Abstract:
Pressure sensitive imaging materials are colorless until pressure addressed, but thereafter provide an intense dark image. The materials comprise white ferric organophosphate, ferric organophosphinate, or ferric organophosphonate and a colorless chelate. The choice of substituents on the chelate nucleus can give images with both good discrimination visually and to near infrared radiation (NIR).

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     This invention relates to carbonless materials. More particularly it relates to colorless pressure sensitive layers on substrates. Many existing compositions exhibit a yellow or brown color cast which is caused by the color of the reactive metal compounds contained therein. This invention uses compositions containing colorless iron salts which are reactable at room temperature to give a visible image. 
     In commercial applications, pressure sensitive labels are sought which not only provide visible images but which are also capable of being read by optical scanners using near infrared radiation (NIR). The images resulting from reacting the colorless iron salts with chelates having certain substituents exhibit good discrimination both visually and to NIR. 
     2. Background of the Art 
     For many years heat and pressure sensitive imaging sheets have been used for copying and labeling. Many of these materials involve the mixing of two or more physically separated reagents to cause a color forming reaction. Several general classes of color forming reactants have been used, of which two common ones are (a) leuco lactone or spiropyran compounds reactable with phenolic compounds (e.g. U.S. Pat. Nos. 3,829,401 and 3,846,153) and (b) heavy metal salts of organic acids reactable with ligands to give colored complexes (e.g. U.S. Pat. Nos. 2,663,654, 3,094,620, 3,293,055, 3,953,659, 4,334,015, 4,513,302, 4,531,141, 4,533,930 and 4,602,264). 
     Commercial preference for the heavy metal salt class has often resulted from the high stability and near black color of the images produced (U.S. Pat. No. 4,531,141). Of the heavy metals used, iron, nickel, and cobalt are common and ferric iron appears to be preferred (U.S. Pat. Nos. 2,663,654, 3,953,659, 4,531,141, 4,533,930 and 4,602,264). 
     The objection raised to the ferric salt phenolic ligand systems is the colored nature of the unreacted ferric salt. This has led to the use of white fillers (U.S. Pat. No. 4,531,141) or other incident light scattering devices (e.g., &#34;blushing&#34; the surface of the layer as in U.S. Pat. No. 3,953,659) to reduce the observed color tint of the coated layer. 
     Recently, there has been interest in obtaining reactive iron salts which are colorless and which give sharp, high density images when reacted with a colorless ligand. Organophosphates of ferric iron are known in the art to be amongst the few colorless ferric salts (Smythe et al., J. Inorg. Nucl. Chem., 30 1553-1561, (1968)). In U.S. Pat. Nos. 4,533,930 and 4,602,264 it is disclosed that such organophosphates, and the equivalent thiophosphates, can react with a variety of ligands under the influence of heat or pressure to give colored results. Ferric salts of organophosphinic acids and organophosphonic acids are included in those disclosures. Some of these organophosphates and many of the thiophosphates have some color cast before reaction which appears to be obscured by the use of white filler in the compositions. In these two patents there are disclosed pressure sensitive manifold papers in which at least one of the two reactants is encapsulated as a solvent solution. When the microcapsules are burst by pressure, the reactants come into contact and immediately react at room temperature to give a colored result. These patents further disclose the use of ferric organophosphates containing organic acid moieties formed by the aqueous reaction of a ferric salt, an alkali metal organophosphate, and an alkali metal salt of an organic acid. These are disclosed as giving the initial material better &#34;color forming properties&#34; and giving better image colors (U.S. Pat. No. 4,533,930, Column 5, lines 38-39 and U.S. Pat. No. 4,602,264, Column 5, lines 7-9) than the simple organophosphates. Excess organic acid salt is disclosed as degrading the white color. It is of significance that the inventors do not consider the choice of the ferric salt used in the preparation to be important. In fact they specifically mention ferric chloride and ferric sulfate (U.S. Pat. No. 4,533,930, Column 6, lines 10-17 and U.S. Pat. No. 4,602,264, Column 6, lines 12-18) and all of their examples use ferric chloride. 
     SUMMARY OF THE INVENTION 
     This invention provides pressure sensitive imaging systems comprising reagents which are colorless and stable at room temperature but give intense dark colors when mixed together via pressure imaging. 
