A COMPARISON OF METHODS FOR “THE VOLUMETRIC DETERMINATION OF HYFOPHOSPHITE Thesis for flu: Degru of M. S. MICHIGAN STATE COLLEGE john D. Brooks 1947 ‘. 733*. ‘,~.—~-‘--fi‘. ‘.l ,— ~‘\ “. v-"~'- |““ ‘1 ‘ \ I ‘ ‘ ' ' ' -»w—QU£aandbr'tniB'DbGUmunC ah: AanLnnLo 0n hLCmurlLfi BY'GONTIflTIIO ' '~ “In Doom-“‘35 3131510135, E‘-?I‘j-JLLIC:.,I€ 3 r3-2, 12.1“: 2;.an 0025mm, 15:74) 9.351335:ng :0 no 7 5 6 Kliiqk‘l’ 1mm. '-‘-“-—— 0mm .0 I“ a cum- TSNAD This is to certify that the thesis entitled THE COMPARISON OF METHODS FOR THE VOLUMETRIC DETERMINATION OF HYPOPHOSPHITE presented by . A John D. Brooks ; has been accepted towards fulfillment :‘ of the requirements for IVA. 80 degree ill-ghemiStg ’ «If? . . ‘ n ET ‘ Major profe‘or —— M Q; (1 mm a «— vi 7 n_r ow: A COMPARISON OF METHODS FOR THE VOLUMETRIC DETIBMINATION OF HYPOPHOSPHITE by John.D. Brooks A THESIS Submitted to the School of Graduate Studies of Michigan State College of Agriculture and Applied Science in partial fulfillment of the requirements for the degree of I STER OF SCIENCE Department of Chemistry 19h? ACKNOWLEDGEMENT Grateful appreciation is expressed to Doctor Elmer Leininger, under whose kind and efficient direction this work was carried out. *ié-Wn‘fi- 9‘ s‘ * \l—X' aes- \86808 TABLE OF CONTENTS Introduction.............................................. Historical................................................ Preparation of Potassium Hypophosphite.................... Preparation of Sodium Hypophosphite....................... Oxidation of Sodium Hypophosphite‘with Iodine............. Oxidation of Hypophosphite Using Potassium Iodate in Sulfuric Acid Solution................................. Oxidation of Potassium Hypophosphite Using Potassium Bromate in Hydrochloric Acid Solution.................. Oxidation of Sodium Hypophosphite with Potassium.Bromate and Sulfuric Acid...................................... Oxidation of Sodium Hypophosphite with Bromate-Bromide in Sulfuric Acid....................................... Oxidation of Sodium Hypophosphite'with Sodium Chlorite... Oxidation of Sodium Hypophosphite with Sodium Hypo- chlorite............................................... sway-0....OOOOOOOOOOOOOOOOOOOOO0..OOOOOOOOOOOOOOOOOOOOOO Bibliography-0.0.0.000...0..0.0....0OOOOOOOOOOOOOOOOOOOOOOO JU'JL‘UQUUL.‘~€. nnnnnnnnl Page l 3 13 18 23 25 26 27 28 29 3o 35 38 INTRODUCTION Theoretically the hypophosphites are powerful reducing agents; however, they are often hard to completely oxidize in short periods with some of our more powerful oxidizing agents. There has been an appreciable amount of work done on the oxidation of these salts. This is especially true of the volumetric methods for determining the hypophosphites. The work as recorded in the literature is often conflicting or misleading. A few examples of this are as follows. A method is given in the literature whereby the investigator used a boiling potassium permanganate solution as an oxidant. A com- mon precaution given students in the laboratory is, not to boil permanganate because it is unstable at high temperatures and especially so in the presence of an acid. Another inves- tigator lists a bromate-bromide method, in'which he used either hydrochloric acid or sulfuric acid as a catalyst, with a one hour standing period. The tabulated results show the method to be accurate. Still another investigator claims that a one hour standing period is not a long enough time for com- plete oxidation, but a three hour standing period is sufficient. Still another worker, following recommended procedures for an iodine oxidation method, finds them to be about 80% efficient. These examples cited are but a few of many discrepencies that occur in the literature. It became the purpose of this research then to test these methods following the procedures as given in the literature, and at the same time to work on possible new methods of analy- Sis. HISTORICAL In 1816 P. L. Dulong (8) isolated the salts of L'acide au phosphoreaux au minimus d'oxigine. He called the acid, acide hypophosphoreaux, hypophosphorous acid. He showed the acids and its salts were prepared by the decomposition of phosphides of the alkaline earths with water. The hypophosphites are obtained by dissolving the bases in an aqueous solution of the acid, or by boiling phosphorus with the hydroxides of the alkalies or alkaline earths in aqueous solution. The salts are usually stable in air; however when heated, the salts of sodium, thallium, lithium, magnesium, zinc, cadmium, strontium, barium, manganese, and '1ead give off hydrogen and phosphine, leaving pyro and.meta- phosphates behind. The hypOphosphites are nearly all soluble in water, and the alkali metal salts are soluble in alcohol. There has not been any work recorded however as to the extent of solubility of the salts. Boiling out of contact with air causes no change in valence; in air, oxidation to the phosphites and phosphates takes place, C. F. Rammelsberg (28). The hypophosphites are all decomposed by heat to furnish pyrophosphates and.metaphos- phate. The mole ratio of perphosphate to metaphosphate is 1:1 with sodium and thallium.salts, 2:1 with magnesium.and on -3- up to 6:1 with the barium salt. H. Rose (30) worked on the gaseous thermal decomposition products of hypophosphites as did Rammeleerg. They found the gaseous products always to be a mixture of hydrogen and phosphine which was spontaneously combustible and which varied according to the circumstance. Hypophosphites have been, and still are, prescribed in medicines although it is possible to recover the hypophosphite unaltered from the urine twenty-four hours after administering the same. Investigations along this line were made by G. Polke (26), P. Schulz (35), and.M. Paqueilin and L. Joly (25). A good, accurate and rapid method for the determination of hypophosphites has long been sought. The oxidation of hypo- phosphite to phosphate is surprisingly slow and erratic in spite of