&M.1 in th,@ piedeno-3 of amm-,lit-= oxalate ww carried out at 200 C,
an-i a -tralne r-X(3-.)",`O"-5 mo@Vl plu-tonyl amlate wa3 obtained.
SolubiLi-@y w1th an. inor-.ase of the ammonium oxalate
concent-7atic-P. b,?@@;auzie caVlt.-xes are formed. The solubility product
-io
Card 1/2 of Pao 3 f 120 10
Th,3 Detenuinatityn of @h--@ Compc;,i @ `Akon and of th+, Instabi_Uty 78-3-7-14/44
OonstamA3 of the C=p.`q-@ Ions @)f Plutonium (VI)
In o-.ralat.,@ of plutonium (VII the following complexes
e@.Jda,-- Pi.LO jo -D ani [FW?2(CP4)iJ" Theii instability con-
, 41
a ")" % 07 a-r-1 ..'L 4 - 310-12 respncti-e3y. There
&T-,i ffg-ay--, '.' j-abl@!, anl'5 references, 4 of which are So-det.
ASSOCIATICN.- lm4 tu @, A-1,7_ I kWmil, AkaAemii nauk SSSR ( I" ti vlt') of
Pbysirzd C_t_.emje@rv AS USSR)
SUBRITTED: 0 j- @, Cr @. -,., 3 1! 95. -1
1, Complex ions--Stability 2, Complex ions--rlutilty
3, kmmordum vxalata--Applications
Card 212
A RS l5ra j'- 1:.- , L e
I L ;,(A(,,r:An@itici. of ji-jr,-ct cf
1 jD I CA L: Zh u r ria I n e j r. - an i c k 1, i.@. i i 8 , 7 c I Nr
1936-
A331'IiACT The solabilil../ jru(iAtt vvi i dt--tf--r:@iinuu of 11 A (i i, I u 4 A @L 1,
2,0, 5,0,j mol. H.':O, un,: Thp
scluluilit,- )rcdict of .i
1 0. n c; -, c t r i
of 6,0.10- ',itli a, incre@iso o. tl@c ox -,;ic
the soILLbilitj 0 1' , I At (j li.; I o Xa I Ate @_,,are,-A@3@23
values of tl.@ ,rol.Act Z u x@-@ I - t- vi e r e -,IFn
dc-tt-rinine(. bj mear.:, of *L'@E: r i, I ",I! fro , @@,* ,, 1 J@,.
solabilitj of' I a t - [;, I f),( -11 1 t -1 i :(t! 'I A t
Hilo ("'ll ),c 0 T.-je @ (,,A - i t @.
4. 1 2 1 C)
fVA h i ca 1 :.1 @i C) s t "D 13 V V s .,c r. @.3
,luite icll to thf-- v-wlau fou.,.@ I T i t @ i e e x n i@% n Ij, r t?
-are 1 fi,,.Art-, 2 t a b I E-, s , a n c, r F. f c r v r, c s v f.
@ard '112 u
Lpter:.,ination of the Solubilit@, Procact of Plit@)nj I Uz-@l -t@
Soviet
ASSOCIATION: Institut fl@:icliesko,, khi-l i 'i': id.-@;,i 1' nauk 1%:@*, It't e of
Ph,y3iC,al Chcmi@,,trj , ASS USSL(
'Ej JB:@'ITT"D October 31,
Card 2/2
AUTHORS; Gellman, he D,, Matorina, N. !!., Loskvin, A, 1.
TITLE: The Determination of the mposition and the Instability Constant
of Oxalate Compleye3 of P@ Compounds by the Method of Ion Excflan'ge
(Opredeleniye sostava i konstant nestoykosti oksalatnykh komplekanykh
soyedinneniy Pu*3 metodom ionnogo obmena).
PERIODICAL! Atomnaya Energiya, 1958, Vol. 4, Nr 1. pp. 52 - 56 (USSR).
ABSTRACT,' By the method of ion exchange the formation of ion complexes of Pu*3
in oxalate solutions -was determined, and the ph value of the solus
tions was found to fluctuate between IA and 2,8. Measuring results:
1.) The instability constant of the complex ion Cpu(c 204)21- 'a
practically constant with in the range of the ph values from 1,47 to
2,65 (11 values).
2.) In a solution with pH> 1,7 s mixture of complex ions [Pu(C 4 02)21-
and rPu(HC 0 - developed, and the average instability constants
L-7 - 2 041 is -10
for these two types of ions were measured to be KIH . 7,1-10
and K" - 1,1. lo
H
Card 1/2 3.) The constants and Kg correspond to a total decay of the
The Determination of the Com osition and the Instability Constant 89-1-6/29
of Oxalate Complexes of Pu t Compounds by the Method of Ion Excrange.
ions in accordance w1th the form**
f'Plj (C 0 ) ' +3 + 2C 0
2 4 21 Pu 2 4
4)- pU +3 + WiC 0
r1'11(HC 04)
L 2 2 4
4.) Determination of KHfor the complex lon @PU(C204)2y by the men
thod of ton exchange supplies values which agree satisfactoriLy with
those obtained by the solubility method.
There are 4 figures, 2 tables, and 15 references, 12 of which are
Slavic.
SUBMITTED: August 15,, 1957.
AVAIIABLE: Library of Congress.
Card 2/2
LUTHORSe Gellman, A. D., Hoakvin, A. 1. 2o-3-21/.59
-----------
T ITLEt An Investi ation of the Complex Oxalates and Carbonates of
Plutonium @Ivl in Water Solutions by Ideans of the Solubility
Method (Isaledovaniye oksalatnjkh i karbonatnykh kompleksov
plutoniya (IV) v vodnykh rastvorakh metodom raetvorimosti).
PERIODICAL# Doklady AN SSSR, 1958, Vol- 116, Nr 3, pp. 493-496 (USSR)
ABSTRACTs go date can be found in publicalions concerning the com osition
and stability of the carbonates complex of plutonium (IV5. In
this work the authors give the determination of the composition
a well as of the instability constants of Pu (IV) as mention-
:
d in the title. 4-6 hours are sufficient to reach the equilibr-
ium between the ammonium-oxalate solution andithe solid phase of
Pu (IT) oxelate at 2o t o,o2O. The experimental results are nen-
tioned in table 1. The solubility of Pu (IV) oxalate decreases
with the increase of the concentration of aamonium-oxelate from
0,001 to 0,005 Rol/liter, it reaches a minimum of 3,55-jo-5 mol.
Pu(IV) per liter and then increases because of the complex for-
mation of Pu(IV) with oxalations. The solubility is expressed by
means of an equation (I). Complex ions with general instatUity
Card 1/3 constants (- I. C. in brackets) are formeds
Ln Inventi tion of the Complex Oxalates and Carbonates of 2o-3-21/59
Rut,onium Xv/ in Water Solutions by Means of the Solubility Method.
PU(C204)11 2* (1. C. _ l'S.10-9)1 [Pu (C204)21 0 (1. C. - 1,2.1o47)
Pu(C204)3 ]2- (1. C.- 4,o.10-24) and [Pu(C204)4@_ (I'C' -
313-10 -20 . These constants correspond to a complete decoupo.
eition of the ions of Pu(IV). From these general instability con-
stants the stepwise constants were determined. Both kinds of
constants correspond to different decomposition schemes (2) and
(3). Tmqble 2 gives the solubility of Pu(IV)-oxalate in water
and in H 304, HU03 and HC104' From this follows that the solubi-
lity, bu? that then, starting from 0,1 N , it increases again.
Because of their interaction with the oxalate in aqueous solu-
tions the acids form a series: H230@4 HIIO@HC104. The pH of a
saturated Pu(IV) oxalate solution wa equa to 4,4, the molecu-
lar electric conductivity 470!2-1. The dissociation process of
Pu(IV) oxalate is explained by means of a scheme for its analogy
with U44*. The estimated constant of the acid dissoziation of Pu(IV)
gave,'_-"'3.io-5. Furtheron the solubility of Pu(IV) oxalate in a
mixed solution HN03_(H*)2C204 (table 1), as well as of Pu(IV)
hydroxide in K2COj. with a constant ionic density with an ad-
Card 2/5 dition ofID1 and KC104 (table 3) are measured. From table 3 it
An Investi, ation of the Complex Oxalates and Carbonates of 2o-3-21/59
Plutonium @Iv/ in water Solutions by Means of the Solubility Method.
ASSOCIATIONs
PRESENTEDs
SUBMITTEDs
AVAILABLEt
Card 5/P3
can be seen that the solubility of the hydroxide increases with
the increasin 2CO3 concentration because of the complex forma-
tion of Pu(IV1 with Carbonate ions. The complex ion[P@(CO3 e+
has an instability coefficient of the concentration 1,1.1617.