     The pressure sensitive imaging systems of the invention may take any of a variety of forms. However, each comprises at least two colorless reactants which are physically separated until pressure is applied, at which point they mix and react with one another at room temperature to form a visible color. Typically the imaging system comprises two substrates arranged in an overlying adjacent relationship to one another with the surface of each substrate facing the other substrate coated with a layer containing a different one of two color-forming coreactants. The reactant containing layers may be solid or liquid and may consist of reactant alone or a solution or dispersion of the reactant. Furthermore, liquid solutions and dispersions of reactant may be encapsulated in pressure-rupturable microcapsules dispersed throughout a layer of film-forming binder material coated on the surface of the substrates. Alternatively, liquid solutions or dispersions of reactant, which may be microencapsulated, may be dispersed or otherwise contained within the substrate in lieu of a surface coating. In carbonless constructions, however, usually one substrate, referred to as a receptor substrate, is coated with a solid reactant containing layer comprising reactant alone or reactant dispersed in microparticulate form in a film-forming binder material; and the other substrate, referred to as a donor substrate, is coated with a layer of film-forming binder material having microcapsules containing a liquid solution or dispersion of the coreactant dispersed throughout. 
     Additionally, the imaging system may comprise a single substrate having coated thereon or dispersed therein two reacting coreactants, provided at least one of the reactants is microencapsulated as a liquid solution or dispersion to provide the required physical separation. The reactants may be contained in a single layer or in separate overlying adjacent layers coated on one surface of the substrate. Alternatively, the microencapsulated reactant may be dispersed within the substrate and the other reactant coated on the substrate&#39;s surface, or both reactants may be dispersed within the substrate. Furthermore, if the substrate is porous, the reactants may even be coated on opposite surfaces of the substrate. 
     One of the colorless coreactants is an iron containing compound chosen from the class of ferric iron complexes in which the ligand is chosen from organophosphates, organophosphinates, and organophosphonates (hereinafter collectively referred to as organophosphates) which are colorless and which react with the second reactant at room temperature. The second reactant is chosen from the class of chelating agents having either neutral donors or at least one ionizable hydrogen, or both, and which form colored complexes with iron (III). Examples of suitable chelates include dithiophosphates, dithiophosphinates, and dithiophosphonates (hereinafter collectively referred to as dithiophosphates) and catechols, including polycatechols, characterized by being colorless. 
     Iron(III) is the preferred metal for the reaction with chelates since it is capable of oxidizing the chelate, and generating iron complexes that are both black in the visible and strongly absorbing in the near infrared. 
     The pressure sensitive receptor layers are typically coated or extruded from coating mixes using aqueous or non-aqueous solvents, which solvents enable efficient milling of the ferric organophosphates or chelates. 
     The pressure sensitive donor layers are typically coated from coating mixes containing microencapsulated coreactant in solution. 
     A principal aspect of the invention is to provide colorless pressure sensitive articles which give dark colored images upon pressure imaging. 
     An aspect of the invention is to provide colorless pressure sensitive articles which are stable at room temperature. 
     A further aspect of the invention is to provide colorless pressure sensitive materials which are stable during the process of coating and drying layers on a substrate. 
     Yet another aspect of the invention is to provide colorless pressure sensitive articles which give images exhibiting good discrimination when examined with near infrared radiation (NIR). 
     Still another aspect of the invention is to provide colorless pressure sensitive articles which give black images exhibiting good visual discrimination and also good NIR discrimination. 
     Definitions: 
     &#34;polycatechol&#34; molecules containing more than one o-dihydroxybenzene moiety, the moieties being connected by an organic or inorganic connecting link. This group includes biscatechols. 
     &#34;ferric organophosphate&#34; compounds of the form 
     
         Fe(O.sub.2 P(R).sub.2).sub.3 
    
     where R is an organic moiety such as alkyl, alkoxy, aryl, aryloxy, alkaryl, aralkyl, alicyclic groups, etc. 
     &#34;ferric dilkylphosphate&#34; as above where R is an alkyl moiety. 
     &#34;chelate&#34; in this case refers to a bidentate or polydentate ligand in which the coordinating groups can bind to the same metal ion. 
     DETAILED DESCRIPTION OF THE INVENTION 
     Carbonless transfer papers have come into wide usage over the past several years. Ordinarily, these papers are printed and collated into form sets for producing multiple copies. Impact on the top substrate causing each of the underlying substrates to form a mark thereon corresponding to the mark applied by machine key or stylus on the top substrate, without carbon paper interleaves or carbon coatings. The top substrate, on which the impact is immediately made, usually has its back surface coated with tiny microscopic capsules containing an active ingredient for mark production. A receptor substrate placed in contact with the back face of the top substrate has its front surface coated with a material having a component reactive with the contents in the capsules. When the capsules are ruptured upon impact by stylus or machine key, the contents of the ruptured capsules react with a coreactant therefor on the receptor substrate forming a mark on the receptor substrate corresponding to the mark impressed by the stylus or machine key. These self-marking impact transfer papers are designated by the terms CB, CFB and CF, which stand respectively for &#34;Coated Back&#34;, &#34;Coated Front and Back&#34;, and &#34;Coated Front&#34;. The CB substrate is usually the top substrate having its back surface coated with the microcapsules, and it is this substrate on which the impact impression is directly made. The CFB substrates are the intermediate substrates which form a mark on the front surface thereof and transmit the contents of ruptured capsules from the back surface thereof to the front of the next succeeding substrate. The CF sheet is the bottom substrate and is only coated on the front surface to form an image thereon, as no further transfer is desired. 
