[1]周向军,齐婷,高茹霞.玉米秸秆腐解释放溶解性有机质的光谱分析[J].黑龙江农业科学,2022,(10):76-82.[doi:10.11942/j.issn1002-2767.2022.10.0076]
 ZHOU Xiang-jun,QI Ting,GAO Ru-xia.Spectral Analysis of Dissolved Organic Matter of Maize Straw in Decomposition Process[J].HEILONGJIANG AGRICULTURAL SCIENCES,2022,(10):76-82.[doi:10.11942/j.issn1002-2767.2022.10.0076]
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玉米秸秆腐解释放溶解性有机质的光谱分析

《黑龙江农业科学》[ISSN:1002-2767/CN:23-1204/S] 卷: 期数: 2022年10 页码: 76-82 栏目: 出版日期: 2022-10-10
Title:
Spectral Analysis of Dissolved Organic Matter of Maize Straw in Decomposition Process
作者:
周向军12齐婷1高茹霞1
1.天水师范学院 生物工程与技术学院,甘肃 天水 741001; 2.甘肃省农业固体废弃物资源化利用重点实验室,甘肃 天水 741001
Author(s):
ZHOU Xiang-jun12QI Ting1 GAO Ru-xia1
1.College of Bioengineering and Biotechnology, Tianshui 741001,China; 2.Key Laboratory of Utilization of Agricultural Solid Waste Resources, Tianshui 741001,China
关键词:
溶解性有机质腐解玉米秸秆光谱分析
Keywords:
dissolved organic matter decomposition maize straw spectral analysis
DOI:
10.11942/j.issn1002-2767.2022.10.0076
文献标志码:
A
摘要:
为进一步开展保护性耕作,在模拟农田黄绵土壤微生物条件下,采用总有机碳法研究玉米秸秆不同腐解过程中溶解性有机质的释放特征,通过紫外光谱、红外光谱以及三维荧光光谱法,对溶解性有机质的光谱特性和荧光组分进行解析。结果表明,溶解性有机质在腐解第0.5天达到最大值为221.01 mg·L-1,腐解过程可分为腐解初期(0~3 d)、腐解中期(3~30 d)和腐解后期(30~60 d)三个阶段,释放特征呈“W”型趋势。紫外光谱表明,E2/E3和E2/E4均先降低后趋于稳定,SUVA254呈先增加后降低趋势。红外光谱表明,腐解初期主要释放游离氨基酸和可溶性糖,腐解中期以降解蛋白质、淀粉类碳水化合物、脂类等易降解性组分为主,腐解后期则以形成腐殖质类为主。三维荧光光谱表明,溶解性有机质首先转化为类富里酸,随后进一步形成类胡敏酸。研究表明,多光谱联用技术可用于秸秆源溶解性有机质的光谱特性和荧光组分解析。
Abstract:
In oder to further develop conservation tillage, the total organic carbon method was used to study the releasing characteristics of DOM in different decomposition processes under simulated microbial conditions of farmland loess. The spectral characteristics and fluorescence components of DOM were analyzed by ultraviolet spectroscopy(UV-vis), infrared spectroscopy(FTIR) and three-dimensional fluorescence spectroscopy(3D-EEM). The results showed that DOM reached the maximum value of 22101 mg·L-1 at 0.5 d, the decomposition process could be divided into the initial stage of decomposition(0-3 d), the middle stage of decomposition(3-30 d) and later stage of decomposition(30-60 d), showing a “W” shape trend. UV-vis spectra showed that E2/E3 and 2/E4 both decreased first and then tended to be stable, while SUVA254 showed a trend of increasing first and then decreasing. FTIR showed that free amino acids and soluble sugars mainly released in the early stage, protein, starch-like carbohydrates, lipids and other easily degradable components mainly released in the middle stage, humus mainly formed in the later stage. 3D-EEM showed that DOM were first converted to fulvic acid-like, followed by further formation of humic acid-like. The research showed that multispectral techniques could be used to analyze the spectral characteristics and fluorescence components of straw-derived DOM.