Absorption spectra of the solutions of the latter complex were
investigated. Table 4 gives the calculated values of the ion
potential. From this is seen the tendency fQr complex formation
of single plutonium ionst pu4+ Pu,3+ -- Puoz+/ puol , which
2
decreases with the decreases ol@ the ion potlaLal. By means of
the data in table 5 the anions can be arranged in a series ac-
cording to their tendency for complex formation with Pu(IV)1
C023@CO 409>C6H50j_ '_'_ C2 02;There are 5 tables, 5 _w@ refer-
4
ences, 4 of which are Slavic.
Institute for FlWsical ChemIstry AN USSR (Institut fizicheskoy
khimii Akademii nauk SSSR).
August 15, 1957, by 1. 1. Chernyayev, Academician
August 1, 1957
Library of Congress
KAYOROV. ?odor Vasillyevich, prof.. doktor tekbn.nauk-, 110SUIR, A.I.,
doktor takhaonauk, lush.-polkovnik. red.; CA 1, Ta.Ke. red,
Isd-va; @@ ZIRKOTA, N.A., tekhn.red.
Elleotronio calculating machinas and thair umil Slektronnye
vychlelitallaye asshiny 1 Ikh primenenta. Nosima, Voen. icd-vo
N-va obor. SM, 1959. 234 p. (MIRA 12:6)
(Zleotronic ealculating machinas)
KOSKVIN. A. I.;_LHATRURIN, G.T.; GILIKAY, A.D.
Investigation of the complex formation of trivalAnt americtun
in oxalate and athylanadtantnatetraacatic acid solutions by
means of ton exchange. Radtokhtmita I no.2&141-146 159.
(KIRA 12.#8)
(Americium compounds)
KOSKVIV, A.I.; AKPMGOU. N.I.
State of microquantities of radioslaments In solutions. Part 13:
Study of the state of polonium in aqueous solutions by imeans of
ultrafiltration and adsorption on glass. Radiolchimiia I no.4:
425-429 159. (MIRA 1@-I)
(Polonium)
MOSKVIN. A.I.
Complex formation by plutonium and americium (III) in aqueous
solutions, studied b7 means of solubility and ion-exchange methods.
Radiokhimiia 1 no.4:430-434 159. (MIRA 13:1)
(Plutonium compounds) (Americium compounds)
5(4)
AUTHORS: Moskvin, A. I., Artyukhin, P. 1. SOV/78-4-3-17/34
TITLE: Determination of the Comnosition of the Stability Constant of
the Ethylene Diamino-tetraacetate Complex of Pu(ITI) by the
Ion Exchange 'Method (Opredelentye sostava i konstant nestoy-
kosti etilendiamintetrantootatnykh kompleksov Pu(ITT) metodom
ionnogo obmena)
PERIODICAL: Zhurnal neorganicheskoy khimii, l)59, Vol 4, Nr 3,
pp 591-595 (USSR)
ABSTRACT: The complex formation of plutonium (M) in ethylene diamino-
tetraacetic acid (EDTA) by ion exchange ras investigated at
constant concentration of Trilon-B and at various p H values.
Distribution coefficients were determined of Pu 3+ in serips
of 1-molar solution of NH Cl on KU-2 at p H 1.6-1.3. The
experimental data are givin by tableg 1 and 2 and figure
From the results it may be concluded that with an incrense
in the pif value the concentration of Pu 3+ in the solution
increases under formation of the ethylene diamino-tetraacetic
Card 1/4 acid complex. In the case of pH = 2.5 and above Pu 3+ appenrs
Determination of the Composition of the Stability SOV, /79-1-7-11/7,,4
Constant of the Ethylene Diamino-tetraacetate Complex of Pla(III) by t'- ',cn
Exchani,rc IMethod
in anionic complex form and is not adsorbed by cationite. In
the case of p H @ 1.25 no complex 13 formed. In the p If range
of 1.5-2 the complex ion:j PuY- and Pu11Y 0are formel with the
following stability constants: 4.4.10- 18 and 6.2.10- 10 Por
C, -
the thermodynamic stability constant of the complex NY
value of PK - 21 was found. For PuIfY 0 pK - 11.9 was found.
The process of complex formation of Pu 3+ with ethylene diamino-
tetraacetic acid proceeds according to the followini7 reactions:
PU3+ + HY3-w-----*Ipulfy 0, P113+ + Y4- @;;-, - PuY-. For the Co mplexes
PuY- and PullY0 the following structural formulae vr,.,re
suggested:
Card 2/4
Determination of the Composition of the Stability 30V/79-,1-3-17'./1'
Constant of the Ethylene Diqmino-tetraacetate Complex of PIA(III'. b.,,, the Ion
Exchange 'Jethod
C112coo OOC112C,
11- 11 11@1 C
2 / \\
C11 coo OOCH C
2 2
0
CH COO OOCH C
2 2
PU C
2 \\' / ,
CH2Cc)/ HOOCH 2C
The coordination number of plutonium (ITT) in the comT-,Iex,3,,3
was not dete-mined. There are I figure, 2 table,;, and
references, 4 of which are Soviet.
Card 3/4
Determination of the Composition of the Stability SOV/78-4-2-17/34
Constant of the Ethylene Dia.-nino-tetraacetate Complex of 1>U(III" by the Ion
Exchange Method
ASSOCIATION: Institut fizicheskoy khimii Akademit nauk 31"SR (Institiite of
Physical Chemistry of tho Academy of Scienceg, 1133R)
SUBMITTED: December 21, 1957
Card 4/4
30';/79-114-'@-l 9,'44
AUTHORS: ,ellman, it. D., Artiukhin -
TITLE: Investigation of the Complex Fo rmation of Pentavalent Plutonium
in Ethylene-diamine-tetraacetic Acid by the Ion Exchange Method
(Issle4ovaniye kompleksoobrazo7 aniya pyativalentnogo plutoniya
v etilendiamintetraatectatnykli rustvorakh matodom ionnogo
obmena)
PERIODICAL: Zhurnal neordan-Icheakoy khimii, 1,"591 Vol 4, Nr 6, ,p 1312-153C
(USSR)
ABSTRACT: The coml)lex for:nntion 1_r@rcss o ' in atliylene-diamine-
tetraacatic acil ivao t'@c lon, exchance metnod.
The result.3 of 'lie Ji'strib,,,,' -. (-.L t-,e pentavalent plutonium
bet ruen 0- 05 mo I -3ol -at inzi N4, C I t:,.,, :Ltion exchan-er
,xith dIfferent pli-valuk, are 1. They show that
4-
Y, i_a
t",C Complex i,)r, i,110
i: the i;!7-ramc 4 - 5
2
with the instabilitj _c@n,3L-Lr,'. inf luence of the
jill-i,alue @, the Jistri',uti i,-. o 1@ 1.,etween 0.05 mol solu-
tion -H4 Cl and tlie ion. caae of presence and
t11C
Card 1/2 abaence of Komplexon i3 ,iv,@,ri i n !'i.7iii-e 1. The instability
r .
44
Tnvesti-ation of the Formatio,% @f Pluton-um in Et,
liamine-tetraacetic )y ",ne Icn Exc:tun_:@!