the fact that it is a strong reducing agent. The vol- umetric procedures developed call for closely controlled condi- tions in order to get fair results and are highly empirical in nature. Pean de Saint-Giles (3h) first attempted to oxidize hypo- phosphite with permanganate but found that oxidation was incomy plete. Amat (1) found that the speed of oxidation.by perman- ganate increases with concentration of hypophosphite, with temperature and with acidity. At high temperatures some per- manganate decomposes, while at ordinary temperatures the reac- tion is incomplete. He recommended adding an excess of perman- ganate at room temperature, heating to 50 degrees for one-half -l4- hour, adding a measured excess of oxalic acid and back titrating the excess with permanganate. Marino, and Pelligrini (2h) recommend oxidation of the hypo- phosphites with permanganate in an alkaline solution and at a boiling temperature. The excess permanganate is determined with oxalate. Kolthoff (18, 19) states, that the permanganate method carried out in acid solution and at room temperatures is accur- ate if allowed to stand twenty-four hours before back titrating the excess permanganate. Zivy (bl) adopted the method of Gailhat (9) to determine the hypophosphites, (i.e.) using permanganate in strong sulfuric acid solution in the presence of manganous sulfate and refluxing for twenty-five minutes. Koszegi (22) recommends the use of permanganate in neutral solution at a boiling temperature, followed by iodometric deter- mination of the manganese dioxide and excess permanganate. Kolthoff (20) pointed out the error in Koszegi's method as well as other methods at elevated temperatures, i.e., the autocataly- tic decomposition of some of the permanganate. This was borne out by the fact that Koszegi obtained higher results with his permanganate method than with his gravimetric conversion to magnesium pyrophosphate. Kolthoff recommends the following changes in Koszegi's method-qulow the flask with the hypophosphite and permanganate to stand for 2h hours at room temperature and then titrate the excess permanganate iodometrically. He recommends further that -5- blanks should be carried through with the experiment and the necessary correction applied. A. Schwicker (36) recommends the addition of an excess permanganate solution to the hypophosphite solution. This is followed by a 30 minute heating period, after which the remain- ing permanganate is titrated either iodometrically or with oxa- late. Schwicker states that the rate of oxidation is greatly in- creased by the addition of four or five drops of a five percent ammonium molybdate solution. A general method of oxidation in an alkaline solution whereby the permanganate goes to manganate and is then precipi- tated as barium.manganate has been suggested by Stamm (37). Gall and.Ditt (10) use a standard.manganate solution in excess and a high temperature to effect the oxidation of the hypophosphites. The excess manganate is reduced.by addition of an excess of oxalic acid. This is followed by a back titra- tion of the excess oxalic acid with the original manganate solu- tion. Pound.(27) states, that oxidation of hypophosphite by per- manganate in neutral or acid solution is slow and direct titra- tion is impossible. After standing for several days the per- centage of hypophosphite determined was no greater than 96%. He found however, that traces of potassium bromide had a cataly- tic effect, which was possibly due to the formation of free bromine. This effect was great enough to cause complete -6- oxidation at room temperature after a few hours. Dickerson and Snyder (7) were able to obtain satisfactory results when they used mercuric chloride as an oxidant. They found that a one hour heating period followed by a thirty min- ute cooling period was necessary to obtain quantitative oxida- tion to phosphate. Ionesco, hatiu, and Popesco (13) and Jean (1h) obtained similar results with slight modifications of this method. However Schwicker (36) reported that this method was very slow. The oxidation from hypophosphite to phosphite was fast but from phosphite to phosphate was complete and quantita- tive only after many hours. C. A. Hurtz (hO) and H. Davey (6) making only qualitative investigations found that hypophosphorous acid was oxidized to phosphorous acid by hypochlorite. K. A. Hoffman (11) using a water solution of potassium chlorate found the hypophosphites were qualitatively oxidized to phosphate. The oxidation was quite rapid but of no value quantitatively. The speed of the oxidation was increased.when osmium tetra oxide was used as a catalyst. S. Komaroski, V. F. Filonova, and I. h. Korenman (17) recommend the use of the sodium salt of para toluene sulfo chloramine (chloramine T). The results, (they list no data) were satisfactory, although somewhat lower than by the iodo— metric method of Rupp and Finck (32). The reaction is as follows: CH 3 - I CH 3 06314 H o / \302 - N’01 1- 1131302 .2.» 06H5\ + H3PO3 + NaCl \ Na SOZ-NH2 A. Schwicker (36) investigated the use of sodium hypochlor- its and found that in the presence of sodium.bicarbonate he could oxidize phosphite to phosphate with no interference from any hypophosphite that might be present. Both Dulong (8), and Kolthoff (20) state that chlorine can be used as a method for the quantitative determination of hypophosphite. Rupp and Kroll (33) used a bromate-bromide mixture for the oxidation of hypophosphite followed by an iodometric titra- tion after one hour. Kolthoff and Furman (21) state that one hour standing time was not long enough a period, as it gave re- sults that were from 1.5% to 2.