     As indicated above, carbonless transfer papers comprise two physically separate coreactants which react upon contact to form a dense colored image. Usually, one of the reactants is dissolved in a reaction implementing cosolvent vehicle and encapsulated in substantially pressure-rupturable microcapsules which are coated on the surface of a substrate. A solution or dispersion of the coreactant is coated on a second substrate, the copy sheet, and dried. The substrates containing the coating of microcapsules and the coating of coreactant are then placed in such a relationship to each other that rupture of the capsules will release the entrapped contents and allow the coreactants to react thereby forming a dense colored image. While it is customary to coat the capsules on the back surface of the overlying substrate and coat the coreactant for the encapsulated reactant on the front surface of the substrate upon which the image is to be copied, this procedure could be reversed if desired. Alternatively, both reactants may be encapsulated and located either on adjacent substrates in superimposable relationship or on the same surface of a single substrate. Additionally, the microcapsules are so rugged and impervious to the coreactants that microcapsules containing one reactant may be interspersed with a fluid suspension or solution of the coreactant and applied to a surface as a single coating with little danger of premature image formation. 
     Furthermore, the capsules need not be applied as layers, but may be subjected to the rigors of paper formation on a paper machine and can be directly incorporated into the paper, the capsules being carried as a filler therewithin. Similarly, the coreactant can be incorporated into a second or copy surface or may be carried adjacent to the capsules in the same web of paper. 
     Alternatively, a composition comprising a solution or dispersion of one reactant can be carried by a variety of materials such as woven, non-woven or film transfer ribbons for use in impact marking systems such as typewriters and the like, whereby the coreactant is transferred to a record surface by impact transfer means. Furthermore, a composition comprising a solution or dispersion of one of the reactants could be absorbed in a porous pad for subsequent transfer to a coreactive record surface by a transfer means such as a portion of the human body, e.g., a finger, palm, foot or toe, for providing fingerprints or the like. 
     As noted above, the color-forming composition of the present invention can be readily microencapsulated by techniques known in the art, such as those described in &#34;Microcapsule Processing and Technology,&#34; A. Kodo, Marcel Dekker, Inc. (1979); &#34;Capsule Technology and Micro-encapsulation,&#34; M. Gutcho, Noyes Data Corporation and as described in U.S. Pat. No. 3,516,941. 
     Capsules containing a reactant of the present invention may be formed from any substantially impermeable film-forming material sufficiently strong to withstand necessary handling. A suitable class of film-forming materials are aldehyde condensation polymers, particularly urea-aldehyde condensation polymers, and more particularly urea-formaldehyde condensation polymers. The capsules are preferably in a size range of from 1 to 50 microns and are preferably used in an amount from 5 to about 50 parts by weight dry capsules per 100 parts pulp when incorporated within the body of paper substrates. 
     The color-forming system of the present invention requires two coreactants, a colorless chelate such as a catechol or dithiophosphate and a colorless iron (III) organophosphate. As used herein, &#34;colorless&#34; is an indication that upon reflective or transmissive observation of the composition (depending upon the nature of the substrate upon which the composition is coated, i.e., opaque or transparent) the human eye observes a &#34;true white&#34; rather than a colored tone. For example, there would be no clear yellow, pink, or blue tones in the observed material. In the transmissive mode this would require that the composition not absorb significantly more strongly in one or more 25-50 nm ranges of the visible portion of the electromagnetic spectrum than in other 25-50 nm ranges within the visible portion of the electromagnetic spectrum. Small percentage variations are of course tolerable so long as the eye does not observe them. This is usually exemplified by having an optical density of less than 0.2 in a 50 nm range in the visible portion of the electromagnetic spectrum. These kind of measurements can readily be taken by densitomiters in reflective or transmissive mode. Some optical brighteners tend to add coloration (in particular blue) at an optical density level of less than 0.05. This is acceptable, but not preferred. Optical densities which vary in any 50 nm range within the visible portion of the electromagnetic spectrum by more than 0.1 are not preferred; it is desirable that any variation be less than 0.05. 
