TY - JOUR
T1 - An improved approach for evaluating the semicrystalline lamellae of starch granules by synchrotron SAXS
AU - Zhang, Binjia
AU - Xie, Fengwei
AU - Wang, David K.
AU - Zhao, Siming
AU - Niu, Meng
AU - Qiao, Dongling
AU - Xiong, Shanbai
AU - Jiang, Fatang
AU - Zhu, Jie
AU - Yu, Long
N1 - Publisher Copyright:
© 2016 Elsevier Ltd
PY - 2017/2/20
Y1 - 2017/2/20
N2 - A fitting method combined with a linear correlation function was developed as an improved approach for the SAXS analysis of the semicrystalline lamellae of starch granules. Using a power-law function with two Gaussian plus Lorentz functions, the SAXS pattern was resolved into sub-patterns of the net lamellar peak and the power-law scattering plus scattering background (PL + B). The ratio of the net lamellar peak area (Apeak) to the total scattering area (Atotal) was proposed equal to the proportion of the lamellae within the starch granule (PSL). Along with this fitting method, we obtained a better profile of linear correlation function, with the elimination of the interference of non-lamellar amorphous starch (i.e., amorphous growth rings). Then, we could accurately calculate the lamellar parameters, e.g., PSL, the thicknesses of semicrystalline (d), crystalline (dc) and amorphous (da) lamellae, and the volume fraction (φc) of crystalline lamellae within semicrystalline lamellae. Quantitative analysis revealed that PSL was positively correlated with the crystallinity (Xc) of starch. It was confirmed that the distribution of lamellar thickness was more important than the starch botanical origin in affecting the validity of the developed fitting method. We also proposed a criterion to test the validity of the proposed method. Specifically, the total SAXS pattern should be mostly tangent to the profile of PL + B at a high q tail (close to 0.2 Å−1).
AB - A fitting method combined with a linear correlation function was developed as an improved approach for the SAXS analysis of the semicrystalline lamellae of starch granules. Using a power-law function with two Gaussian plus Lorentz functions, the SAXS pattern was resolved into sub-patterns of the net lamellar peak and the power-law scattering plus scattering background (PL + B). The ratio of the net lamellar peak area (Apeak) to the total scattering area (Atotal) was proposed equal to the proportion of the lamellae within the starch granule (PSL). Along with this fitting method, we obtained a better profile of linear correlation function, with the elimination of the interference of non-lamellar amorphous starch (i.e., amorphous growth rings). Then, we could accurately calculate the lamellar parameters, e.g., PSL, the thicknesses of semicrystalline (d), crystalline (dc) and amorphous (da) lamellae, and the volume fraction (φc) of crystalline lamellae within semicrystalline lamellae. Quantitative analysis revealed that PSL was positively correlated with the crystallinity (Xc) of starch. It was confirmed that the distribution of lamellar thickness was more important than the starch botanical origin in affecting the validity of the developed fitting method. We also proposed a criterion to test the validity of the proposed method. Specifically, the total SAXS pattern should be mostly tangent to the profile of PL + B at a high q tail (close to 0.2 Å−1).
KW - Granule
KW - Methodology
KW - Semicrystalline lamellae
KW - Starch
KW - X-ray scattering
UR - http://www.scopus.com/inward/record.url?scp=85002755581&partnerID=8YFLogxK
U2 - 10.1016/j.carbpol.2016.12.002
DO - 10.1016/j.carbpol.2016.12.002
M3 - Article
C2 - 28024539
AN - SCOPUS:85002755581
SN - 0144-8617
VL - 158
SP - 29
EP - 36
JO - Carbohydrate Polymers
JF - Carbohydrate Polymers
ER -