Constituent phases and mechanical properties of iron oxide-additioned phosphoaluminate cement

Iron oxide was added to phosphoaluminate clinker and its effects on cement constituents were determined using XRD, DSC, SEM-EDS and conduction calorimetry analysis. The variations in compressive strength were also studied. The results showed that in moderate amounts, iron oxide acts as a mineraliser during clinker sintering, furthering the conversion of CA1-Y(PY) to LHss at a lower temperature than normally required for that reaction. The main constituents of iron oxide-rich phosphoaluminate clinker included LHss, CA1-Y(PY), CP1-Z(AZ) and ferrite. The EDS findings showed that the composition of the ferrite phase was nonuniform. The conclusion drawn was that by modifying the dose of Fe2O3, the composition of phosphoaluminate cement can be controlled to produce clinker and cement compliant with different mechanical strength requirements. The conduction calorimetry findings were consistent with those results.


INTRODUCTION
High aluminate cement is a special binder whose quick hardening and chemical resistance make it suitable for repairing highways, airport runways and similar.Its hydration products include CAH 10 , C 2 AH 8 , C 3 AH 6 and AH 3 .At ambient temperature, CAH 10 and C 2 AH 8 , known to be metastable, convert to C 3 AH 6 and AH 3 , lowering mechanical strength (1)(2)(3).A number of methods are in place to attenuate or prevent that conversion (4)(5)(6).Shiqun and Jiashan et al. (7)(8)(9)(10) found that a new phase containing P and Si and named LHss forms in the CaO-Al 2 O 3 -P 2 O 5 -SiO 2 quaternary system.Later research showed that the hydration products of this new phase were stable at later curing ages, an indication that including P and Si in solid solution could effectively inhibit the conversion from CAH 10 and C 2 AH 8 to C 3 AH 6 and AH 3 .Further to electron probe microanalysis findings, the chemical composition of new phase LHss is CaO•(1-X-Y)Al 2 O 3 •XSiO 2 •YP 2 O 5 , X=0.146-0.206,Y=0.048-0.081(7).This solid calcium phosphoaluminate solution deriving from monocalcium aluminate was subsequently used as the main mineral phase in the invention of a phosphoaluminate cement (PALC) with excellent mechanical properties.
In addition to the LHss, this new cement contains modified calcium phosphate (CP 1-Z (A Z )), modified monocalcium aluminate (CA 1-Y (P Y )) and a vitreous phase.The first two phases play important roles in later age cement strength development, while the latter two enhance early age hydration (11).PALC is characterised by high early age and increasing long-term strength.Its low alkalinity affords it long durability, its low porosity, high resistance to frost and penetration, and the absence of Ca(OH) 2 in its hydraulic system, resistance to carbonation (12).
The drawback is that since new phase LHss forms at over 1500 °C, producing this type of cement is highly energy-intensive.Earlier studies (13) explored the effect of oxides on LHss sintered at 1380 °C.The addition of MgO to the C-S-P-A system favours CA formation, but may inhibit LHss formation.Conversely, SO 3 may hasten the transformation of the main crystalline phases CA and C x P to LHss.Moreover, small amounts of TiO 2 further both LHss and C x P formation in the C-S-P-A system (13).The optimal TiO 2 content is 1.39 wt%, above which LHss formation is hindered.Unfortunately, however, MgO has an adverse effect on LHss formation, the SO 3 emissions generated during sintering are environmentally harmful and TiO 2 is rare.
A certain amount of ferric oxide in the raw material is known to lower the sintering temperature of portland clinker and further alite formation (14,15).In alite-sulphoaluminate cement, the addition of ferric oxide enhances free lime absorption and alite formation (16).The addition of ferric oxide also lowers the sintering temperature of alite-C 2.75 B 1.25 A 3 S cement from 1410 to 1350 °C (17) and favours the formation of sulphoaluminate clinker (18).
In light of those findings, the potential of ferric oxide to expedite LHss formation has also been studied.Wang (13) found that 4 wt% of the compound favours LHss formation at a temperature of 1380 °C.At a proportion of 5-6 wt%, however, it appears to lower the LHss content in the clinker.Inasmuch as the effect of high proportions of Fe 2 O 3 on the formation of the constituent phases of phosphoaluminate cement has not yet been studied, the impact of proportions of over 10 wt% on its formation was explored here.Its effect on the constituent phases and the hydration mechanism are also discussed.