     It is an important feature of the present invention that the liquid employed as the solvent for the encapsulated reactant may be a solvent for the coreactant but need not be. If the liquid is a solvent for both reactants, then it serves as a reaction implementing medium for the two reactants at the time of rupture of the capsules, and is commonly referred to as a cosolvent. Examples of cosolvents include cyclohexane, tributyl phosphate, diethyl phthalate, toluene, xylene, 3-heptanone and the like. The selection of additional suitable cosolvents will be obvious to those skilled in the art. 
     U.S. Pat. Nos. 4,533,930 and 4,602,264 disclose a wide range of ferric salts of organo phosphorus oxyacids and thioacids as useful in pressure sensitive and thermographic reactions with a range of ligands. They are presented as giving much whiter backgrounds than ferric salts previously used in this art. It is clear from the examples, and confirmed from our own investigations, however, that the organothiophosphates are highly colored and dark. Furthermore, many of the examples using organophosphates, disclosed in these patents, record appreciable coloration of the compounds with whiteness levels being achieved by the use of fillers such as zinc oxide, aluminum hydroxide, and calcium carbonate. 
     This invention defines a preferred narrow range of ferric organophosphates which are entirely colorless. The structural formulae of some of these compounds (I) are encompassed generically by the disclosures of U.S. Pat. Nos. 4,533,930 and 4,602,264 without any means of providing them as truly colorless species being disclosed. Other structures within this invention are not even generically disclosed (II-IV). These compounds are dialkylphosphates, dialkylphosphinates, and dialkylphosphonates (hereinafter collectively referred to as dialkylphosphates) and have structures chosen from the general formulae: ##STR1## in which each R is selected independently from alkyl or alkoxy groups and substituted alkyl or alkoxy groups bearing substituents such as those selected from alkyl, cycloalkyl, and aryl provided that such substituents do not act as ligands or chelates for ferric ions; and X is a counterion. 
     Preferably R is selected from the group represented by the formula ##STR2## where d=0 or 1, b&gt;a, b&gt;c, c is 1 to 10, and 3&lt;a+b&lt;=18; and X is selected from F - ,PF 6   - , Ph 4  B - , BF 4   - , NO 3   - , (where Ph = phenyl). In our preferred compounds a=1, b=4, c=2, d=1 and x=NO 3   - . 
     Dialkylphosphates are the preferred ligand for iron(III) since the resulting complexes are completely colorless. If trialkylphosphates are used as the main ligand, sufficiently stable iron complexes do not form, and if monoalkylphosphates (as well as inorganic phosphates) are used, generally undesirable, extensive crosslinking occurs between metal centers such that the resulting iron organophosphate is too stable to react with the chelate. Previously used iron carboxylates typically are too highly colored and cannot produce colorless backgrounds. Mixed dialkylphosphate/carboxylate iron complexes can be made to be less colored than iron carboxylates, but they still retain undesirable color because of the presence of the carboxylate. The iron complexes of the sulfur analogues of the carboxylates, phosphates, and their mixtures are particularly undesirable since they are highly colored, even black, materials. Aromatic phosphates often provide an iron complex that is less reactive and more colored than the dialkylphosphates. 
     Ferric propyl(2-ethylhexyl)phosphinate, ferric cyclohexyl(2-ethylhexyl)phosphinate, and ferric dicyclohexylphosphinate have been made and found to be reactive with chelates. The most preferred organophosphate ligands, however, are branched chain dialkylphosphates, especially di-2-ethylhexylphosphate (DEHP). Linear chain dialkylphosphates form colorless iron complexes that give images with chelates but are generally too unreactive (too highly crosslinked) to provide sufficient image density. The branch on the main chain should be sufficiently long and sufficiently close to the metal center that crosslinking between metal centers is inhibited. On the other hand, the branch should not be too long or too close to the phosphorus center since iron that is incompletely reacted with the phosphate may result in a colored iron source. From a practical aspect, the ideal structure is illustrated by DEHP. The range for the side chain length might best be put at about 1-10 carbon atoms, the further from the connection point to the phosphorous the longer the chain. The length of the main chain is best illustrated by DEHP, that is, around 6-10 carbon atoms. Chains as long as 18 carbon atoms are the practical maximum due to the required loading necessary to achieve suitable optical density (i.e., the molecular weight of the non-image contribution of the organic moiety becomes impractically high). 
