2.1 Materials

FEP film of 100μm thickness supplied by Du pont (USA) was used for the grafting. Acryladehyde (from Sinopharm Chemcial Reagent Co., Ltd., China) distilled (bp 52ºC, atm. pressure) prior to use was dissolved in solvents. Other Chemicals were reagent grades and used as received.

2.2 Irradiation

FEP films were washed with methanol and dried under vacuum before irradiation. A ⁶⁰Co gamma ray source (10 000 Curies) was used for the irradiation of FEP films. All the irradiations were carried out in nitrogen at ambient temperature.

2.3 Graft Copolymerization

Irradiated films were cut into pieces (2.5 cm×4 cm) and were immersed in the acryladehyde solution placed in a glass ampoule. Several solvents i.e., water, ethanol, methanol, ethyl ether, and dichloromethane was used as solvent for the grafting reaction. The monomer solution was flashed with nitrogen for 30 min to remove the air, and then the ampoule was sealed. The grafting was carried out by placing the ampoule in a water bath, maintained at a constant temperature for the desired period. After the reaction, films were removed from the ampoule and extracted with ethanol to remove the homopolymer adhering to the surface of grafted films. The films were dried under vacuum at 50ºC until a constant weight was obtained. The degree of grafting was gravimeterically determined as the percentage of weight increase of the FEP film using the following equation

$Degreeofgrafting\text{/\%}=\frac{w_{\text{g}}-w_0}{w_0}\times 100\%$where w₀ and w_g are the weight of original and grafted FEP films, respectively

2.4 FT IR -ATR measurements

FT IR-ATR measurements of original and grafted FEP films were carried out with an FT IR Spectrometer at ambient condition in the transmitance mode. The film spectra were detected by an ATR accessory.

2.5 X-ray diffraction measurements

X-ray diffraction (XRD) measurements were made using an X-ray diffractometer. The diffractograms were measured at 2θ, 5‒50°.

2.6 Acraldehyde content

Acraldehyde content of the membranes was determined by acid-base titration. The membrane samples (about 2.0 g) were immersed into 50 mL of 0.5 M NH₂OH·HCl solution overnight at room temperature after at 45ºC with 1 h, with frequent stirring. The protons (H⁺) released in the solution were titrated with standardized 0.1 M NaOH solution until yellow color turns into green. The cost of standardized NaOH solution is V₁. The same work to the 0.5 M NH₂OH·HCl solution have no membrane samples, the cost of standardized NaOH solution is V₀. The degree of acraldehyde content of the membranes determined as the following equation.

Acraldehyde Content / %={[(V₁‒V₀)×C]/m}×100%

where V₁ and V₀ are the cost of standardized NaOH solution of titrated NH₂OH·HCl solution have and no membranes immersed respectively. And C is the concentration of the standardized NaOH solution, and m is the weight of the membrane.

3.1 Effect of radiation dose

The influence of the radiation dose on the degree of grafting is presented in Fig.1.

Fig.1Full-screen View

Variation of the degree of grafting with time at various pre-irradiation doses. Grafting conditions: monomer concentration, 100%; reaction temperature 55ºC.

For all dose, the degree of grafting increase with the increase in irradiation dose. Such a behavior may be attributed to the fact that at higher doses of radiation, the number of radicals generated in the system also increase. Therefore, more radicals are available for grafting reaction with increasing dose.

3.2 Effect of monomer concentration

The influence of the monomer concentration on the degree of grafting is presented in Fig.2. As can be seen, the grafting degree increases with increase in monomer concentration. Moreover, the degree of grafting increases as acrylaldehyde concentration increase from 20 up to 100 vol% not too much.

Fig.2Full-screen View

Grafting degree of acrylaldehyde onto FEP against monomer concentration. Grafting condition: pre-irradiation dose, 30 kGy; reaction temperature 55ºC; reaction time, 16 h.

3.3 Effect of diluent type

Diluent is basically used in radiation-induced graft copolymerization processes to bring about swelling of the base polymer, and hence enhance the degree of monomer accessibility to grafting sites. Therefore, the correct choice of diluent is one of the radiation- induced grafting techniques.

Fig.3Full-screen View

Grafting degree of acrylaldehyde onto FEP against reaction time at different diluent.

3.4 FT IR Measurements

Figure 4 shows FTIR spectra of the original and grafted FEP films. The original FEP films are characterized by narrow band at 1100‒1200 cm^‒1, which represents the stretching vibration of C-F. The presence of an aldehyde of acryladehyde in grafted FEP films is established by the C=O stretching vibration at 1710 cm^‒1 and the C-H of aldehyde stretching vibrations at 2850 cm^‒1. The spectra clearly indicate that the bands arising from the presence of aldehyde increase with the increase in the degree of grafting. This means that acryladehyed is successfully grafted to the FEP backone.

Fig.4Full-screen View

FT IR-spectra of original FEP (A) and acraldehyde- grafted FEP membranes having various degrees of grafting: (B) 5.21%, (C) 10.52%, (D) 17.05%, (E) 28.65%.

3.5 X-ray diffraction measurements

The grafting of acryladehyde onto FEP has been found to bring about considerable changes in the crystallinity of the graft copolymer. Fig.5 shows the diffraction patterns of the original and grafted FEP films.

Fig.5Full-screen View

Diffraction patterns of original FEP (A) and acraldehyde-grafted FEP membranes having various degrees of grafting: (B) 5.21%, (C) 10.52%, (D) 17.05%, (E) 28.65%.

It was found that the crystallinity peak for the original and all grafted films occurs at the same angle (2θ), meaning that there is no change in the structure. However, the peak intensities of all grafted films are lower, and decrease with the increase in the degree of grating. This means that the crystallinity decrease with the increase in the degree of grafting. It can be noticed that these results are similar to those obtained upon grating of styrene onto FEP, styrene onto PFA. This behavior can be explained on the bases of dilution and partial destruction of the inherent crystallinity.

3.6 Acraldehyde content

Fig.6Full-screen View

Relationship between acraldehyde content of the grafted membrane and the degree of grafting.