% too low. Heating causes a loss of bromine: therefore, they recommend a three hour standing period at room temperature. W. Manchot and F. Steinhauser (23) stated, that phosphite can be quantitatively oxidized to phosphate by using a fifty percent excess of bromine in potassium bromide solution. The presence of a mineral acid retards oxidation. Oxidation is much more rapid in a neutral solution. It is necessary then to add an excess of either sodium.acetate or sodium bicarbonate to the phosphite solution before adding the bromine. Hypophosphite -8— in the presence of a mineral acid requires three hours before complete oxidation takes place. Oxidation in the presence of an excess of sodium.acetate or sodium bicarbonate, and at a sixty degree temperature requires only 30 minutes. F. Viebock and K. Fuchs (38) recommend the use of a saturat- ed bromine water solution and boiling. The excess bromine is finally boiled off. The solution is cooled, a few drops of phenolpthalein and a few grams of sodium chloride are added; the primary phosphite is titrated to the secondary salt. Excessive heating must be avoided to prevent decomposition of the hypophos- phite. In the national formulary methods, G. L. Jenkins and C. F. Bruning (15) list the potassium permanganate method as unsatis- factory because of its excessive yield and length of time re- quired for oxidation. They recommend a method, good for all hypophosphites, using a bromate-bromide mixture with sulfuric acid as a catalyst. Rosin (31) recommends the use of an excess of free bromine in presence of sulfuric acid and a three hour standing period. A. Schwicker (36) used a bromate solution in presence of either sulfuric acid or hydrochloric acid. This mixture was heated just below boiling and allowed to stand for forty—five minutes. The hypOphosphite is oxidized almost immediately to phosphite. The phosphite in turn is oxidized to phosphate over a longer period. E. Rupp and A. Finck (32) used iodine in two different solu- tions to effect the oxidation of hypophosphite to phosphate. The iodine was used in acid solution for the oxidation of hype- phosphite to phosphite. The solution was then neutralized with an excess sodium bicarbonate for the oxidation of phosphite to phosphate. The first oxidation in acid solution is very slow. The second oxidation in neutral solution however is quite rapid. Boyer and Bauzil (h) gave the following equations from their work on iodometric determinations of hypophosphites. In acid soln: (a) H3P02 + 212 + 2H20 a H3Poh + hHI In acid soln: (b) H3P02 + 12 + H20-—>H3P03 + 2H1 In Neutral soln: (c) H31303 + I2 + H20-—>H3P0h + 2H1 To make the determination quantitative it was necessary to use the equations (b) and (c). They found that the reaction in both (a) and (b) proceeded at a much slower rate using acetic acid, and much faster using hydrochloric or sulfuric acid. Reaction (c) was complete in thirty minutes using sodium.bicar— bonate and in three hours if sodium carbonate was used. A. Brukl and.M. Behr (5) recommend iodic acid as an oxidant for hypophosphite. They give the following.reactions; 5H3P02 + hHIOB ~—>, $131383 + 2H20 + 12 5H3P03 1- 2HIo3 ———+ 5H3P0h + H20 + 12 Using the iodic acid Brukl and Behr claim gives them a double check method. The solution is boiled and the liberated iodine .10- is distilled over into a potassium iodide solution where it can be titrated with a standard sodium thiosulfate solution. At the same time potassium iodide can be added to the original solution remaining in the flask, and the liberated iodine titrated.with a standard sodium.thiosulfate solution. L. wolf and'W. Jung (39) found that it was impossible in a nautral solution, to oxidize phosphite to phosphate in the pres- ence of hypophosphite. If it was desirable to oxidize both the hypophosphite and phosphite, the iodine solution was first made acid with sulfuric acid and allowed to stand until the hypophos- phite was oxidized to phosphite. At this point sodium bicarbonate was added until the solution was made neutral after which oxida- tion to phosphate takes place. V. Hovorka (12) recommends the use of potassium iodate and mercuric chloride in an atmosphere of carbon dioxide. D. Raquet and P. Pinte (29) using iodine, make two separate determinations for a mixture of hypophosphite and phosphite. They determine the hypophosphite with iodine in an acid solution and the phosphite with iodine in a neutral solution. The phos- phite is determined first by adding a warm borax solution to the reaction mixture and setting aside for forty-five minutes. The solution is acidified with acetic acid, potassium iodide is added and the liberated iodine is titrated with a standard sodium thiosulfate solution. For the hypophosphite determina- tion hydrochloric acid is added to the reaction mixture and heat .11.. from a steam bath is applied for one hour. At the end of one hour the solution is cooled and a warm borax solution is added and the same procedure prescribed for the phosphite determina- tion is followed. H. R. Bond (3) made a study of the method of Raquet and Pinte (29) and found the method gave results twenty percent too low. TWith a longer digestion period 92% of the hypophosphite was oxidized to phosphate. J. Kamicki (16) found the rate of oxidation of hypOphos- phite to phosphite by iodine was proportional to the sulfuric acid concentration. A. Benrath and K. Ruland (2) oxidized hypophosphite to phosphite using ceric sulfate as the oxidant. .12... PREPARATION OF POTASSIUM HYPOPHOSPHITE A series of comparisons of analytical methods for the volumetric oxidation of the hypophosphites was run on potassium hypophosphite. A commercial salt (Baker's C.P.) was recrystal- ized, to insure purity, and made up in .0250 M solutions for the analysis. The potassium salt was chosen in preference to the sodium hypophosphite because it is an anhydrous salt. It was found by experiment that approximately 200 grams was the maximum amount of potassium.hypophosphite that could be put into solution in 100 mls of water heated just to boiling. This proved not to be the best method for the recrystallizing of the salt, however, as the yield after one recrystallization is only 15% by weight of the original 200 grams. The next method tried, was