     Fe(DEHP) 3 , Fe(DEHP) 3  (NO 3 ), Fe(DEHP) 3  (HDEHP) 3  and Fe(DEHP) 3  (HDEHP) 3  (NO 3 ) are preferred in the iron organophosphate series. These are completely colorless, a major improvement over the iron carboxylates and mixed carboxylate/organophosphate iron complexes. In addition, unlike the general straight chain dialkylphosphate iron complexes, they are very reactive with the chelating ligands and particularly with the bis-catechols. The latter three are also soluble in the organic solvents used in the microencapsulation process and can, therefore, be microencapsulated on donor sheets for pressure-sensitive imaging constructions. 
     We have found that the preparation of the colorless ferric organophosphate compounds of I is not as simple as U.S. Pat. Nos. 4,533,930 and 4,602,264 suggests. Their method involves mixing aqueous solutions of an alkali metal salt of the organophosphoric acid and a ferric salt of a strong mineral acid such as hydrochloric and sulfuric acids, which results in a precipitate of the ferric organophosphate. It has been found that ferric chloride (which is preferred by these patents) gives slightly colored precipitate even with dialkylphosphates whereas those from ferric nitrate are completely colorless. The preferred preparation, therefore, uses ferric nitrate to give compounds I-IV. 
     Ferric dialkylphosphate compounds II where X = fluoride, hexafluorophosphate, tetraphenylborate, or tetrafluoroborate, may be prepared by mixing required equivalent quantities in aqueous solution of ferric nitrate, alkali metal salt of the dialkylphosphoric acid, and the alkali metal salt of the acid HX. Compounds II then precipitate. 
     When X = nitrate, however, the nitrate ion is too soluble in water to remain attached to the ferric dialkylphosphate and the result is the compound I again. However, if the ferric nitrate and dialkylphosphoric acid are dissolved in glacial acetic acid, then compound II for X = nitrate is precipitated. This compound and the fluoride may also be prepared using ethyl alcohol as solvent and adding potassium acetate or sodium fluoride to the ferric nitrate and alkali metal phosphate in required equivalent amounts. 
     Ferric dialkylphosphate compounds III and IV may be prepared by mixing together the required equivalent quantities of an aqueous solution of ferric nitrate and an organic solution of the dialkylphosphoric acid, or its alkali metal salt, and extracting into the organic solution. Alternatively, compounds III and IV may be prepared directly in non-aqueous solution. 
     The chelate compounds which we select as pressure-activated reactants with these iron compounds, are chosen to be colorless, to react rapidly with the iron compounds at room temperature and to be easily soluble in organic solvents. These colorless chelates are selected from aromatic or alkyl ligands having either neutral donors or at least one ionizable hydrogen, or both, and which react with iron (III) to form colored complexes. In this invention these chelates are preferably chosen from dithiophosphates, catechols, and polycatechols. 
     The most preferred chelates are catechols in which two catechol (specifically o-dihydroxybenzene) groups are part of the same molecule. These are illustrated in Formula V. ##STR3## where A is an organic or inorganic connecting linkage, and substituents R 1 , R 2 , R 3  and R 4  are independently chosen to modify the electronic character (donating or accepting) of the OH groups on the ring and include H. The connecting linkage may be aliphatic, aromatic, mixed aliphatic and aromatic, a fused ring, or a heteroatomic fused ring, provided that the polycatechol so produced is colorless. Some aromatic linkages have been found to give colored polycatechols and thus are precluded by the requirement that the chelate be colorless. 
     The position of the o-hydroxy chelate site relative to the connection site between the two catechol groups is not critical. Additionally, the two catechol units need not be symmetrical in their substituents or their positioning. Substituents such as --OH, --SH, and --NH 2  which contain acidic hydrogen can produce high reactivity of the o-dihydroxy substituents and are, therefore, preferred in this invention. 
     The substituent groups R 1 , R 2 , R 3 , and R 4  may serve three functions: (a) sterically constrain the molecule to enhance or inhibit interactions between the reacted metal centers, (b) modify the solubility of the catechol, and (c) modify the electronic character of the hydroxy groups by withdrawing or donating electron density to the chelating site. 
     One of the most important functions of the R groups is the control of the electronic properties of the catechol, in order to control the color of the final image. Commonly known electron donating R groups (such as alkyl, mono- or di-alkyl substituted amino, alkoxy, etc.) enable the catechol to be oxidized more readily by the iron, which is important for obtaining the infrared absorption properties (at 905 nm in particular) needed for bar code readers. A green complex results upon imaging catechols having electron donating R groups with iron. Conversely, commonly known electron withdrawing R groups (such as nitro, ammonium, halogen, etc.) inhibit oxidation of the catechol by the iron. The resulting complex will tend to remain a violet-blue. The combination of catechols containing both electron donating and electron withdrawing groups provides for an imaging construction that is able to generate both a desirable black visible image and a high contrast image in the near infrared. The connecting linkage between the catechol groups may be used to control all three functions, (a)-(c), if the R groups are built into the connecting linkage. 