rori3tants 2f the ADTA-cortlle@ L-ir c f i
'III), 1-u(VI) and
,
- IV)
u @ were @ompur-3d und b.112 inclination of
lifferpnt 7)lutonium. i@,ns to f r
ma*Lon I.hs tl.e foilow
P,,@ P11 3 > UO
2
The Pu(N' i1n the qra@ are moot inclined
to cemT,lex fo.-.aticn .;it,,-. t:@ "here are 2 fi---,res,
5 tahles, und -1 r - f Pr e-:1 Ir- S @,V: e t
AS50C Ii@'ZIOTT : Ins t i t7ut f ic,'- ec: @,()y i@ii 11,Auk SSSR
(Inz,titute of c A c a j e my -f 3ciences
USSR)
SUBMITTED: April 16, ')5F3
Card 2/2
5(2)
AUTHORSs Moskvin, As 0 akharova, P.A. SOV/78-4-9-36/44
TITLE: The Investigation of the Complex Formation of Uranyl in Oxalate
Solutions by Means of the Solubility Method
PERIODICAL: Zhurnal neorganioheskoy khimii, 1959, Vol 4, Nr 9, pp 2151-2160
(USSR)
ABSTRACT: A. A. Grinberg, B. V. Ptitsyn and Ye. N, Tekster (Ref 2) determined
the instability constant of the following reactions:
2-,,:o
UO _ 02- and
2(C204)2 C2 4 + U02C204
(UO ) ]6- IP C 02- + 2 0 (C 0 2-
2)2(C204 5 it 2 4 IU 2 2 4)21
In the present paper the solubility product (SP) of the compound
UO2 C204* 3H20 and the complex formation of uranyl with oxalate
ions were investigated. The solubility of uranyloxalate in HC10 4
and HNO 3 solutions of different concentrations as well as with
Card 1/4 additions of oxalic acid or ammonium oxalate was determined by
The Investigation of the Complex Formation of SOV/78-4-9-36/44
Uranyl in Oxalate Solutions by Means of the Solubility Method
the usual solubility method. As the data contained in table 1
show, the solubility decreases as the oxalate ion concentration
increaseso so that no complexes form in the range of concentration
investigated. Table 2 lists the values of the equilibrium
constants, table 3 those of the SP. As the graphic representation
of the relationship betwoon the logarithm of the concentration of
the oxalate ion and the logarithm of the mineral acid conmntra-
tion shows, the S equals 2.2.10-9 in the presence of chloric
acid, and 3-0.103 in the presence of nitric acid. The determina-
tion of the solubility of uranyl oxalate in oxalic acid and
ammonium oxalate solutions, respectively, with additions of
chlorio acid or nitric acid (Tables 4, 5) point to complex
formations according to the general equation
(2- 2x)H+ + UO C 0 3H 0-0 0 (C 0 )2-2x + (1- x)H C 0 + 3H 0
2 2 40 2 *_ IU 2 2 4 X 1 2 2 4 2
The graphical evaluation of the data (Figs 2, 3) showed that
predominantly a oomplex with a component ratio of uranyl ion:
oxalate ion - I : 2 forms. This complex formationo however, takes
Card 2/4 place in the case of hydrogen ion concentrations below 2 mol/l only.
The Investigation of the Complex Formation of SOV/76-4-9-36/44
Uranyl in Oxalate Solutions by Means of the Solubility Method
The equilibrium constants of the complex formation are listed
in table 6. The investigation of the solubility of uranyl
oxalate trihydrate in ammonium oxalate solutions without any
additions of mineral acid (Table 7) showed that here complexes
of the same composition are formed. The following equation was
established for the dependence of the solubility of uranyloxalate
2
on the concentration of H+ ionst [al . 7.35 H2C20 4*
By means of this equation the most favorable condition for the
precipitation of uranyloxalate from solutions in the presence of
mineral acids can be determined. T4_respective instability 2-
constants of the oxalate complexes U02C2041 and IN2(C20 4)2]
are given as (1.7tO-3).10-7 and 0.010.3).10-12 for the
oxalate ton concentration range under investigation. The
acidolysia constants are 2.5-10'.2 and 2.1.10 -2, respectively.
Card 3/4
The Investigation of the Complex Formation of SOV/78-4-9-36/44
Uranyl in Oxalate Solutions by Means of the Solubility Vethod
A comparison of the results with the data obtained in the case
of plutonium oxalate complexes shows that there are but slight
differences. The uranyl ion complexes are even more stable than
those of the plutonyl ion. The authors thank Professor A. D.
Gellman for his valuable advice. There are 3 figures, 8 tables,
and 10 references, 5 of which are Soviet.
SUBMITTEDs June 4, 1958
Card 4/4
5(2) 21(l) SOV/89-7-2-11/24
AUTHORS: Gellman, A. D., Moskvin, A. I., Irtyukhin, P. I.
TITLE: The Compositionp %-.,)A Dfssociation Constavics of P-,(V) and N(III) Com-
plexas 4th '.ostav i konstanty disscot:3iatsil komplvK-
sov Pu(V) i iu(III) s etilendiamintetrauksuanoy kislotoy)
PERIODICAL: Atomnaya energiya, 1959, Vol 7, Nr 2, pp 162 - 163 (issR
ABSTRACT: The complex formation of Pu(V) with and without complE:x-
forming ethylene diamine tetra acetic acid (LDTA) was measared
with the ion exchange method under the following conditions:
KU-21 pH range 3-3 to 5.1; ionic force @ 1 0.05 (0-05 9 NH 4Cl
solution)i temperature 20 + 10C. In the examined pH range a
complex ion of the type P4u-0 2y5- (y4- . anion of the EDTk) is
11
formed with a dissociation constant K 6.8.io- . Similarly the
complex formation was determined for Pu(III) in the pH range
1.2 to 5.4, in a nitrogen atmosphere )t . 1 (1 M NH 4CI) . The
following complex ions are formeds PuY and PuHY; their dissocia-
-18 10
tion constants are 4.4.10 and 6.2.10- . By thin and earlier
Card 112 data the dissociation conotants of the EDTA complexes of the
The Compositions and Dissociation Constants of Pu(V) and SOV169-7-2-11124
Rt(III) Complexes vith Ethylenedis-Inetetraacetic Acid
trivalent transuranic elements (Pu-Cf) can be compared and one
may see that with increase of the Z the strength of the
complexes of the type HY- increases, which is easy to under-
stand because of the increase of the ion potential. When the
dissociation constants of the complex plutonium ions are being
compared it can be established that the tendency of complex
formation decreases in the following sequencet
PU 4+ > PU3' >PuO'* >P,O', i. e. with decrease of the ion potential
2 2
There are I table and 6 references, 4 of which are Soviet.
SUBMITTED: January 6, 1959
Card 212
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V1
,67, --9.2 00(A) 69013
AUTHORS: z Denotkina, R. G., Moskvin, A. I., S/078,/60/005/04/008/040
ahavaheako, V. Be- B004/B007
TITLE: The Solubility Product of Binubstituted Plutonium(IV)Phosphate
and Its Solubility in Some Acids
PERIODICAL: Zhurnal neorganicheskoy khimii, 1960, Vol 5, Nr 4, PP 805 - 810
(USSR)
ABSTLRACT: The authors investigated the solubility of Pu01P0 4)2.XH20 in
KC104 and ENO 3# and determined the solubility product of this
compound, Solubility was determined at a constant ton strength - 29
which was maintained by addition of N&CIO 4 or LINO 3* The proolpi-
tation. of Pu(HPO4)2-xH2O (r fluctuates according to the authors'
data botween I and 4) was effected from a solution of
I - 2 M Pu(IV)-nitrate by a solution of 0.4 M K 3 PO4. The expert-
mental data are given as follows: figure I - influence of hydrogenion
concentration upon the solubility of Pu(HPO 4 )2.XH20 in HNOY
figure 2 - the same in HCIO 4 . Hydrogen ion concentration was at&-
Card 1/3 sured by means of an LP-5 potentiometer. The solubility of
& 69013
The Solubility Product of Bisubstituted 5/078/60/005/04/008/040
Plutonium(IV)Phosphate and Its Solubility In B004/BO07
Some Acids
plutonium diphosphate increases with increasing hydrogen ton con-
oentratioa, and in greater in HNO 3 as a result of the formation
of tka'a0pilex )3+. Further, the solubility of
@PU(No 3
Pu(HPO 4)20XH2 0 in distilled water and in JICIO4 and HNO3 with con-
centrations between 0.1 - 2 M was determined. Table I gives the
data. From the low pH (3-55 - 3.6o) of the saturated aqueous
solution of Pu(HPO 4),OXH,O, conclusions are drawn an to hydro-
lysis aooompanied by formation of the &quo-hydromo complex
[Pu(EC?O4)(H,O),,_,OHJ+, where n - I...ei, From the dissociation
constants of HPO 4 and the equilibrium constant for the dissooia-
tion of Pu (HP04)2'xyj2o the solubility product was calculated.
Table 2 gives the solubility product In HCIO 4# table 3 given
the solubility product In EMO 3 with an Lon strength - 2. Further,
the solubility product was calculated iamediately from the equa-
tion LP -0 [pu4+] [Elpo 2-j 2(Table 4), and finally
Card 2/3 Pu(HPO4 ).XH20 4
The Solubility Product of Bisubstituted
Plutoniu=(IV)Phosphate and Its Solubility in
Some Acids
SUBMITTED:
69013
S/078/@0/005/04/008/040
ROWBOOT
the solubility of the Pu(IV)Vhosphate was determined hi-
oally from experimental data for the solubility of PuriaMhos-
phate in mixtures of HNO 3 and H3P04 (fig 3). The mean value
of the solubility product determined according to the three
methods in 2.10-28. A comparison between the solubility
product of Pu(IV)phosphate and the corresponding Th- and
U-oompounds shows that the Pu-conpound has the lowest solubi-
lity because of its lower ionic radius. There are 3 figures,
4 tables, and 6 references, 5 of which are Soviet.