that of dissolving the potass- ium hypophosphite in a hot alcohol solution and recrystallizing it in a cold alcohol solution. In this manner it was found, that the maximum weight that could be dissolved was approximately 60 grams in 100 mls of 95 percent alcohol. The yield after one recrystallization was twice that of the first method mentioned, or 30% by weight of the original 60 grams of potassium hypophos- phite dissolved. Procedure for Recrystallization of Potassium Hypophosphite Heat one hundred.milliliters of distilled water in a 250 ml beaker, to a temperature just below boiling. iMaintain this -13- temperature throughout the procedure up to and including the filtration. At the same time weigh on the rough balance, in a beaker, or watch glass, 200 grams of the commercially pre— pared potassium hypophosphite. When the water has reached the proper temperature, add, with constant stirring, approximately 25 gram.portions of the potassium hypophosphite, making sure each time that the salt has all gone into solution before the next portion is added. When the potassium hypophosphite has all been added the solution becomes quite viscous. It is im- portant at this point to continue stirring to prevent any cry- stals from forming before filtration. The syrupy solution is quickly transferred to a hot water funnel and filtered into 600 mls of redistilled ethyl alcohol. Crystal formation takes place almost immediately. The contents are set aside in the refrigerator for 12 hours to allow for complete precipitation. As was indicated earlier the yield was not good by this method and for this reason it was not repeated. 3 Procedure for Recrystallization of Potassium Hypophosphite dis- EBIvedhin hot alcohol In this method, an all-glass reflux unit was used with a continuous stream,of nitrogen blown into the system to keep it free from oxygen. One hundred milliliters of redistilled ethyl alcohol was placed in a 500 ml flask which was then attached to a conden- sor by means of ground glass joints. The alcohol was heated —lh- with a glass col mantle, to a boiling temperature. At this time, the previously weighed commercial potassium.bypophosphite (60 grams) was quickly introduced into the alcohol and refluxed for 20 minutes. The nitrogen bubbling through the alcohol also served as a stirring effect. After 20 minutes the flask was quickly disconnected and the solution filtered through a hot 'water filter into 600 ml of ethyl alcohol at room temperature. Crystal formation starts immediately. The solution is set aside in the refrigerator for twelve hours to allow complete precipita- tion to take place. The crystals are filtered through a buchner funnel and air dried, on porous plates, until they tumble freely. They are then placed in glass stoppered bottles for keeping. Tests for the presence of phosphite at this time were posi- tive, indicating that some oxidation from hypophosphite to phosphite had taken place during the procedure. Phosphite was found to be present in amounts ranging from 1% to 2%. A sample of potassium.hypophosphite, weighing approximately 2 grams, was placed in a drying oven for a number of hours. The oven temperature was set at 1100 for the first few hours and then increased to 130°. To ascertain the loss in weight, the sample was weighed hourly; the maximum loss in weight occurred after 11 hours heating at 130°. There was no further change in weight after heating for 55 more hours at the same temperature. When the temperature was increased above 150°, on another sample, decomposition took place. -15- Several references list potassium hypophosphite as a de- liquescent salt. In order that it might be known what to expect 'when'weighing such a salt, an experiment was performed on a pre- viously dried salt. The cap was removed from the weighing bottle containing the potassium hypophosphite, leaving a surface of the salt exposed to the air. The weighing bottle was placed on an analytical balance during the exposure period, and weighings were made at one minute, five minute and fifteen minute intervals for a time totaling one hour. During the first half hour the gain in 'weight due to moisture equaled 0.5 milligrams. At the end of one hour the total gain in weight equaled 11 milligrams. As indi- cated above there was only a small surface area exposed to the air. When this same experiment 'was tried with dryvcrystals placed on a watch glass, the gain in weight after the first few minutes was so rapid, a true ‘weight could not be obtained on the balance. This indicated that if samples are weighed by difference 'with a minimum of surface area exposed there should be no error in weighing due to the deliquescence of the potassium hypophos- phite. For the comparisons, a .0250 h solution of potassium hypo- phosphite was used. -16... Procedure A 2.6023 gram.samp1e of potassium hypophosphite was weighed by difference on the analytical balance. This sample was trans- ferred to a one liter volumetric flask and diluted to the mark 'with distilled water. The solution was shaken thoroughly for five to ten minutes, and was then ready for use. Fresh solutions for analysis were prepared after a maximum of h8 hours inasmuch as test for phosphite showed an increase over the original 1% to 2% present after this time. -17- PREPARATION OF SODIEH HYPOPHOSPHITE Several of the comparison methods of analysis for the hypophosphites were run on a commercial preparation (Baker's C.P.) of sodium hypophosphite which, to insure purity, had been recrystallized twice. Oxidation.methods for the determination of hypophosphite should apply equally well to sodium or potassium hypophosphite. There is a difference however in the physical state in which the two salts exist. The potassium hypophosphite can be dried to the anhydrous state, while the sodium hypophosphite exists as a monohydrated salt and cannot be completely dehydrated as shall be indicated later in the report. i It was found by