     The proper choice of the substituents on each catechol in the molecule can give the desired mixture of visible and NIR absorption properties. Alternatively, the physical mixture of catechols having the different substituents can give similar results. 
     A carbonless recording donor substrate of the invention can be made in the following manner. The chelate or the organic solvent soluble ferric dialkylphosphates of (II-IV) are dissolved in an organic solvent and encapsulated by methods known in the art. The pressure rupturable microcapsules so formed are dispersed throughout a suitable binder material to form a coating composition. The coating composition is then coated on a suitable substrate and dried. A carbonless recording receptor substrate of the invention can be prepared as follows. The coreactant for the reactant encapsulated on the donor substrate is dissolved or dispersed in microparticulate form throughout a suitable solvent to form a coating composition. When the encapsulated reactant is the chelate, the coating composition may comprise solid ferric dialkylphosphate (I-II) dispersed throughout or dissolved in a solvent such as water, acetone, methyl ethyl ketone, ethanol, etc. or organic solutions of ferric dialkylphosphates (II-IV). When the encapsulated reactant is one of the organic solvent soluble ferric dialkylphosphates, the coating composition is an aqueous dispersion or solution, or an organic solution of the chelate. The coating composition is coated on a suitable substrate and dried. 
     Substrates which may be used as carbonless recording substrates are films of transparent, opalescent, or opaque polymers, paper, optionally with white or colored surface coatings, glass, ceramic, etc. 
    
    
     The following are preparative examples for the ferric dialkylphosphtes I, II, and IV. 
     EXAMPLE A 
     Preparation of Fe(DEHP) 3   
     1. The method is similar to the literature preparation of L. E. Smythe, T. L. Whateley and R. L. Werner, J. Inorg. Nucl. Chem., 30, 1553 (1968) (but using ferric nitrate instead of ferric sulfate). To 2.0 g KOH in 175.0 ml H 2  O is added 10.0 g DEHP. This solution is added over 5 minutes to 35.0 ml of water containing 4.0 g Fe(NO 3 ) 3  .9H 2  O with vigorous stirring. The mixture is stirred 10 minutes, filtered, washed in fresh water with stirring, filtered and dried under vacuum at 70° C. to a constant weight. An off-white solid is obtained. The infrared spectrum shows the expected phosphate stretches, as well as small amounts of OH, and the characteristic ethyl group presence at 1466.1 cm 31  1. 
     EXAMPLE B 
     Preparation of Fe(DEHP) 3  (NO 3 ) 
     Powdered Fe(NO 3 ) 3  .9H 2  O, 80.8 g, is dissolved in 800 ml glacial acetic acid. As soon as a clear solution is obtained, 193.0 g bis-(2-ethylhexyl) phosphate (DEHP) is added in a rapid dropwise manner with vigorous stirring. Less than a stoichiometric amount of DEHP gives a more colored product; an excess of DEHP is not disadvantageous. The white product is filtered, washed with acetic acid and dried under vacuum. The approximate yield is 84%. The product is found to be rubbery and may be recrystallized by precipitation from cyclohexane by acetone. It is important that FeCl 3  not be used since a clear yellow acetic acid solution results. 
     Alternative preparation from ethanol: To 40 ml of absolute ethanol is added 2.0 g Fe(NO 3 ) 3 .9H 2  O. Upon dissolution, 5.0 g DEHP are added, and the clear solution stirred 5 minutes. An aqueous solution of potassium acetate (0.5 g in 4.5 g H 2  O) is added dropwise. The mixture is stirred 2 minutes, filtered, redispersed in water, stirred an additional 20 minutes, filtered and vacuum dried. The infrared spectrum is identical to that prepared from acetic acid. 
     Characterization: The infrared spectrum clearly shows the coordinated organophosphate (1000-1200 cm -1 ) and nitrate (1551.0 cm -1  asymmetric stretch, the symmetric stretch is under other peaks), and the absence of Fe-O-Fe stretches. The complex is readily soluble in cyclohexane, and is an excellent film forming material when coated on a substrate (clear, colorless film). Elemental analysis is consistent with the presence of one nitrate, and confirms the 3:1 P:Fe ratio. Magnetic susceptibility determined by the Evan&#39;s NMR method (J. Chem. Soc., 2003 (1959)), demonstrates a high spin iron complex. The complex was also found to be conductive in cyclohexane solution. 