December 18, 1958
Card 3/3
S/078
BO
Z ol: I i q Y- v t! F. A. !Ionl-
T TTT.-- The Sall)b@l , ty P r
T'T V I I r
and Di sF- @ I at I -@r- Const-w.s
A-lueoi;E S@)2utoro-A
PZRIC-)!@AL-, Zliurnai rtr-rGani,.hc-@3k-y khiml@ 1960 Vol.
pp. 12?8
TFXT@ Th-@ authors exami red the formai@l on --f
r @iranium in oxala- solut.lons @y ising th@
T'. P; 1 n 5
Sol I @, 4@y prodij U( 4 2" 6H
C,
@on-.Aar@@, of f-h; r a " it, x ompour. d i- wc- -c- 6- rm -. r, @r! i n i
in-7c ' ja*- @ one . r. tet ra,:-a-t =r f. plutoni um d Lls(- r - @',I n R-2 f 2
perLd, - c-f the 5olubi I i ty product of U("- 2 0 4 1! 0 r 'Y
#.he hydrochloric. a7lid solukion was determined rnean5 )f i- j
th- radioactive Isotope TJ Th e rx a @ t i v [ I-y @d by m
Card 1 /,
The 'Scliibility Producl@ of Urarium,'IV) Oxalat-. S/1"- 60/005/0@/Cf/C5C
Comn_-.sition and Dissocia'@ior Ccns'.ar,s @f BC Y301 4
Complex U(IV) Ions in Aqueous Sollittcni
-aiirTetric apparatus of the hype 7- '0,000 (PS-10,000). Table lists ei.
"i r,@,ental da;a@ Thr- so] ubility proltv 1% was Pqwil
2., 2
- 0 /1 an , -
'-Ih- :rlmplex ions IU(C 0 tT i r U(C 0 ) ' r C
2 4 2 4 2. 4 3. 2 'ill.
--lith the instability constant5_2.@_'O 9. )'4'1Oz"' 23'
0 and
0 -.28
were dete--ted by examJninU tb- romplex --np-@unds fnrmqt-@
u(IV) in oxalate solutions in tile presen-.r- of N 111C', (Tablc- 3), '71 V,
If"'endence 9f the reolprocal lolgar!@.'bm Df the 4r),v--bility -orla@an-i -7-
thc_ ratio between metal and addend ie shown i.n a f-.jijre, Thi:-. -,nstahil 'Y
,onstanta of the oxalate @@,omplex ions -f thr, 1;9t7a.-alent T,
'rp, and Pu are nomptled in Talle A.- The auth.-irs r4-f',_7 to pap@rit by
A. A. Grinberg and G. I. Petrz@ak ' and thank PTnf:?as r A, n r- -q- -
his valuable advice. There are ' f"IGUTP, 4 tables, -,,J *0 refercn(-_
4 Sovietl I American, I Brltiiih and 2 Indian.
Card 2/3
The Solubility Product of Uranium(IV) Oxalate. S/078/6 0/G05/C6j 106 /r)7 r
Composition and Dissociation Constants of B004/BO14
Compley U(Iv) Ions in Aqueous Solutions
ASSOCIATION; Institut fizicheskoy khimil Akademii nauk SSSR (Inatitut- -
of Physical Chemistry cf the AcadsTy of Scienep USSR) I-,-'
SUMUTTED: March 10, 1959 C
Card 3/3
12
S/07 40/005/07/05/014
B004r,B(0(56
AUTHORSt Denotkina, R. G.-, Moskvin, A. I.. Shevchenko, V. B.
TITLEs Determination of the Composition and the Dissociation
Constants of the Phosphate Complexeslof Plutonium (IV) by
Means of the SoluBTil-i-Ey'-Ne-Enou k-1
PERIODICALs Zhurnal neorganicheskoy khimii, 1960, Vol- 5, Po. 7,
pp. 1509-1515
TEXTa In order to obtain stable solutions of nitric acid when dissolving
the fuel elements consisting of an uranium-molybdenum alloy of the first
atomic power plant of the USSR, 20-40 g1l phosphoric acid is added. This
caused the authors to investigate the complex-formation of plutonium (IV)
in solutions of phosphoric acid and to determine the ratio between metal
and addend and the dissociation constants of the complexes. They in-
vestigated the solubility of the gelatinous Pu(HPO 4)2'xH2o in 0.012 to
2 mole/l phosphoric acid in the presence of 2 M HNO 3 at 25'C. The ex-
perimental data are shown in Table I and Fig. 1. The solubility of
Card 1/3
Determination of the Composition and the 8/0 ' 6/005/07/05/014
Dissociation Constants of the Phosphate B05NB056
Complexes of Plutonium (IV) by Means of the Solubility Method
plutonium (IV)-phosphate at firat deoreanoto, attitina a mitilmum tit
1.06x.10-4 mole/I, after which it increases as a result of complex
formation. From the curve in Fig. I it may be seen that the number of
phosphate groups in the complex ion increases steplike from 1,2,3,4 to 5.
The following inatability constants are calculated for EINUPO 4 ) 2+
Knj = 1.2.10-13 -24; for FPu(HPO ) 3]2-
for FPu(HPO )2jo Kn2 - 1'8-10
U_ - 4 4
Knj @ 3-7-10- 341 for IP*, (HPO '4- K 6.io-44; and for FPu(HPO 6-
-53 4
Kn 5- 9.10 Fig. 2 shows the dependence of the exponent of the in-
stability constants on the ratio between metal and addend. When increas-
ing the hydrogen-ion concentration, acidolysis of the phosphate com-
plexes occurs, also for which the constants are calculated. Further, the
solubility of the dry plutonium diphosphates in aqueous phosphoric acid
solution (0.03-3.9 mole/1) was investigated. The results are given in
Card 2/3
Detertaination of the Comvo,3ition fi@id the S/0' @8 20/005/07/05/014
Dissociation Constants of- the Phosphate B0044PBB056
Complexes of Plutoniui,@ (IV) by Means of the Solubility Method
Table 2 sM in Fig. 3. Complex ions with the ratio metal : addend - 1 1 3,
1 : 4, and 1 9 5 were found. Formation of these complexes could be proved
by means of electromigration (Table 3). In Table 4 the instability con-
stants of the phosphate complexes of Pu(IV) were compared with those of
the complexes with other acid-anions, and the following order was foundl
2- 2-
CO HPO'- > C 0 .There are 3 figures, 4 tables, Find 5 referencest
3 4 2 4
4 Soviet and 1 imerican.
SUBMITTEDs March 10, 1959
Card 3/3
mn
PHASE I BOOK EXPWlTATION SW/5501
Gellman., Anna DmItriyevna, Doctor of Chemical Sciences; Apolllnariy Ivanovich
X06XVIn' Candidate of Chemical Sciences, Lev Kikhaylovich Zeytoey, Candidate
of-CEe-mic&I Sciences; and Kayya Pavlovna Kefodlyeva, Candidate of Chemical
Sciences
Kompleksnyye soyedineniya transuranovykh elementov (Complex Compounds of
Transuranium Elements) Moscow, Izd-vo AN SSSR, 1961. Errata slip inserted.
4,000 copies printed.
Sponsoring Agency: Akademija nauk SSSR. Institut fizicheskoy khinit.
Ed. of Publishing Hcuse: E.S. Dragunov, Tech. Ed.: P.S. Kaahina.
PURPOSE: This book Is intended for chemists interested in the complex compounds
of transuranium elements, and specifically for young scientific workers and
aspirants doing research in this field.
COVERA09: The book deals with the complex compounds of transuranium elements.
It describes the formation of complex compounds of neptunium (including
oxalates, carbonates, acetates, and fluorides), and plutonium in aqueous
solutions. Types of such solutions are described along with the hydrolysis
card-.1/-6-
Complex Compounds or Transuraniun Moments SOV/5301
or hydrated plutonium ions of various oxidation states. Physicochemical
properties or plutonium compounds In equeous solutions are exazIned along
with the lutonium oxalates, phosphates or Pm (u) and Pu (vi),, and acetates
of N (VIT The synthesis and properties of complex compounds of tri-,
tetra-, an@ hexa;valent plutonium are described along with the insoluble
plutonium compounds such as the plutonium oxalates, hydroxides, peroxides,
and dioxides. The formation of americium, curiumt, berkellum, californium,
einsteinium, fermium,, and mendelevium complexes am also covered. the use
of complex compounds for the separation of transuranium elements is discussed
along uith prevailing methods such as coprecipitation, extraction, ion exchange,
and fractional distillation. The authors thank Candidates of Chemical Sciences
F.I. ArtyukhIn and L. Ye. Drabkin. There axe 108 references: 54 E"91ish,
46 Soviet, 4 Swedish, 2 German, and 2 French.
TAEM OF COMMM:
Foreword (7.1. Spitsyn, Academician]
From the Authors
4
Ch. 1. Formation of Reptunium Complexes in Aqueous Solutions 5
Formation of Np (111) complexes 5
Formation of Np (IV) complexes 6
Card-ef6
27559
S/170/61/004/010/014/019
00 B108/B102
AUTHORSs Likhachev, V. A., Moskvin, A. I.
