Moisture distribution and migration of Ginkgo biloba seeds during air drying process

doi:10.3969/j.issn.1000-2006.201808008

JOURNAL OF NANJING FORESTRY UNIVERSITY ›› 2019, Vol. 43 ›› Issue (6): 188-192.doi: 10.3969/j.issn.1000-2006.201808008

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Moisture distribution and migration of Ginkgo biloba seeds during air drying process

SUN Xu¹(), JIANG Dong², XU Li², HUA Tongtong³, XUAN Yan⁴^,^*(), CAO Fuliang³

1. College of Information Science and Technology, Nanjing Forestry University, Nanjing 210037, China
2. College of Science, Nanjing Forestry University, Nanjing 210037, China
3. College of Forestry, Nanjing Forestry University, Nanjing 210037, China
4. Advanced Analysis and Testing Center, Nanjing Forestry University, Nanjing 210037, China

Received:2018-08-03 Revised:2018-10-19 Online:2019-11-30 Published:2019-11-30
Contact: XUAN Yan E-mail:121957684@qq.com;xuanyannfu@njfu.edu.cn

Abstract

Abstract:

【Objective】 The water composition of Ginkgo biloba seeds plays an important role in its physiological metabolism and affects its quality. Information about moisture distribution and migration inG. biloba seeds during hot air drying can provide data to optimize drying and rapidly determine the water content during storage. 【Method】The Carr-Purcell-Meiboom-Gill decay signals were obtained during hot air drying of G. biloba seeds by low-field nuclear magnetic resonance (NMR) equipped with a 0.5 T permanent magnet and proton resonance frequency of 21 MHz at a temperature of 32℃. The transverse relaxation time (T₂) was calculated based on the decay signal data using the SIRT algorithm, which provides the position and area of each peak. NMR images were obtained by SE imaging sequence. 【Result】 The drying rate increased with an increase in the air temperature during hot air drying. For all states of water, T₂ followed a decreasing trend during drying. The states of water could be classified into three main categories: bound water (0.79-7.32 ms), weakly bound water (13.67-89.07 ms), and free water (109.70-1 072.27 ms). The moisture state ofG. biloba seeds changed, and free water and weakly bound water were gradually removed during hot air drying. Increased water content significantly correlated with stronger NMR signals and larger peak areas. This phenomenon can be described by this equation: y = 7 436.46 x + 153.32 (R²= 0.993). NMR imaging was used to visualize proton images at different stages in the light and dark. 【Conclusion】 There is a high correlation between moisture content and NMR relaxation peak value. The water content of G. biloba seeds can also be observed directly using a nuclear magnetic map.

Key words: ginkgo seed, moisture transformation, dry, low field-nuclear magnetic resonance, transverse relaxation time

CLC Number:

S792.95

SUN Xu, JIANG Dong, XU Li, HUA Tongtong, XUAN Yan, CAO Fuliang. Moisture distribution and migration of Ginkgo biloba seeds during air drying process[J]. JOURNAL OF NANJING FORESTRY UNIVERSITY, 2019, 43(6): 188-192.

Figures/Tables 6

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样品序号 No.	T₂₁			T₂₂			T₂₃
样品序号 No.	起始点 starting point	峰点 peak point	结束点 end point	起始点 starting point	峰点 peak point	结束点 end point	起始点 starting point	峰点 peak point	结束点 end point
1	0.026	1.047	3.917	14.65	23.817	41.504	62.950	155.223	289.942
2	0.370	1.123	2.097	6.368	33.701	58.728	83.099	178.343	289.942
3	0.026	1.203	5.543	5.941	38.720	109.699	117.585	204.907	310.787
4	0.280	1.290	2.967	29.332	41.504	51.114	83.099	219.639	357.079
5	0.028	1.383	3.917	23.817	41.504	77.526	117.585	289.942	471.375
6	0.026	1.482	6.368	22.219	47.686	109.699	126.038	310.787	580.523
7	0.026	1.825	11.895	27.364	47.686	95.477	109.699	382.749	943.788
8	0.028	1.956	11.895	23.817	51.114	102.341	289.942	439.760	766.341
9	0.026	2.248	11.895	27.364	51.114	102.341	471.375	541.587	821.434
10	1.956	3.917	5.941	14.65	62.950	194.713	235.429	580.523	1 121.029
11	0.740	3.917	7.317	33.701	72.326	126.038	289.942	622.257	911.638
12	0.026	4.501	34.789	41.504	72.326	135.099	714.943	880.488	1 162.322

Moisture distribution and migration of Ginkgo biloba seeds during air drying process

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