     EXAMPLE C 
     Preparation of Fe(DEHP) 3  F 
     1. To 500.0 g H 2  O is added 6.0 g KOH. To a separate 500.0 g H 2  O is added 12.0 g Fe(NO 3 ) 3 .9H 2  O followed by 0.62 g NaF. To the aqueous base solution is added 32.0 g DEHP, which is then added rapidly to the mechanically stirred iron solution. The pure white iron complex is filtered, washed and vacuum dried. 
     2. To 300 ml ethanol is added 16.13 g Fe(NO 3 ) 3 .9H 2  O. Upon dissolution, 40.0 g DEHP is added rapidly dropwise (3 minutes). The clear solution is stirred 5 minutes then 3.2 g NaF in 32 g H 2  O are added dropwise (5 minutes). The white solid is stirred, then diluted with 400 ml H 2  O, stirred 30 minutes and filtered. A colorless solid results. Elemental analysis is consistent with a 3:1:1 P:Fe:F ratio. 
     EXAMPLE D 
     Preparation of Fe(DEHP) 3  (tetraphenylborate) 
     To 1.1 g sodium tetraphenylborate and 1.0 g Fe(NO 3 ) 3 .9H 2  O in 40 ml H 2  O is added rapidly 3.2 g DEHP and 0.73 g KOH in 80 ml H 2  O. The mixture is filtered, dispersed in water, stirred, filtered and air dried. The infrared spectrum is consistent with the proposed material. 
     EXAMPLE E 
     Preparation of ferric n-propyl(2-ethylhexyl)phosphinate 
     To a solution of 25 g of n-propyldichlorophosphineoxide in 300 ml of petroleum ether, 28 g of diethylamine in 150 ml of petroleum ether was added over 4 hours. The petroleum ether was removed by distillation and the remaining n-propyl(diethylamine) chlorophosphineoxide was distilled off under vacuum. 
     The Grignard of 1-bromo-2-ethylhexane (31 g) was prepared in ether, and 26.4 g of the n-propyl(diethylamine)chlorophosphineoxide was added to it at room temperature and refluxed for 72 hours. The resulting solution was treated with 5M hydrochloric acid and refluxed overnight. On cooling the n-propyl(2-ethylhexyl)phosphinic acid was extracted with petroleum ether and distilled to give a colorless liquid (B.P.=172-180° C. at 0.12 mm Hg). 
     To 1.3 g of Fe(NO 3 ) 3 .9H 2  O dissolved in 5 g of glacial acetic acid, 2.7 g of the prepared organophosphinic acid was added. This solution was diluted with 9 parts of water rapidly. The ferric n-propyl(2-ethylhexyl)phosphinate appeared as a white solid precipitate which was filtered off, washed with water, and dried in air. 
     EXAMPLE F 
     Preparation of ferric dicyclohexylphosphinate 
     The dicyclohexylphosphinic acid was made by the method disclosed in D. F. Peppard, G. W. Mason, and C. M. Andrijasich, J. Inorg. Nucl. Chem., 27, 697 (1965). Phosphinic acid, 2.35 g, was dissolved in a solution of 0.66 g of KOH in 10 g of water. This solution was diluted with 50 ml of water and added rapidly to a solution of 1.3 g of Fe(NO 3 ) 3 .9H 2  O in 50 ml of water. A fine yellow precipitate occured which was filtered off, washed with water, and air dried to give the ferric dicyclohexylphosphinate. 
     EXAMPLE G 
     Preparation of ferric cyclohexyl(2-ethylhexyl)phosphinate 
     Using the method described in Example E, 30 g of cyclohexyldichlorophosphineoxide was used in place of the n-propyldichlorophosphineoxide to give a thick colorless oil. The white ferric cyclohexyl (2-ethylhexyl)phosphinate was obtained by the treatment described in Example F. 
     EXAMPLE H 
     Preparation of Fe[OOP(OR) 2  ] 3  [HOOP(OR) 2  ] 3  NO 3   
     To a solution of 4.04 g Fe(NO 3 ) 3 .9H 2  O in 50 ml of ethanol was added a solution containing 0.56 g KOH and 19.66 g DEHP dissolved in 100 ml ethanol. This will yield a substantially colorless solution species having the formula Fe(DEPH) 3  (HDEPH) 3 .NO 3 . 
     EXAMPLE I 
     The iron(III)-organophosphates used in the following preparations were prepared according to the preceding examples unless otherwise specified. 