experiment, that approximately 300 grams of the sodium.hypophosphite was the maximum amount that could be easily put into solution in 100 ml of water heated just to boiling. In the first recrystallization 80% by weight of the ori- ginal material used was recovered. This is compared to the 30% recovery for the best recrystallization method for potassium hypophosphite which could bnly be recrystallized once due to such poor recovery. The second recrystallization yielded a 58% by weight recovery of the original sodium hypophosphite. -18.. Procedure Heat one hundred milliliters of distilled water in a 250 ml beaker just below boiling. haintain this temperature throughout the procedure up to and including the filtration. At the same time weigh out in a beaker or large watch glass, on the rough balance, approximately 300 grams of the commercially prepared sodium hypophosphite. When the water has reached the proper temperature, approximately 25 gram.portions of the sodium hypop- hosphite are added with constant stirring. 'Making sure each time before adding more that the salt has gone into solution. This should be quite rapid until almost all of the 300 grams have been added. At this time the solution becomes quite visc- ous and it is important that the stirring be kept up to prevent the crystals from settling out in the beaker. 'When the last of the salt has been added and the solution is clear it is quickly transferred to a hot water funnel and immediately filtered into 600 ml of redistilled ethyl alcohol which is at room temperature. Crystal formation takes place almost immediately. The alcohol 'with the filtrate in it is set aside in the refrigerator for 12 hours to allow for complete precipitation. This procedure is re- peated for the second recrystallization. At the completion of the second recrystallization and 12 hours digestion period, the crystals were filtered through a buchner funnel and then air dried on porous plates until they tumbled freely, at which time they were transferred to glass stoppered bottles. -19- Tests for presence of phosphite were made immediately after completion of the drying and again some months later. The test for phosphite proved to be negative each time. Mellor states that sodium hypophosphite can be made nearly anhydrous at 200°C. Having previously heated some of the recrystallized salt at 150°C. and detecting the odor of phosphine, which is indicative of decomposition, it was de- cided to attempt drying at lower temperatures. Three temperatures, with a total range of 60°, were chosen to work with; they are 75°C, 105°C, and 135°C. The sample dried at 1350C gave the customary evidence of decom- position after 6 hours. The two remaining samples (i.e.) one drying at 75°C. and the one drying at 10500., were weighed at intervals up to 118 hours. The theoretical amount of water present in the monohydrated sodium.hypophosphite is equal to 16.98%. The amount of water lost due to drying for 118 hours 'was equal to 1h.69% for the sample at 75°C and 1h.95% for the sample at 105°C. These two samples were again heated at the same temperatures for a total of 200 hours with no signifi- cant change in weight. Some oxidation had taken place through over such a long period of exposure to heat and air as is evi- denced by the following when phosphite was tested for. -20.. Sample heated at 75°C for 200 hours Heq of I2 used Heq_of I2 recovered % phosphite 2.0968 2.0580 1.85 Sample heated at 105°C for 200 hours 2.0968 2.0590 1.80 This indicated that at the best there is still 2% water left in the sodium hypophosphite after 200 hours at 105°C, and if this last 2% were to be removed it would require higher temperature or longer heating periods, both conditions under which sodium hypophosphite is unstable. The preceding evidence indicated that it is not practical to gry to obtain anhydrous sodium hypOphosphite. For this reason then, the monohydrated sodium hypophosphite was used in a series of comparisons of analytical methods. Six liters of a .0250 M solution of sodium hypophosphite monohydrate were made up and stored in a pyrex bottle under an atmosphere of nitrogen. Periodic test of the solution for the presence of phos- phite proved negative. To insure complete absence of oxygen the storage bottle after filling was tightly stoppered and sealed with wax. The interior was then flushed several times with nitrogen which in turn had been passed through two strong caustic solutions of pyrogallol. -21... Procedure An eight liter pyrex bottle was fitted with a three-hole rubber stOpper. In one hole was fitted an all glass siphon, in the second hole a short glass stem with a piece of rubber tubing which acted as a safety valve in case the pressure from the nitrogen was too great. The third hole was fitted with glass tubing leading back to two bottled filled with the caustic pyrogallol solution. These bottles were in turn connected with the source of nitrogen. Three samples of 5. 13h grams each are weighed by differ- ence on an analytical balance, and transferred to separate two liter volumetric flasks. The samples are then diluted to the mark on the flask and shaken thoroughly before transfer to the pyrex storage bottle. Again after the three solutions are com- bined in the large bottle they are shaken very thoroughly from five to ten minutes before the final connections with the nitrogen and siphon are made. 'When the stopper with the siphon and nitrogen tubes is in place it is secured with copper wire and then melted wax is poured around any possible source of leakage. The system as has been mentioned before is flushed out several times with nitrogen and is then ready for use. The Wolf and Jung (39) method of testing for phosphite in presence of hypophosphite is carried out periodically. If no phosphite is present the solution is considered to be good. -22... OXIDATION OF SODIUM HYPOPHOSPHITE WITH IODINE Rupp and Finck (32), Boyer and Bauzil (h), and Wolf and Jung (39) used iodine in acid solution to oxidize the hypophos- phite to phosphite, followed by iodine in sodium bicarbonate solution to complete the oxidation to phosphate. The same procedure recommended by the above investigators was followed here. Procedure Twenty ml of .0251M solution sodium hypophosphite and a standard solution of iodine approximately 0.1N were pipetted into 250 ml iodine flasks. 