Specimen preparation
Sinopharm Chemical Reagent Co., Ltd, 99.0% pure laboratory reagents with a fineness of at least 74 μm were used throughout: calcium carbonate (CaCO 3 ), calcium phosphate (Ca 3 (PO 4 ) 2 ), alumina (Al 2 O 3 ), silica (SiO 2 ), ferric oxide (Fe 2 O 3 ) and alcohol.All the materials were precisely weighed to the proportions specified in the phosphoaluminate cement design ( 12) and 0, 10, 11, 12, 13 or 15% Fe 2 O 3 was added to prepare specimens respectively labelled A, B, C, D, E and F. Sample G had the same composition as sample A but was sintered at a higher temperature.
The components were thoroughly blended, mixed with laboratory grade alcohol and then dried at 105 °C for 4 hours.They were subsequently pressed into round specimens measuring Φ60 mm×10 mm, sintered at 1380 °C for 2 hours (ramping the temperature at a rate of 5 °C/minute) and cooled under fast-flowing forced air.Specimen G was sintered separately at 1560 °C for 2 h, ramping at the same rate as above and fan-cooled.The seven clinkers, including specimen G, were ground to pass the No. 200 sieve.The powder was mixed with water and the resulting paste was poured into 20×20×20-mm 3 moulds for curing at 20 °C and 90% relative humidity for 1 day.After removal from the moulds the pastes were stored in water for 1, 3, 7, 28 or 90 days, at which times they were tested for compressive strength.The fragments were then immersed in alcohol to detain hydration and vacuum dried at 30 °C for further analysis.

Test methods
Clinker fineness was determined by negative pressure sieving as per Chinese standard GB/T1345-1991.The unsieved residue was held within 0.5-3 wt%.Compressive strength was determined on a 50-kN MTS CMT5504 test frame (China).XRD patterns were recorded on a Bruker D8 Advance diffractometer (Germany) fitted with a Cu Kα X-ray tube and operating a 40 kV and 40 mA.Readings were taken between 2θ angles of 5 to 60° with a step size of 0.02° and a scan speed of 0.2 s.SEM analyses were conducted on a FEI QUANTA FEG (USA) scanning electron microscope operating at 20 kV and 20 mA.The EDS findings were obtained on an Oxford Instruments INCA energy X-MAX-50X analyser (UK).A TAM Air eight-channel, thermometric isothermal conduction calorimeter was used to determine heat of hydration and heat flow.DSC data were logged with a TGA/DSC1/1600HT analyser from ambient temperature to 650 °C, ramping at a rate of 10 °C/min.

Variation in phase composition
The XRD patterns for anhydrous phosphoaluminate cement with varying Fe 2 O 3 contents sintered at 1380 °C and for two reference specimens without the oxide sintered at 1380 and 1560 °C are reproduced in Figure 1 When the Fe 2 O 3 dose was increased to 15%, however, as in specimen F, LHss formation declined.The possible explanation lies in Fe 2 O 3 's role as intermediate network oxide in partially molten clinker.At low percentages, it would act as a network modifier oxide, lowering the viscosity of the molten phase and favouring LHss formation.At an overly high content, however, Fe 2 O 3 would act as a network former, hindering ion migration and inhibiting crystal precipitation (19).
The SEM and EDS element maps for specimen E (13% Fe 2 O 3 ), taken as an example of mineral morphology and Fe 2 O 3 distribution in the cement, are shown in Figure 2. Al, P and Ca overlapped in the regularly shaped α particles, which consequently consisted of calcium phosphoaluminate or modified monocalcium aluminate.The P/Ca overlap in the b particles was evidence that they consisted of calcium phosphate.The Ca content was observed to be higher in calcium phosphate than in calcium phosphoaluminate and modified monocalcium aluminate.Si was distributed evenly across all the minerals.
As Figure 2(f) shows, the iron phase was found in interstitial positions between the crystals, where it acted as a mineraliser during clinker sintering, confirming the XRD findings discussed above.The EDS-determined ferrite composition at seven points on the iron phase (20,21) are given in Table 1.The respective chemical formulas, calculated from the EDS data, are listed in the last column of the table.These findings revealed substantial variation in ferrite composition, which in this phosphoaluminate cement comprised a series of solid solutions comparable to the solutions in portland and calcium aluminate cements (22)(23)(24).

Compressive strength
The compressive strength values of the pastes at different ages are listed in Table 2. Figure 1 showed that the main minerals present in A were modified monocalcium aluminate (CA 1-Y (P Y )) and dodecacalcium hepta-aluminate (C 12 A 7 ).The former would clearly afford the paste early age strength, which rose to day 7 and remained constant thereafter.In the XRD pattern for paste G, which unlike the other cements was sintered at 1560 °C, the diffraction line for LHss predominated over all the other minerals present.The data in Table 2 show that while early age strength was much lower in paste G than in paste A, the 28-and 90-day strength values were higher in the former.Paste C, which had higher early age strength than specimen E, according to Figure 1, contained more CA 1-Y (P Y ) and less LHss than specimen E. The higher rate of strength development in  This reasoning is consistent with the XRD findings.Hence, the compressive strength of phosphoaluminate cement paste may be modified by controlling the Fe 2 O 3 dosage used.