     1. Encapsulation of 8-Hydroxyquinoline. A sample of 0.22 g of a polyvinyl alcohol oil dispersing agent (commercially available from Monsanto Company under the trade designation Gelvatol 40-12) is dissolved in 642 g of water. Separately, 153.3 g of a 8-Hydroxyquinoline/toluene solution (34.1 g 8-Hydroxyquinoline in 292.4 g toluene) is mixed with 26.8 g of polyphenylmethylene diisocyanate (commercially available from Mobay Company under the trade designation Mondur MR$) and then added to the water solution. After equilibrating 5 minutes at 71° F., 65 ml of tetraethylenepentamine (TEPA) is added slowly (about 1 drop/2-3 minutes) for about 15 minutes, then more rapidly (about 1 drop/15-20 seconds), then 1-2 drops per second. At this point, miroscopic investigation clearly demonstrates the presence of capsules. 
     The microcapsules prepared in 1, when broken via pressure against a receptor coated with a ferric organophosphate, such as that prepared in Example B, instantly produce a deep green-brown image. 
     2. Encapsulation of an iron(III)-organophosphate. A sample of 30.0 g Fe(DEHP) 3  (NO 3 ) is dissolved in 232 g cyclohexane. Separately, 0.5 g of Gelvatol 40-12 PVA is dissolved in 630 ml of water at 70° F. 
     TMXDI (m-tetramethylxylenediisocyanate), 126.0 g, is added to the iron(III) solution, which is then added to the water buffered to pH 2.5 with acetic acid. The Waring blender is equilibrated at 2300 rpm for 5 minutes and then a 25% solution of TEPA is added while monitoring the pH. Keeping the pH below 6 with acetic acid, the TEPA is added slowly until complete. Additional TEPA, 47.5 g, is then added to ensure encapsulation, which is verified by microscopic investigation. 
     3. Direct preparation of the iron(III)-organophosphate in organic solution. Pellets of 85% potassium hydroxide (14.55 g, 0.0735 mole) were slowly added to a stirred suspension of bis(2-ethylhexyl) hydrogen phosphate in 200 ml water. After the potassium hydroxide had dissolved, 132 g of cyclohexane was added. A solution of ferric nitrate nonahydrate (29.7 g, 0.0735 moles in about 50 ml water) was added with vigorous stirring to the above suspension. After the addition was complete, the mixture was stirred for an additional five minutes and the organic layer was separated and washed with water. Tributyl phosphate (55.6 g) and diethylphthalate (36.9 g) were then added to the capsule fill solution. Urea-formaldehyde microcapsules were prepared from the fill solution using standard encapsulation procedures. 
     A CB coating slurry was prepared by adding 10 g of the above capsule slurry to 65 g of a 1.5% sodium alginate solution. The coating slurry was applied to a coated paper using a bar coater with a 3 mil gap. The coating was allowed to dry at room temperature. 
     A CF coating solution was prepared by dissolving propyl gallate (15 g), 8-hydroxyquinoline (1 g) and azelaic acid (4 g) in 100 g of anhydrous ethanol. The coating was applied to uncoated basestock using a #4 wire wound rod and allowed to dry at room temperature. 
     When the CB sheet was brought into contact with the CF sheet and imaged with pressure, a purple image resulted. 
     4. Encapsulation of a catechol. Lauryl gallate (12.5 g) was dissolved in a solution consisting of tributyl phosphate (58.7 g), diethylphthalate (38.9  g), and cyclohexane (139.9 g). Ureaformaldehyde microcapsules were prepared from the fill solution using standard procedures. 
     A CB coating slurry was prepared by adding 10 g of the above capsule slurry to 65 g of a 1.5% sodium alginate solution. The coating slurry was applied to a coated paper using a bar coater with a 3 mil gap. The coating was allowed to dry at room temperature. 
     A CF coating solution was prepared by dissolving 20 g. of Fe(DEHP) 3  (NO 3 ) in 80 g cyclohexane. The coating was applied to uncoated basestock using wire wound rods and allowed to dry at room temperature. 
     When the CB sheet was brought into contact with the CF sheet and imaged with pressure, a purple image resulted. 
     5. Encapsulation of a catechol mixture. 6-tert-butyl-3-methylcatechol (2.93 g) and 3-isopropyl-6-methylcatechol (2.82 g) were dissolved in a solution consisting of tributylphosphate (64.7 g), diethylphthalate (43.0 g), and cyclohexane (136.5 g). Urea-formaldehyde microcapsules were prepared using the fill solution and a CB coating was prepared from the capsule slurry and applied to a coated paper as described in Example 4. 
     When the CB sheet was brought into contact with a CF sheet, prepared in a manner similar to that in Example 4, and imaged with pressure, a neutral gray (measured on the Hunter Colored Coordinates Scale) image resulted. The image showed discrimination in the NIR (image = 57%, background = 82% reflectance measured at 905 nm), comparable to that observed in the visible region (image = 46-61% reflectance from 400-700 nm).