5 m1 of hN sulfuric acid was added to each flask which was then tightly stoppered and set aside over night. At the end of approximately 12 hours each flask was opened and enough sodium bicarbonate was added to neutralize the solution. One gram excess of sodium.bicarbonate was added to each flask which was stoppered and set aside for one hour. The solution was acid- ified, at the end of the hour, with 15 ml of 30% acetic acid and the remaining iodine titrated with a standard solution of sodium thiosulfate. Freshly prepared starch was used as an indicator. Blanks were carried along with the regular reaction. There was no gain or loss of iodine over the twelve hour period. -23- The results are as follows: 2.0080 2.0080 2.0080 2.0080 2.9080 2.0080 2.0080 2.0080 2 -used heq of H 2 1.9808 1.9859 1.9808 1.9653 1.9550 1.9787 1.9777 1.9705 —2h- P02-oxidized % HZPO2 oxidized -*98.65 98.90 98.65 97.87 97.37 98.56 98.52 98.13 OXIDATION OF HYPOPHOSPHITE USING POTASSIUM IODATE IN SULFURIC ACID SOLUTION A. Brukl and.H. Behr (5) used iodic acid for the oxidation of hypophosphite to phosphate. The reaction is as follows: 15 H3P02 + 12 H103.-_-,15'83203 6 H20 + 6 12 15 H3PO3 + 6 HIO3s—~o'l5 H3P0h + 3 H20 + 3 I Procedure Twenty4m1 of .02h9h potassium.hypophosphite and no ml of 0.1000N potassium iodate solution were pipetted into 250 ml iodine flasks. Ten.ml of 6N sulfuric acid was added to each flask which was stoppered immediately. The flasks were allowed to stand one hour at.room temperature. At the end of this period they were heated to drive off all the excess iodine. Potassium iodide was added to the solution and the liberated iodine was titrated with a standard sodium thiosulfate solution. Freshly prepared starch was used as indicator. 1 Heq H2P02'used heq H2P02- oxidized % HZPOZ- oxidized 1.9920 1.2339 61.9h 1.9920 1.0800 58.21 1.9920 .9921 h9.80 1.9920 1.1t60 57.h9 OXIDATION OF POTASSIUh HYPOPHOSPHITE USING POTASSIUM BROLATE IN HYDROCHLORIC ACID SOLUTION Schwicker (36) suggests a method for the determination of hypophosphite whereby enough hydrochloric acid is added to the hypophosphite-bromate mixture to bring it up to 1N. Procedure: Twenty ml of a .0251N solution of potassium hypophosphite and hO ml of 0.1000N potassium bromate were pipetted into 250 ml iodine flasks. Sixty ml of hydrochloric acid was added to each flask, and the flask was immediately stoppered. A saturated potassium iodide solution was placed in the gutters. The flasks were allow- ed to stand over periods ranging from one hour to twelve hours at room temperature. The potassium iodide was run into the flask and the amount of potassium'bromate remaining determined by titrating the liberated iodine with a standard solution of sodium thiosulfate. Freshly prepared starch solution was used as indicator. Blanks were run under the same conditions outlined above. There was no loss of bromine at any time. Heq,H2P02' used Time Heq H2P02-oxidized % oxidized 2.0880 -1 hour 1.5790 75.62 2.0880 1 hour 1.5857 75.9h 2.0880 12 hours 1.6208 77.62 2.0880 12 hours 1.7351 83.10 2.0880 12 hours 1.6903 81.00 -26- OXIDATION OF SODIUM HYPOPHOSPHITE WITH POTASSIUN BRQ'ATE AND SULFURIC ACID Schwicker (36) states, that sodium hypophosphite can be quantitatively oxidized, in a short period of time, by potas~ sium bromate in a sulfuric or hydrochloric solution. The procedure recommended.by Schwicker was used in this comparison. Procedure Twenty m1 of .0251M solution of sedimm hypophosphite and no m1 of a 0.1000N solution of potassium bromate were pipetted V into 250 ml iodine flasks. Five ml of hN sulfuric acid was added to each flask. The flasks were heated just to boiling and the flame was removed. The flasks were set aside for forty—five minutes after which time they were heated again to boiling to drive off all excess bromine. They were cooled, 3 grams of potassium iodide was added to each flask and the remaining bromate titrated iodometri- cally using a standard sodium thiosulfate solution. Freshly prepared starch solution was used as indicator. Blanks were carried through the same conditions and no loss of bromate was found. The results obtained were as follows: Meq of HZPOZI used Meq of H2P02-oxidized % H2P02- oxidized 2.0080 2.0857 103.86 2.0080 2.0771 103.hh 2.0080 2.0788 103.53 2.0080 2.0728 103.22 -27- OXIDATION OF SODILN HEPOPHOSPHITE WITH BRONATE- BRO IDE IN SULFURIC ACID Schwicker (36), Jenkins and Eruning (15), and Rosin (31) recommend the use of a bromate-bromide mixture catalyzed with sulfuric acid. The procedure as recommended was carried out for this comparison. Procedure Twenty m1 of .0251M solution of sodium hypophosphite and hO m1 of 0.1000N potassium.bromate were pipetted into 250 ml iodine flasks. One gram.of potassium bromide and 5 m1 of hN sulfuric acid was added to each flask. The flask was immediately stoppered. A saturated potassium iodide solution was placed in the gutters. The flasks were set aside, at room temperature, for one hour. At the end of this period they were carefully opened and the potassium iodide solution was allowed to run down into the flask. Here as a precautionary measure against losing any of the escap— ing gas, the flasks were placed in ice water which reduced the pressure and sucked the potassium iodide from the gutters into the flasks. The remaining bromine was titrated iodometrically using a standard sodium thiosulfate solution. Results obtained were as follows: Meq of H2P02'used Neq of H2P02- oxidized % of HZPO -oxidized 2 2.0080 2.0h70 101.9h 2.0080 2.0521 102.20 2.0080 2.0655 102.86 2.0080 