TITLEt Change in density of aluminum due to heat variations
PERIODICALs Inzhenerno-fizicheakly zhurnal, v, 4, no. 10, 1961, 111-114
TEXTo The authors studied the thermal fatigue of cylinders of 99.97%-pure
copper which were subjected to a cyclic thermal treatment, The specimens
were put into a furnace, kept there for about 5.7 min, and then chilled in
100C water for 2 min. This process was repeated cyclically. After about
1000 oycles over a temperature inter-tal of some 500 0C, the thermal stresses
led not only to a crinkling of the surface but also to a relative
deformation (elongation) of the specimens by 5 - 7%. The relative change
in the apparent density of the specimens rised with the number N of cycles
according to a parabolic law, The anomalous course of the curve
corresponding to cycles over an interval of 400 0C could not be explained.
The relative change in density was due to thermal fatigue which causes
Card 1/2
275,59
S'/170/6'/004/O'O/C14/C1q
Change in density of aluminum due to B108/B!02
microscopic cracks in the material. The greatest change in density was
observed in the regions of the highest thermal stresses. Measurements
showed a relative change in density of 2.75% cn the surface and of 2% In
the center of the specimens. In between, the decrease in density was
lesser. The relative decrease in density reached more than 4% after 200'.
cycles over a temperature interval of 6000C, There are 2 fig-ures and
Soviet references.
ASSOCIATIONs Fiziko-tekhnicheskiy institut, g. Leningrad (Physicotechnical
Institute Leningrad)
SUBMIT TED i June 12, 1961
Card 2/2
S/078/611006/005/003/015
B121/B208
AUTHORSt Zolotov, Yu. A., Marov# I. N., and Hoskvin, A. I.
TITLEt Complex compounds of pentavalent neptunium in solutions of
oxalic acid and ethylene diamine tetraacetic acid
PERIODICLLi Zhurnal neorganicheakoy khimii, v. 6, no. 5, 1961,
1055 - 1062
TEXTt The authors studied the complex formation of the NpO 2+ ion with
oxalic acid and ethylene diamine tetraacetic acid by ion exchange. The
study was carried out statically by observing the distribution of NPV
used as indicator between a 0#05 N solution of RH 4clo4 and the KY-2 (KU 2r'
cation exchanger in its ammonium form in the presence and in the absence
of complexing agents. The experiments were performed at 20 1 20C. The
grain size of the cation exchanger was 50 - 70 mesh. The pH of the solu-
tion was measured with a glass electrode and the ATT-5 (LP-5) pH-meter.
In a pH-range of 2 - 5 NP V wa3 found to form complex ions of the following
Card 1/4
Complex compounds of ... S/07 61/006/005/003/015
B1 21YB208
composition with oxalic acid MpO 2HC 204' NP02C204-2 and NPO 2(C204 ).23% The
corresponding stability constants werec 590 - 10 t 101 - 10 , and
7
2P3 # 10 . At a pH below 1,6 no neptunium oxalate complexes were obtained.
In the pH-range 2,0 - 3,2 RpO 2He204 and VpO 2C204- are formed, and at a pH
above 4 NP02 (C204)2 3% The complex formation is expressed by the follow-
ing equationat NPO2+ + HC204_.-C_-4 NPO2He204 (11),
NPO2+ + C 2042- -C @Npo2C 204- (12),
NPO2+ + 2 C20 42- -==bypo 2(C204)2'- (13)-
The thermodynamic stability constants of the NpO 2 +oxalate complexes were
compared with published data (Ref. 5t D. M. Gruen, J. J, Katz, J. Amere
Chem* Soc-P 75P 3772 (1953)); the results are summarized in Table 3. In
the pH-range 4,9 - 602 neptunium forms with ethylene diamine tetraacetic
acid on'L.V one complex of the composition Npo 2y3- and a stability constant
Card 2/4
3/078/61/006/005/003/015
Complex compounds of B121/B208
(4.9 t 1,11,109.
There are I figure, 4 tables, and 21 referencest 12
Soviet-bloc and 9 non-Soviet-bloc. The four most recent references to
English language publications read as follows' 4. G. Gibson, Il. M. Gruen,
J. J. Katz, J. Amer. Chem. Soc-, 74, 2103 (1952)1 8. T. C. Hindman, L.
B. Magnussonp T. J. La Chapellep The Traneuranium Elements. Nat. Nucl.
En. Sev., Div. IV, 14B, paper 15.2, Now York 1949; 9. R. Sjoblom, J. C.
Hindman, J. Amer. Chem. Soc., 11, 1744 (1951); 10. R. M. Diamond, K.
Street, G. T. Seaborg, J. Amer. Chem. Soc., L6, 146 (1954)-
ASSOCIATION: Institut geakhimii i analiticheskoy khimii im. V. I.
Ternadskogo Akademii nauk SSSR
(institute of Geochemistry and Analytical Chemistry imeni
V. 1. Vernadskiy of the Academy of Sciences USSR)
SUBMITTED: April 6, 1960
Card 314
AUTHORSi
TITLE:
2 S/078 61/006/008/005/018
Y)
B121/B203
Moskvin, A. I., Marov, I. N., and Zolotov, Yu. A.
Complex compoundsof pentavalent neptunium with citric and
tartaric acid
PERIODICAL: Zhurnal neorganicheskoy khimii, v. 6, no. 8, 1961, 1815-1820
TEXT: The complex compounds of neptunium with oxy-acids have been little
studied. Only Yu. A. Zolotov and Yu. P. Novikov (Ref. 1i Zh. neorgan.
khimii 6, 1055, 1961) detected a change in the absorption spectra of
neptuniu.m solutions in the presence of complex-forming substances. The
complex formation at different pH va:.ues was studied by cation exchange
between pentavalent neptunium in 0.01@ molar NH 4CIO4solution and the
cation exchanger 93-2 (KU-2) in ammonium form in the presence of citric
and tartaric acid. TI)e pH value was measured with an 11'ff-5 (LP-5) pH meter
with Rlass electrodes. In the pH range 4.5 - 5.2, neptunium (V) was
founa to form the following complexes with citric acid: NpO 2Cit2- and
NpO HCit with the stability constants (4-7 t 1.0)-103 (pK = 3.67) and
2
Card 112
S/07 6!/006/008/005/018
Complex compoundsof... 25506 B12 I Y3203
(4-9 t 1-4)-102 (pK - 2.69). The absorption spectra of neptunium (V)
solutions in the presence of citric acid at PH - 0.9, 3.5, 5.1, 5.7, and
6.1 were recorded. The absorption maximum at 963 mp was found to shift
due to complex formation to the side of increased complex formation. The
complex formation in the system neptunium (V) - tartaric acid was deter-
mined by a change in absorption spectra of neptunium (V) solutions in the
presence of tartaric acid at different PH values of the solutions. In
the PH range 3.2 - 6.2, neptunium - tartaric acid complexes of the
following compositions were determined by cation exchangeo NpO 2HTar,
NPO Tar-, NpO Tar3-, and NpO Tar5-. These complexes have the following
2 2 2 2 2 3 2
stability constants: 2.3 - 10 (pK - 2.36), 2.1 - 10 (pK - 2.32),
2.0 -104 (pK - 4.30), and 1.5 - 10 6 (pK - 6.18). There are 7 figures,
3 tables, and 4 Soviet-bloc references.
ASSOCIATIONi Institut geokhimii i analiticheskoy khimii im.
V. 1. Vernadskogo AN SSSR (Institute of Geochemistry and
Analytical Chemistry imeni V. I. Vernadskiy AS USSR)
SUBMITTED# July 8, 1960
Card 2/2
"14, 'f6
S/186/62/00'1/001/005/0@`
0 0 E075/E436
AUTHORS: Mo S, I Za y t s e va , V , P .