Analysis of hydration products
The XRD patterns for the 1-, 3-, 7-, 28-and 90-day A, C and E cement pastes are reproduced in Figure 3.The signal for CA 1-Y (P Y ) was weak after just 1 day, an indication that it was largely consumed.In contrast, relatively intense diffraction lines for this mineral on the patterns for 3-day paste A showed that the addition of Fe 2 O 3 favoured CA 1-Y (P Y ) hydration.As CA 1-Y (P Y ) hydrated, the  The line for C 2 (A 1-X-Y P X Si Y )H 8 practically disappeared in the 28-day pattern for paste C, however, with its conversion into C(A 1-X-Y P X Si Y )H n at later ages (25).These findings were confirmed by the DSC analysis of paste C shown in Figure 4.
The intensity of the signals generated by C(A 1-X-Y P X Si Y )H n (6.201°,12.299°)rose with curing age.Since CA 1-Y (P Y ) was almost entirely consumed in the first day, the hydration product detected, C(A 1-X-Y P X Si Y )H n , must have been the result of LHss hydration.Unlike CAH 10 (6.219°,12.352°),which is unstable in high alumina cement, C(A 1-X P X Si Y )H n was stable due to the replacement of Al by P and Si (25).The diffraction lines associated with LHss declined in intensity after 90 days, when more C(A 1-X P X Si Y )H n was found in the system.As the solid solution of P and Si in LHss prevented C 2 AH 8 and CAH 10 from converting to C 3 AH 6 , compressive strength rose continuously in these specimens.Figure 5 shows the 1-day SEM micrograph and EDS analysis for specimen C, in which flaky hydration products were observed.EDS identified points

Heat of hydration
The heat flow curves plotted are shown in Figure 6.The figure shows that hydration peaked in paste A at 16.19 mW/g after 7.86 h and in paste C at 10.55 mW/g after 9.19 h.Both peaks were associated with swift CA 1-Y (P Y ) hydration.The paste E hydration peak was recorded at 7.03 mW/g after 17.86 h.Unlike paste C, paste E exhibited no significant heat peak in the first 10 hours.The reason was that the Fe 2 O 3 added had already induced CA 1-Y (P Y ) conversion to LHss.

CONCLUSIONS
A certain amount of iron oxide acts as a mineraliser, favouring the conversion of CA 1-Y (P Y ) to LHss at lower than the usual temperature.The ferrite occupies primarily interstitial positions.The main hydration products in iron oxide-rich phosphoaluminate cement are C 2 (A 1-X-Y P X Si Y )H 8 , and C(A 1-X-Y P X Si Y )H n .While the former ultimately converts to the latter, this conversion entails no decline in strength.The inclusion of P and Si in solid solution with C(A 1-X-Y P X Si Y )H n renders the system fairly stable.As LHss hydrates at later ages, strength grows continuously in the hardened cement paste.While adding Fe 2 O 3 lowers the early age strength of the hardened paste, it enhances the later age strength.The modification of the Fe 2 O 3 dosage can be used to control the composition of phosphoaluminate cement to produce a material compliant with different mechanical strength requirements.Hydration is deeply affected by Fe 2 O 3 : when the oxide was added at a rate of 11%, heat flow peaked at 10.55 mW/g after 9.19 h, while at 13% the peak declined to just 7.03 mW/g.
. As the figure shows, the main phases identified in specimen A (0% Fe 2 O 3 ) included modified CA 1-Y (P Y ), C 12 A 7 and CP 1-z (A z ), while only traces of LHss were detected.In contrast, large quantities of LHss (lines at 23.751°, 33.858°, 41.756°) were present in specimen G (likewise with 0% Fe 2 O 3 ), whose diffractogram showed no signals for CA 1-Y (P Y ), C 12 A 7 or CP 1-z (A z ).In other words, LHss was observed to form at high temperatures even without Fe 2 O 3 .In specimens B to E, with Fe 2 O 3 ranging from 10 to 13%, the main phases were CA 1-Y (P Y ) and CP 1-z (A z ).In these patterns, the LHss signal was more intense than on the pattern for specimen A, while the line for C 12 A 7 disappeared and a new phase, C A AF, formed.According to these findings, Fe 2 O 3 would favour the reaction between C 12 A 7 and phosphorus oxide, yielding mineral LHss at the lower temperature, while C 4 AF would be the product of the reaction between Fe 2 O 3 and C 12 A 7 .The intensity of the LHss diffraction line rose while the signals for C 4 AF, CA 1-Y (P Y ) and CP 1-z (A z ) weakened with rising Fe 2 O 3 content.Therefore, like high temperature, moderate percentages of Fe 2 O 3 favoured LHss formation from CA 1-Y (P Y ), CP 1-z (A z ) and C 4 AF.

E between 3
and 90 days would indicate that LHss enhances cement strength at later ages.Early age compressive strength declined significantly with rising percentages of Fe 2 O 3 , while later age strength rose visibly.The conclusion that may be drawn is that Fe 2 O 3 favoured the conversion of CA 1-Y (P Y ) to LHss, thereby raising later age compressive strength.

Figure 2 .
Figure 2. SEM analysis of specimen E.

Table 1 .
EDS analysis of ferrite in phosphoaluminate cement