2.0hh9 101.8h -28- XIDATION 0F SODIUh HYPOPHOSPHITE WITH SODIUM CHLORITE Sodium chlorite does not react with sodium hypophosphite in either neutral or alkaline solution. The original amount of sodium chlorite used as an oxidant was always recovered in the final titration regardless of time or other conditions. Sodium chlorite is unstable in acid solution so this was not tried. Procedure Twenty ml of.0251N sodium hypophosphite and NO m1 of approxi- mately 0.1N sodium chlorite were pipetted into 250 ml iodine flasks. To make the solution alkaline, 5 m1 of concentrated sodium hydroxide was added to each flask and the flask tightly stoppered. To make the solution neutral 1 gram of sodium bi— carbonate was added to each flask, and the flask tightly stoppered. The flasks were then set aside for times varying from one hour to twelve hours. -29- OXIDATION OF SODIUN HYPOPHOSPHITE WITH SODIUM HYPOCEEORITE Schwicker (36) used sodium hypochlorite in a sodium bicarbonate solution to oxidize phosphite in the presence of hypophosphite. Davey and'Nurtz (6) oxidized hypophosphite qualitative- ly to phosphate using hypochlorite. They did not state the conditions. Sodium hypophosphite can be quantitatively oxidized to phosphate using sodium hypochlorite in a sulfuric acid solu- tion. As a source of sodium hypochlorite a commercial bleach Chlorox (Chlorox Chemical Company, Oakland, California) was used. One hundred ml was diluted to 1 liter to give an approxi- mately 0.1N solution. The stability of this solution in'a brown bottle had previously been worked out in another thesis. Sodium hypophosphite was allowed to react with sodium hypochlorite under conditions ranging from alkaline to neutral to acid. Procedure Forty m1 of a phosphate buffer solution (pH 8.5) was introduced into a 250 ml iodine flask. Twenty ml of .0251M solution of sodium hypOphosphite and_25 ml of a standard sodium hypochlorite solution, approximately 0.1N, were pi- petted into the flasks containing the buffer solution and the flasks immediately stoppered. -3o- A saturated potassium iodide solution was placed in the gutters. The flasks were set aside for times varying from one hour to twelve hours at room temperature. The amount of hypochlorite remaining was determined by allowing the potassium iodide to run into the flask, acidify- ing with acetic acid and titrating iodometrically with stan- dard sodium thiosulfate solution. In each case the original amount of hypochlorite used was recovered. There was no reac- tion between hypophosphite and hypochlorite. heq H2120 "used time iieq H2130 ”oxidized 7% H2P0 'oxidized 2 2 2 2.0080 1 hour 0.0000 0 2.0080 2 hours 0.0000 0 2.0080 12 hours 0.000h 0 The next attempt at oxidation with hypochlorite was tried in a neutral solution. Procedure Twenty ml of .0251M solution of sodium hypophosphite and 25 ml of standard sodium hypochlorite solution, approximately 0.1N, were pipetted into 250 m1 iodine flasks. 1 gram of sodium bicarbonate was added to each flask which was immediately stoppered and set aside at room temperature for one hour. A saturated solution of potassium iodide was placed in the gutter of each flask. This was allowed to run into the flask upon opening, and the remaining hypochlorite was determined. This was titrated iodometrically using a standard sodium thio- sulfate solution. -31- The results obtained were as follows: 11eq of H P0 ’used heq H PO ' oxidized ,3 H P0 " oxidized 2 2 2 2.0080 .5608 27.92 2.0080 .h893 2h.31 2.0080 .6122 30.hh These results indicate that phosphite may be present, (36), however'when the original hypophosphite solution was tested for phosphite using the method of Wolf and Jung (39) no phosphite -was found. Before trying hypochlorite in acid solution it was necessary to check it's stability in acid solution. Procedure Twenty m1 of water and 20 m1 of sodium hypochlorite solution were pipetted into iodine flasks. Ten m1 of 6N sulfuric acid was added to each flask which was immediately stoppered and set aside at room temperature for 12 hours. This gave a solution approxi- mately 1.5N with respect to sulfuric acid. The results were as follows: Meq of NaClO used Neq of NaClO recovered 3.2979 3.2979 3.2979 3.2979 3.2979 3.2979 This particular acidity was chosen because in all previous experiments where a halogen oxidant has been used the acidity has been IN. -32- Procedure Twenty m1 of .0251N solution of sodium hypophosphite and 25.00 ml of a standard solution of sodium hypochlorite, approxi- mately 0.1N were pipetted into 250 ml iodine flasks. 10 m1 of 6N sulfuric acid 'was added to each flask which in turn was immediately tightly stoppered and set aside at room temperature for one hour. A saturated potassium iodide solu- tion was placed in the gutters. At the end of the hour standing time, the flasks were carefully opened.%* The potassium iodide solution was allowed to run into the reaction solution and the remaining hypochlorite was determined iodometrically using a standard sodium.thiosulfate solution. Neq of H2P02'used Esq of H2P02’oxidized 3 H2P02‘oxidized 2.0080 2.0139 100.29 2.0080 2.0100 100.09 2.0080 2.0102 100.10 2.0080 2.0165 100.31 .iNote: There is considerable pressure built up inside the iodine flask during the reaction. To avoid loss, due to the sudden release of pressure upon opening, the flasks were placed in ice water. A ten percent potassium iodide solution placed in the gutter be- fore opening will be sucked down into the flask by the reduced pressure. The same procedure outlined on the preceding page was followed with the exception of the time factor. This was varied over periods from 15 minutes to 12 hours. Oxidation is incom- plete prior to h5 minutes, but from h5 minutes up to 12 hours, the time of standing has no effect on the oxidation. This is indicated in the following results: Neq H2P02"used Time heq H2P02'oxidized % H2P02'oxidized 2.0080 15 Min 1.7580 87.35 2.0080 15 hin 1.78h1 88.88 2.0080 30 hin 1.90h5 9h.8h 2.0080 30 Min 1.9516 97. 