TITLE- Hydrolytic behaviour of plutonyl in aqueolis sollitioi-
PERIODICAL- Ra d i o k h i m i y a , v . It , ri oI , 19 62, , 7 3 - V, I
TEXT: The object of the authors work was to obt I III % ;;I()l 1,
complete elucidation of the nature of the processes of hvflrolyst@-
of pU02+ in aqueous solutions with pH changing from 3 0 to 1) 0
Concentration of OH was regulated by additions of 11C104 or
NH40H It was shown that with the increasing equilibrium VJ1Ue
of pH from 3.0 to about 8,2, the solubility of ('1'Hi,)-)P,i,)O-
decreases to a minimum value (4.2 x 10- mole Pu/litre) -,nd flien
increases for the higher values of pH (pH > 8,3)@ In
concentrated ammonia solution (pH > 13) the solubility is lowered
again, The value L)f the solubility at Of = 3.25 -1-4 19ed for 11-
calculation of solubility product for PuO-,(OH)-) w'@ich fo,iri,!
be 1,8 x lo-23. Absorption spectr1ri for the satur,ited -i@,iieoii-
solutions of (N"4)2P207 were oUtained at r)H values of - 0,
and 8,-/ . Their comparison with the spectrum for PU(V1) in
IM HCICI, showed that the spectra all differed -lue to for:,-.ation cf
Card 1/4
Hydro 1 y t i C 1,011a v I our
S/ I P'6/62/06 'I /O(j I/Oc) -,looil
E07r)/EI'36
hydrolysis products of PuO2 in the aqueou.- Solution It I H
Equilibrium constants were obtained for a serie5 of h:.
processes which led to the derivation of summarized re,ictluTll
gi ving the hydro I vs is produc ts
@:PUO + 31-120 f(PuO, (OH
)31+
lind P u 0 + 5 110 0 PU 0 OH r 11-1
Equilibrium constants for these reactions :i r e x 10 - 7
8,0 x 10-23 reslyectIvely. Compo.,qltion of And relation,hil
between the different forms of plutonyl depend on F,H of thr,
solutions, The predominant products were ((PUO,) ) - t Om -1 1 '
PH < 7,5 and P"02 ) 2 (OH) 53 - a t P H > 8 If , Betwei-n fiH v, I
of 7-5 and 8,9 solub7lity of the rlutonyl hydroxides, , Lva- at a
mi n inium a n (I de T) en de d on t h e forria t i on o f' I 1>0 011
0
Concentrationg of 1puo') ( 011 + , L,)'10'. ( oil )J, il [Pilo., I Oil
in t fie s olut ions a r e ver y sma L 1 due @o t he i r t@iti t ua I i n t @i I tt
;,h ic h I ea cis t o forma t i on o f more ( omP1 ex I on 01 0
Ca r d
Hydrolytic behaviour ...
ammonium diplutonate (NH4)2Pu207-
4 tables.
SUBMITTED: January 28, 1961
S/186/62/004/001/005/008
E075/E436
There are 2 figures and
Card 4/4
s/186/62/004/002/004/010
E075/EI36
AUTHORS: Gel'man, A.D., Moskvin, A.I., and Zaytseva, V.P.
TITLE: on the carbonaLe coctip(attids of' plutonitim
FLUIODICAL: Radiolhimiya, v.1i, no.2, 1902,
TEXT: The object of the wor1% wrtb to determine the
composition and stability of PukVI) complexes forming in 2+
carbonate solutions by determining, the relationship between Mo 2
and the addend. To confirin th" reaction.9 taking place in
the solutions some of the carbonate r-omplexes of " were
separated in the solid state. The equilibrium concentration of
Pu in the solutions was determined by a radiometric method and
pH values were measured by a potentiometer type f(II-5 (LP-5)
with a glass electrode. Solubility of' ammoninin diplutonate in
ON"4)2CO3 solutions was determined and found to increase with the
carbonate concentration. Dissociat-Lon constants were calculated
for the first time for the following complexes:
EPUO 2 (CO3) (OH) 2' 21120] 2-, LPU G2(CO3)(010-3H20]-, and
Card 1/2
on tile carbonate compounds Of ... s/186/62/004/002/004/0-10
E075/E136
T'-I-'L'02(C03 )2 - 2H20 32-. Dissociation constants and solubilitv
products of 1'uO2 C03 were alfjo determined. The authors isolated
for the first time a compound Niij,@Pllo,(Co )(Oil) - 311,0@ from
3
dark red corbonate solutions. Carbonate complexes with a ratio
Of @'022* to addend equal to arid 1:3 were also isolated.
Tile solubility of plutonyltricarbonatte in M-14)2CO3 solutions
of various concentrations was determined and the absorption
spectra of the green solutions thus obtained were measured.
It was calculated that tinder these conditions a carbonate
complex w3.th a ratio of yo','2* to addend equal to 1:2 forms
predominantly.
There are 2 figures arid 4 tables.
SUBMITTED. March 1, 1961
Card 2/2
5/02oj63/149/003/023/028
BM/B180'
AUTHORS: Geletseanu, I., Lapitskiy, A. T.
TITLE: Some regularities of complexing of pentavalent actinidea
Akademiya nauk SSSR. Doklady, v. 149, no- 3, 1963, 611-N
TEXT: On the basis of compositions and instability constants of complexes.
of pentavalent Pa, Rp and Pu with anions of some acids (determined by
means of vhe ion exchange method), the tendency of these elements to form I
co,mprlexes was shown to be much stronger than is generally supposed. This
entionedp as they form.
tendency is much the same for the elements m
complexes of identical compositionand approximately identical stability
wi'ts'anioneLof suitable acids. The tendency of the addends to form
complexea decreases according to the following sequence:
.4- 3- > Hp02- 2-
> Cit > tart >Ao_-C::@ Laot-.' The stability of the complexes
4
of Pa (V) with hydroxy acids permits generalization of this sequenc-.@ as
follows: ETTA >oitrio acid > oxalic- >phosphoric- >@ trioxyglutaria >a-!
hydroxyie-obutyrAio '7 tartaric malio Mandelic acetic ?,lactio acid.
S/020/63/149/003/023/028
Some regularities of i.. B11T/B166
Although no complete data exist for-11p(V) and Pu(V), this aequence can
also be applied for these elements owing to conformance of instability
copetants. Instability constants of complexes formed by Pu of different
valence'with the same addend show that Pu in the pentavaleat state has the!
weakest tendency to form complexoa. On the basis of the similarity of
complexing properties of pentavalent Pa, Np and Pu, and of the
qu@antitative data available, conclusions may also be drawn as to the
composition and stability of complexes of pentavalent uranium with the
acids mentioned. One of the properties of actinidea which serves to
prove their position in the periodic sy8tem of elements is their behavior
during ion exchange. Pa, lip an'd Fu in, peatavaleat state were found to
behave similarly during ion exchange#. 'Thera are I figure an(i I table.
ASSOCIATION: Mosk,)vskiy gosudaretvennyy universitat ia. K. V.
IN6
Lomo.
aosova. scow State University imeni R. T. Lomonosov),
PRESENTED: Octo*Der 29, - I 962,'by 1. 1. Cho
rayayevl Academician
SUBUNTED: Ooto,)er 24, 1962
rd- 2/2.-
MOSKVIN, A.I.; PM!.7RUKHIN, V.F.
Study of t.-m comljljx of 1-11t, val,;rit %"j,turdum in
-1
phosphate ijolutiona by means of* Ion exckang.-l. iwa.,okhimlia
6 no.2:206.-214 164. (MI.-iA 17:6)
MOSKVIN, A.I.; ZA)rrSEVA, V.P.; GELIMUTI, A.D.
Study of th6 complbz formation -of +Irivalent plutwilli;.-
of acetio, citriop and tartaric acids by means of ion sxchange.
Radio'khlmlia 6 no.W14-230 164. (@@!,ItA 17.6)
L ooo35-66 EWT (m)/EPP (a) -2/FWP(j ) /T/E-KP(t)/UP(b.) IJP(c) JDMIMI@M,
ACCESSIOK KR: APS020303 Llk/Oi66/65/0071004/01tlGloklg''
541.49:546.799.3.5:661.733
-AUTHOR: Koskvin, A. r.; Kefod'yeva, M. P.
TITLE: Formation of pentavalent neptuni complexesAn lactate and glycolate
solutions
;SOURCE: Radtokhimiya, v. 7, no. 4, 1965, 410-4L9
'TOPIC TAGS: neptunium compound, complex compound
11ARSTRACT: The recent do-termination of the composition and stability constants for
complexes formed by KPO+ ion with oxalic, citr c and tartaric acids led the authors
1 2 1
ito obtain data on the complex formation of Kp02 ion with lactic and glycolic acids.
