2. Experimental section2.1. Materia

2. Experimental section
2.1. Materials
Poly(L-lactic acid) with a melt flow index in the range of 5e7 g/ 10 min (2.16 kg, 210 C) and a density of 1.24 g/cm3 was obtained from Nature Works! (2002D). Natural Rubber (NR) latex containing 60 wt% dried rubber was provided by the Key Laboratory of Tropical Crop Products Processing of Ministry of Agriculture of China (Zhanjiang, China).
2.2. Preparation of PLLA/NR blends
Before blending, PLA particles were dried in vacuum oven at 80 C for 24 h and the Natural Rubber latex was dried in vacuum oven at 40 C until it was transparent completely. The PLA and PLA/ NR blends were processed at 60 rpm, 170 C in a Haake internal mixer (Rheocord 90) for 10 min. The well mixed blends were cut into small granules while they were hot. The samples with 0, 1, 3 and 5 wt% NR were labeled as PLA, PLA/NR-1, PLA/NR-3 and PLA/ NR-5.
The melt mixed samples were then pressed into 0.2 mm thick films under 10 MPa pressure for 2 min at 190 C, followed by cooling process at room temperature for 3 min under the same pressure.
2.3. Contact angle measurement
Static water contact angle measurements of the samples were obtained by a contact angle measuring instrument (JGW 360C, Chenghui Testing Machine Co., Ltd, China) at 25 C and 50% relative humidity. The values were obtained when the contact time of water and specimen was 10 s. At least ten measurements on different areas of each film specimen were averaged.
Contact angle relaxation of water droplet was measured by sessile drop method. Contact angle at t 1⁄4 0 s was measured by less than 1 s and estimated from the first droplet image which was collected by the instrument automatically every 0.5 s.
2.4. Hydrolysis
The film samples prepared by compression molding were cut into 1 3 cm2 specimens for hydrolysis study. Each pre-weighed specimen (W0) was dipped in a vial containing 10 mL deionized water and the vials were placed in a water bath at a constant temperature of 58 C. Three specimens of each sample were picked out at predetermined time, washed with deionized water, dried to a constant weight in vacuum oven at 40 C and weighed again (Wt). The mass loss was calculated from the following formula: mass loss (%) 1⁄4 (1Wt/W0) 100, and all the values presented were the average of three specimens.
2.5. Water absorption
The specimens (2 4 cm2) were pre-dried in vacuum oven at 40 C until a constant weight and weighed as initial mass (M0). Triplicate specimens of each sample were placed in a beaker con- taining deionized water and then sealed the beakers in 58 C water bath. At a predetermined time, each specimen was pick out, wiped
out the water on the surface and weighed (Mt). The water ab- sorption of each sample was calculated from the following formula: water absorption (%) 1⁄4 100 (MtM0)/M0, and all the values pre- sented were also averaged from three specimens.
2.6. Molecular weight measurement
Molecular weight of neat PLA and PLA/NR blends, before and after degradation, was performed by gel permeation chromato- grams (GPC, 20AD, Shimadzu). The GPC system was calibrated us- ing Agilent Company’s mono-disperse polystyrene standards, KF- 805 and KF-802 columns were running in series. Chloroform was used as mobile phase at a flow rate of 0.8 mL/min at 36 C.
2.7. Scanning electron microscope (SEM)
The morphology of the surfaces and fracture surfaces of samples were recorded with an INSPECT F scanning electron microscope (SEM) operated at 5 kV working voltage. Before the SEM observa- tion, the specimens were sputtered with gold under vacuum. Samples with fracture surface of neat PLA and PLA/NR blends were prepared by brittle fracture with liquid nitrogen cooling.
2.8. Differential scanning calorimetry (DSC)
The thermal properties (5e6 mg, respectively) were tested by DSC (Netzsch DSC-204F1). The crystallization and melting behavior were detected by two heating scans and a cooling scan in the range of 0e190 C at a heating rate of 10 C/min. Glass transition tem- perature (Tg) was estimated from the inflection of the glass tran- sition based on the second scan. Cold crystallization temperature (Tc) and melting temperature (Tm) were determined by the maximum value of the DSC exo/endotherm peak. Crystallinity (c) was calculated by the following formula:
cð%Þ 1⁄4 DHm  DHc 100% DHmo ,ð1fNRÞ
where DHc, DHm and DHmo are respectively the enthalpies of cold crystallization, melting and melting for 100% crystalline PLA. The value used for DHmo is 93.1 J/g [2]. fNR is the content of NR in PLA/NR blends.
3. Results and discussion
The changes of contact angle with contact time are presented in Fig. 1 and the static water contact angle values at 10 s contact time, averaged from 10 measurement values, are contained in the legend. As can be seen, the curves shift to higher values with increasing NR content and the values shown in the legend also present the trend that the contact angles increase with NR increase. This indicates that NR as a hydrophobic material compared to PLA dispersing on the PLA surface has led to an increase in hydrophobility of the PLA surface. In addition, the contact angles decrease continuously with contact time showing the behavior of contact angle relaxation. From the relaxation curves, three regimes can be clearly observed. At the first stage (0e2 s), contact angles decrease very fast. This is mainly due to the conformational change of PLA which could lead to a rapid decrease of contact angle. Compared to neat PLA whose contact angle reaches equilibrium in the second stage (2e10 s), a slow contact angle relaxation of PLA/NR blends occurs continuously which is attributable to the viscoelastic dissipation of NR [26]. With water evaporation, during the third stage (10e60 s), contact angle relaxations are slower and have the same tendency for each sample