31; 2.0080 h5 hin 2.0100 100.09 2.0080 h5 hin 2.0102 100.10 2.0080 12 Hrs 2.0086 100.00 2.0080 12 Hrs 2.0076 99.98 It was found by experiment, that in all cases where the excess of hypochlorite solution present was less than 50% of the total amount necessary for oxidation of hypophosphite to phosphate the oxidation was incomplete. Hypochlorite present in amounts in excess up to 100% of the total amount necessary for oxidation had no harmful effect. SUITEARY Potassium.hypophosphite and sodium.hypophosphite are in- expensive and readily obtainable on the commercial market. It is for this reason the commercial salts were used in the pre- ceding work in place of laboratory preparations. Under similar conditions pertaining to the dissolving of sodium hypophosphite and potassium.hypophosphite, and to the recrystallization of the two salts, experiment proved that potassium hypophosphite was less soluble and gave a smaller per- cent yield than the sodium.hypophosphite. Test for oxidation to phosphite during the above procedures showed the potassium salt to have been oxidized while the sodium hypophosphite was not. The sodium hypophosphite did however show a positive test for phosphite upon heating in an attempt to dehydrate it. To run analyses on potassium hypophosphite whereby it was oxidized all the way to phosphate, it would first be necessary to determine accurately each time the amount of phosphite present. In view of this fact, only those analyses of the potassium hypophosphite which were definitely incomplete as far as oxidation to the phosphate is concerned, are presented. To avoid.making a primary analysis for phosphite it was necessary to obtain a phosphite-free salt. From the above it can be seen that the only salt of this type is the monohydrated sodium hypophosphite. In all analyses where sodium hypophosphite 435- , was used, unless otherwise stated, it can be assumed to be the monohydrated salt. Seven types of volumetric oxidations were tried during the course of the work. The first five of these had previously been worked out and reported in the literature as reliable methods. (1) (2) (3) (h) (S) Oxidation with iodine in first and acid solution and then neutral solution. The best results ob- tained were approximately 98% oxidation from hypophos- phite to phosphate. Oxidation with potassium iodate in sulfuric acid solution. The best results obtained ranged from h9% to 61% oxidation from hypophosphite to phos- phate. Oxidation with potassium.bromate in hydrochloric acid solution. The best results obtained were approximately 77% oxidation from hypophosphite to phosphate. Oxidation with potassium bromate in sulfuric acid solution. The best results obtained were approxi- lmately 103% oxidation from hypophosphite to phos- phate. Oxidation with a bromate-bromide mixture in sul- furic acid solution. The best results obtained were 102% oxidation from hypOphosphite to phosphate. -36- (6) (7) Oxidation with sodium chlorite in either a neutral or an acid solution. The results were negative. There was no reaction. Oxidation with sodium hypochlorite in sulfuric acid solution. The results, when certain minimum require- ments were satisfied as indicated in the outline of the method, always gave a 100% oxidation from hypophos- phite to phosphate. -37.. 16. 17. 18. 19. 20. BIBLIOGRAPHY Amat, h. L., Compt. rend., 111, 676 (1900). Benrath, A., Ruland, K.ZAnorg. Allgem. Chem. 11h, 267-77 (1920). '_" Bond, H. 111., J. Assoc. Official Agr. Chem., 22, 516 (1936). Boyer, and Bayzil, J. Pharm. Chem., 18, 32l-3h (1918). Brukl, A. and Behr, H., Z. Anal. Chem. 6h, 23-8 (l92h). Davey, H., Phil. Trans., 192, DDS (1812) and.198, 316 (1818). Dickerson, J. S. and Snyder, J. P., J. Am. Pharm. Assoc., §. 99-100 (1919). Dulong, P. L., 11cm d'arcveil _3_, hos (1817). Cailhat, Bull. Soc. Chem., 35, 395 (1901). Gall, H. and Ditt, 11., 2. Anal. Chem., 8_7, 333-8 (1932). Hoffman, K. A., Ber. E5, 3329 (1912). Hovorka, V., Chem. Listy. 26, 19-26 (1932). Ionesco, A., Nartin, and Popesco, H., J. Pharm. Chem. (8) 13. 12-9 (1931). Jean, Bull. Soc. Pharm. Bordeaux, 68, 239-h3 (1930). Jenkins, G. and Bruning, C. F., J. Am. Pharm. Assoc. 25, Kamicki, J., Roczinski Chem. 16, 199-206 (German Summary) (1936). "' Komaroski, A. G., Filinova, V. F. and Korenman, I. 1., J. Applied Chem. (U.S.S.R.) 6, 7112-8 (1933) Z. Anal. Chem. 29. 321-8 (1931). Kolthoff, 1.11., Pharm. week blad _5__3_, 909-16 (1916). Kolthoff, I. m., Pharm. Neekblad 61, 95h-60 (192a) Kolthoff, I. H., Z. Anal. Chem. 62, 36—8 (1926) -38- 21. 22. 23. 27. 32. 33. 3h. 35. 36. 37. 38. 39. 110. hl. Kolthoff, I. P., and Furman, N. H.,"Volumetric Analysis" Vol. II, New York, John Wiley a Sons,(l929). Kosgegi, D., Z. Anal. Chem., 681 216-20 (1926) hanchot,‘fl., and Steinhauser, F., Z. Anorg. Allgem. Chem. 138, 301-10 (1921) Harino, L. and Pellegrini, A., Gazz. Chem. Ital. 12, I, h9h-7 Paquelin, N. and Joly, Comp. rend., 86, 1505 (1878). Polke, Pharm. Journ. (3) 5, h25 (187h). Pound, J. H., J. Chem. Soc., 307 (1982). Rammelsberg, Sitzber Akad. Berlin, 111, 576 (1872). Raquet, D. and Pinte, P., J. Pharm. Chem. 18, 5-10 (1933) Rose, H., Pogg. Ann. 2, 225, 361 (1827). 8 Rosin, J., ”Standard and Tests for Reagent Chemicals", New York, D. VanNostrand 00., (1937). Rupp, E., and Finck, A., Ber., 25, 3691-93 (1902). Rupp, E., and Kroll, Arch. d. Pharmaz. 219, h93 (1911) Saint-Giles, P., Annales de chimie de physique III, LV, 376 (1859). Schulz, P., Arch. Ex. Path. 18, 178 (188h). Schwicker, A., z. Anal. Chem. 119, 161—8h (1937). Stamm, H., Angela) Chem. 11, 791-5 (19311) Viebock, F. and Fuchs, K., Pharm. Nonatsh. 15, 37-9 (193h) Nelf, L. and Jung W., Z. Anorg. Allgem. Chem. 291, 337-60 (1931). Nurtz, Compt. rend., 18, 702 (lth). Zivy, L., Bull. Soc. Chem. 39, h96-50 (1926). _39- #09527 '47 7.2321? .2 "3? '- ii 731“ 2 5 ‘53 AUG 1 5 '53 q... a A. 7 .0. m_P ’1 g.) llllllIllllIIIIIIIIIIIHIIIIIIIIIIIIIIIIIIIII’IIIIIIIIIIIIIllIlll 31293 02446 8112