@They used the experimental procedure described in Zhur. neorg. Xhim. 6, 1813 (196.0
@and Hadiokhimiya 9, 214 (19610 to study the distribution of Kp M between the cat-
@ionite KU-2 and lactic acid solutions of different concentrations. The equiMriuK
!concentration of different form of 1(p M as a function of the concentration of
@Lact Is
I shown In Fig. 5 (Enclosure 01). The concentration of lactic acid was
pivaried within 040054.2 K range and pR 6,5. The ionic strength values were V=0/06
iand UtO.2. Twolactate, complexes wera dideovered! INP02L&ctjl and [HP02(Lact)21-
Card 1/3
4L 00035-66
ACCESSrON MR: APS0203 03
The concentra-tionstability constants for these two complexes amf
(SeSltl,
respectively., Electr*phorssis pro'duced .distribution curves which show that in lac-1
tate solutions neutral complex is predominant. ru glycolate solutions of complexes!
only an electrically neutral complex of Np (V) Is formed, The stability constant of
this complex is W7. The thermodynamic equilibrium constants were calculated and
listed with those of other neptunyl. complexes. Acid- anions arranged in decreasing
lorder of complex formation are as followst. .. 1
4- , cjt3- ),. io HPO&73,, tart2- KCOj 902- 3o AeuGlya 3, Lact-
I Y C204z- a
10rig. art. has: 4 tables and 8 figures.
iASSOCIATION: none
ISUBKITTED. 14Dec64 EKCW 01 SUR CODE: IG,.QG
iM0 REF SOVs 015 OTHER: 003,
I Card 2/3
.Looo35-66
7ACCESSION RR: APS020303
ERCLOSUIM: 01
40-
J
Fig. L Cquilibrium concentration of
different form of Rp (Y) as a functLon,
of concentractim of Lact in aolution#-@
(the total content of neptunium in the
solution is taken as 100%)
I- EKpOirActI*; 2-m [MpO2"1
ca@
13
F-ViT(M)/EPF (c
ACC NRt A
OP(t)/BaP(b) LJP(c) JD
SOURCE CODE: uR/ob-78T6
2 2
AVMOR: Denotkina,, R, G.;.Shavchenkop V, B.; Moskvinp A. 1.
ORG: None
I!ITLE: The solubility product of ammonium plutonyl phosphate In
aqueous solutions
SOURCE: Zhdrnal neor n chaskoy khimti;, v, 10,, no, ll,, 1965t 2449-2452
POPIC TAGS: ammon sphatep plutonium compoundp solubility
ium. pho
ABSTRACT: Amzwn1wm plutonyl phosphate was precipitated by the reaction
of a 0,1 molar nitric acid plutonyl solution with an 8.26 x 10-5 molar
concentration of the metal and a 1,0 molar solution of (NH4)aHPOI,e The
finely crystalline precipitate obtaineds which was of a light griren
color and had the composition NH4Fu02P04-3H20P was the starting materi&
for the investigations, The soldbillty of ammonium plutanyl phosphate
was determined in aqueous solutions over the pH range from 1.0 to 6.4.
In one series of experlmnts the pH of the solutions was adjusted by
addition of HG1Oh# and in another series of experiments by addition of
HWOi* The Ionia-ratrength in the solution was not aonstantp since
add tion of N010h or LiNO3 to maintain mm constant brought about
partial replacemedt of the NK4 group by sodium or lithium Loner as a
UDC:
-T99-4f39'185
-1 . 1 -1 .., el .@ 0 -z- 0
L 8143-66
ACC NRc AP5027204
result of which the solubility could be determined only for the mixed
compound (NHh, Na)PuG PO or (Nff LL)FuO PO but not for a=onium
plutonyl phodphate. SOK@@Iity data is exhibited In
tabular form, On the, basis of the experimental datap calculations were
made of the solubility, product or amdnium plutonyl phosphate and or a
double substituted plutonyl phosphate; th 15 a were found to be equal to
(2*3 + lo2) x IG-27 and (2,8 + 1,3) x 16- . The concentration In-
stabiTity constants for NH4?u62PO and PuOpHPOIL were calculated to be
equal to 3*7 X and 'J491 It is coAcluded from the calcula-
10,-22 6.8 X 10 &
ted solubility products for Xff4Pu02PO4*3Hp0 and PU02HPOi that aftnonium
plutonyl phosphate belongs to t .he groups,of slightly so itble compounds
formed by the reaction of the PUO??-+ ion with phosphoric acid. Orig,
art. has: 10 form,las and I table.,
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"Problem of Cathode Utmineacence," Candidate Tech
act A. v. maskvin, 6 pp,
"Elektrichostvd" No 3
Luminescence brought about by electron bombardmenta
very widely used in television, radar and anoillo-
graphic instrument as means of trwwforalng ilectri-
cal impulses into light. Diagrams the operation of
cathode luminescence In systems requiring high qualit@
luminophors. Also presents sane purely theoretical
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tow.
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Cathodohninescence, fart Il. Cathodoluminophors and Screens. Glawt.oligrafizdat,
Nain PolygraFhic Fublishing House, 700 pp, 1952,
AUTHORSt Lushehik, Ch.B. and Mosirvin, A.V. SOV/51-6-1-28/30
TITLH@ VII Confarence on Luminescence (Crystal Phosphors). (VII Soveshchaniye
po lyuminestsentalt (kristallofoofory) )
NRIODI(.;ALs Optiica i Spoictrosicoplya. 1959, Vol 6, Nr 1, pp 122-124 (USSR)
A BSTRA 0 T i The VIT Conference on Wmins4cence was held in Moscow between June 26
" July 3, 1958. It was organized by the Physics Institute Imeal
P.H. Leb6dev of the Academy of Sciences of the U.S.S.R. and by the
Scientific Coun@.Al on Luminescence. The conference was devoted to
the physics , chemistry and applications of crystal phosphors . Over
360 delegates from 24 cities &no towns in the Soviet Union attended the
conf3rance. Hanirarian, Polish and East German scientists were also
present. Over 100 papers were read at 4 plenary and 14 sectional
Sessidna. Tne conference was split into two parallel sections an the
physics and on the ch6mistry of crystal phosphors. %pars on the
ph@sics of crystal phosphors could be divided into the following grouass
(1 nature of the luminescence centres, (2) processes of transfer of
energy in crystals, (3) kinetice of recombination luminescence and the
naimrs of capture centres, (4) physical processes occurring on
excitation -with electric fields, electron bows and hard radiationa.
Card 1/6
VII Conforonce on Luminesc6nce (Cryetal Phosphors).
6OV/51-6-1 -28/30
The authors review first the papers on the nature of luminescence
contras. These papers included work on quantz=-wochaaical calculation
of a luminesconc-a contre In KC1,-T1 (N.N. Kristofell), a discussion of
alkali-halide rhosphori activat(sd with mercury-like icna (F.TA.Lushchik,
work: on halida phoqphore in which the aztivator ions were saLQ to be
distributed along crysta! lattice sitoi (F@D@ Klvent) , a discussion
of surface offectE in luminescowo (P. Shvi3t ana N.I. Ivanova). a
paper on cryitAlv in whinh lumine-..-en@:@ @!qntres are In the form of
compl.-.kxer ='ltuated cn the surfewn i,( @U. 3hatieveciy and A.A.. Dunina).
Z @A*Traoatsritiro-a, M.L. FAtr acd N.1fi.Wchchik shcmed that in phosphors
with one activator several typov of .@mlna3caw,* contras are possible.
The offort,3 rf uniform prossurto of 7000 atn on luminescent properties
of Zn41UO4 44n aad of halile phosphors wora, reported by Ya.Ya. Kira.
1,
Z.L. 11organshtera reported w@rx cn 1w!i.'.nqBcanc* of non-antivated
algali-halida @rystai_,i. The timperaturs Tuan,:hllng of luminescence
oi al"li-halida phcrphors ani the relationship between optical and
thermal prop-artioa of Impurity contro@ were reported in a Paper by
K.K. Shvaft';, 1.L. Plya-;Ul ancrPed that the ahort-dUration emission
C%rd 2/6 of alkalt-halAde phoephort ii of inetaitable nature. A number of papers
, OV/ 51
V11 Coaferews cn LumiL;esr-enca kCrystal Fhosphora)
deft1t with rqptord 7eatras in alkal'L-halide phosphors kI.A. Parfianovich,
F.K. Zaltr,-, L,Ya. Uyb,@@, ?@A@ t0iellewirme, A.Kh. Khalilov,
A.X, Foltrsiciy and othere). Ch.B. Luahchilc ana G.G. Liyd' ya
inver.tig,.ati,orn af th-c tntorR@tlon of' oxcAtons with various defectu of'
the cryFts.'- latt-@,e. of ele@,tron auJ hoia processes producing
r3c-ccabtratlon in a-liaij-halid,9 phosphors were discussed
in JkL@IOrE@ hy I&J- eAti, 1,A, Farftaunvl@-,h, L.!@. Shamovskiy, Ch.B. Lushchik,
Kh P. Kyaambrn and Yaok. A gr,-ip cS papere dealt with kinetics of
recrunti-nation an@ iaterpretaticr. of relaxation relationshipL
in termi .)f the tand th.+,jx-y -,f ph"L-hr.rv k:ia, Tolstoy, A.A. Rysidn'
LI,V. Yok, F.!,, e,,&. Ritaa@*. YuAd. Pop-:@'7,@. Flash SMission by
wan ropcrtel 1)v N-L@ T.)1iitcy and h.13 zo-workers. The
effef!t )r infrarb,j ra6lation on re,@=blnaticn luminesTance was discussed
in papera by P.? Poland) and K,S.K. Rebans. V.L. Levshin
and B.M. Orlo,1 stu- x-,mo-optical maximum -,f electron liberation
from captnro levela. !a papers and discussions at the Conference It
ms stressed that atudio? cf re@omblAation bunines,:ence kinetics should
include not only ele,:-tron and eleAron-hole prci-ssues, but also exciton,
sensitizing, iont-, dislccaticn and electron-vibrational processes. Only
a srall number of papers dealt with luminescent and sleetrical prop-trties
Card 3/6 of pho-3vh--@ @O,V. Agnahkin, I.K. u*tol, va.A. Ok-,.Tr@,a,
VII Conference on lAoinescence (Crystal Phosphors)
P.Ye- Razazano-). Frofasoor Nad, (Nagy) of Hungary, V.V. Antonov-
Rctmanowskly, IA,V. Fok and othors discussed the Sochan1cm and kinetics
of electroluminescencv. V.Yo. Orano,7skly and B.T. Fadyushin reported
their investigations of anisotropy of aloctroluminescence in synthatif-
US crystals. V.Ye. Oranovekiy ana I A. Trapernikova read a paper or.
sulphides activated with rare earthe in which thay established the
identity of emission contras rasponsible for photo luinines can ce, &ad
alectroluminescancs. Practi,@al aonlications of alectroluminescance 71-3r.-.
dealt with @n the pa?ers of K,N. OrIc7 %Ld I.Ya. Lyamichav. Papers on
cathodoluminas,:,en@-t# of cryatalP in,!Iuded one by M@D. Galanin and
A@V. Raye,7skiy on temperature quenching of lumines-cance of ZnS-AS
excited with M-Partic:163. The paperg on the chemistry of crystal
phoephori dealt wita a treat variety ef zubjacts. Many of them
descrIbad pr*Uaratii;n of now photo -Pbnt rhnrg (Yu.M. Loonov and
F.M. Pokerman) , cathodo-phos pho& OXUW-1-10 vr%-O.- :CIAd2o
n.it. Gur'Lachava, BJd. Gugell, L.Ya. xa,irovnicxy ana V.r. avL&tt;via) and
slactro-phosphors (T.K. Voznssenskaya, OX. Katankin and Z.1. &Iabukova) -
Luminescence of oxidet (M.A. Konstantinova-Shlazinger), observations on
behaviour of earopium in silicates and phosphates kYu.S. Blank and
;a rd 4/ 6 V.?@ Nararova), rolationchip between tamp mturo quenching and stabilit-.i
VII Conference on Lu,:iinaseanca (Crystal Fhosphors,, SOV/5.1-6-1-28/.30
of crystal lattlos,3f tungstates (Y-aJd. Loonov, and ageing in
cathodo).L@mine;;^ozica kB-41. Gugoll) ware also r;ported. Interaction of
Oblus" aaa "samari=l centras in s-jLlphide phosphors activated with mr&-
earth ion5 was reported in a papor by Z.A. Trapeznikova. Excess tiac
and 611ver aA activatora of sulphidag ware discussed by A.A. Bundell
ano Chorspns-. khe affe-it of exygen in formation of lumiaescencis
centro vas dealt vulth by A.A. Bumdel, , A..". Gurevic-h and Yu.M. Laomov.
Exiitance of a now %rystal phave In the wurt?ita-sphalarita system was
dliro7overe-! by S.41. F.-ldvan who a-';;o reported work on rare-earth activators.
Preparation of -;ulphllde mono.-ry4talv was daq,:!rIbed by Ya.I. Panasyuk.
Phase analysis cf willamite waa reported by V.V, Odko. Many papers
dealt with phcephors prepared @y aublimatioa and with Ituainascent
scroens. Hxtenpicn of the range of a:@tivatora and bases used to
prepare screong by sublimation was also reported. Practical applications
of such screena ware dealt wit.4i by E.Ya. Arapova, Ye.l. Blathnova,
Card 5/6 N,A. Vlasanko arrJ V.V, Golubeth, xhore were only a few papers on the
VII Conference Ca Luminescencs (Crystal Phosphorn)
industrial processes of preparation of phosphors and on purification
methods. ApPlicatica of luminescence to the study of phase squilitrial
(Y.V. Oeikv)and to the etudy of reactions in the silicate phase
(A.&. Trofimo- and T@@.M. Leono7) were also reported. The authors of
the report point out that the Conferen4@e showed lack of coordinAtion
of studies of phosphors and semiconductors and come examples of lag
of theory behind experiments and vice versa.
Card b/6
MWKV111, A.V.
Intakes In rivers of the north. Sbor.nauch.raboAiM no.12:82-92
162. (MMU 16:4)
(Russia, Northem-Intakes (Hydraulic engineering))
97 - i - 8Ao
AUTHOR: @bskvin, B.M., Dr. of Technical Science, Prof., an4 Alekseev, S.N.,
'NidlAit-e-or Technical Science.
TITLE: Method of Improving Corrosion Resistance in the Reinforcement
of Concrete Construction. (SDosohy povyaheniyakorroztonnCy
stoikosti armatury zhelezobetDnrVkhkonstruktsJY.)
PERIODIC;L: B.ton i zhelezobeton, 1957, Ho. 1, pp. 28-29, (U.S.S.R.)
ABSTRACT: The corrosion resistance of steel is affected by the quality of
the concrete used, and decreases with decreasing alkalinity,
i.e. when the hydrogen ion concentration falls below 9.5
which can occur due to the carbonization of the cement matrix
which is in direct cdatact with the reinforeemtfAt. Th 'e degree
of carbonization dVends on the permeability of the protective
layer, the permeability being a function of the density and of
the thickness of the layer. Considerable reduction of the
permeability can occur during autoclave curing, especially
when cement containing silica additives is used. In all these
cases the degree of corrosion is influenced by the thickness of
Card 113 the protective layer both during the initial stages of the hardening
97 -1 - 8AO
TITLE: Method of rnproving Corrosion Resistance in the Reinforcement
of Concrete Construction. (Sposoby povysheniya korrozionnoi
stoikosti armatury zhe1ezobetorx0i& konstrukair.)
and during the final stages when corrosion is retarded by the
formation of metal recommended to ensure a substantially thick
protective layer. Various methods devised to achieve this protective
coating were submitted to the authorities, e.g. the coating of
the reinforcement with a cement slurry containing various additives,
coating with a layer of bitumen, ate. The first method did not
prove to be successful, the second method, although more advantageous,
has the following disadvantages: the adhesive properties of the
concrete and the steel are not utilised, it Is difficult to ensure
the coating of all steel surfaces, and there is the undesirable
affect of heat on the bitumen during autoclave treatment. The
best method of protecting steel surfaces appears to be the
Oneutralisation" of the surfaces of the reinforcement. Ordinary
concrete, due to its high degree of permeability, acts as a
"neutraliser". Experiments were carried out to bring about this
*neutralisation" artificially. Various inorganic salts are known
to act as oxidising agents and thus act as Oneutralisersw,
Card 2/3 e.g. chlorides, nitrates, phosphates and some alkaline metal salts.
97 1 - sAo
TITLE: Method of Improving Corrosion Resistance in the Reinforcement
of Concrete Constructions. (Sposoby Povysheniya Korrozionnoy
Stoikosti Armatury ZhelezobetoMkh KonstruktsiY'.)
Investigation showed that the best additive is Na nitrate which
is added to the cement mix (2-3% by weight 6f cement.) Coating
with this chemical substance proved unsuccessful during autoclave
treatmeht. NaK02 did not have an adverse effect on the physical
or the mechanical properties of the concrete in the above proportion.
There are 1 table, 2 Slavic references.
ASSOCIATION:
PRF-3ENTED BY.-
SUBMITTED: ---
AVAILABLE: Library of Congress
Card 313