参考文献/References:

[1]YIN H,ZHAO W,LI T,et al.Balancing straw returning and chemical fertilizers in China:Role of straw nutrient resources[J].Renewable and Sustainable Energy Reviews,2017,81(2):2695-2702.

[2]余旭芳,周俊,任兰天,等.小麦秸秆堆肥水溶性有机物的结构和组成演变[J].光谱学与光谱分析,2021,41(4):1199-1204.
[3]李彬彬,武兰芳.秸秆还田条件下剖面土壤溶解性有机碳含量及其组分结构的变化[J].农业环境科学学报,2019,38(7):1567-1577.
[4]RAN B,LU Q,YU W,et al.Electron transfer capacity of soil dissolved organic matter and its potential impact on soil respiration[J].Journal of Soils and Sediments,2013,13(9):1553-1560.
[5]YE Q,WANG Y,ZHANG Z,et al.Dissolved organic matter characteristics in soils of tropical legume and non-legume tree plantations[J].Soil Biology and Biochemistry,2020,148:107880.
[6]王齐磊,江韬,赵铮,等.三峡库区典型农业小流域水体中溶解性有机质的光谱特征[J].环境科学,2016,37(6):2082-2092.
[7]CHEN H,ZHOU J,XIAO B.Characterization of dissolved organic matter derived from rice straw at different stages of decay[J].Journal of Soils and Sediments,2010,10(5):915-922.
[8]韦梦雪,王彬,谌书,等.川西平原还田秸秆腐解释放DOM的光谱特征[J].光谱学与光谱分析,2017,37(9):2861-2868.
[9]HE Z,MAO J,HONEYCUTT C W,et al.Characterization of plant-derived water extractable organic matter by multiple spectroscopic techniques[J].Biology and Fertility of Soils,2009,45(6):609-616.
[10]肖燏杰.水稻秸秆腐解产生溶解性有机质的分组组成及其环境意义[D].成都:四川农业大学,2009.
[11]何伟,白泽琳,李一龙,等.溶解性有机质特性分析与来源解析的研究进展[J].环境科学学报,2016,36(2):359-372.
[12]周萌,肖扬,刘晓冰.土壤活性有机质组分的光谱分析方法及应用[J].土壤,2020,52(6):1093-1104.
[13]LI P,HUR J.Utilization of UV-vis spectroscopy and related data analyses for dissolved organic matter(DOM) studies:A review[J].Critical Reviews in Environmental Science and Technology,2017,47(3):131-154.
[14]王君玮,袁会敏,江荣风,等.中红外光谱法测定土壤碳的研究进展[J].土壤通报,2021,52(1):233-241.
[15]李飞跃,桂向阳,许吉宏,等.生物炭中溶解性有机质的光谱分析[J].光谱学与光谱分析,2019,39(11):3475-3481.
[16]NEBBIOSO A,PICCOLO A.Molecular characterization of dissolved organic matter(DOM):A critical review[J].Analytical and Bioanalytical Chemistry,2013,405(1):109-124.
[17]范春辉,张颖超,王家宏.温度和铅离子对秸秆腐殖化溶解性有机质三维荧光光谱的干扰效应[J].光谱学与光谱分析,2015,35(11):3117-3122.
[18]范春辉,张颖超,王家宏.黄土区秸秆腐殖化溶解性有机质对土壤铅赋存形态的影响机制[J].光谱学与光谱分析,2015,35(11):3146-3150.
[19]LI D,HE X,XI B,et al.Study on UV-visible spectracharacteristic of dissolved organic matter during municipal solid waste composting[J].Advanced Materials Research,2014,878:840-849.
[20]刘堰杨,秦纪洪,孙辉.川西高海拔河流中溶解性有机质(DOM)紫外-可见光吸收光谱特征[J].环境科学学报,2018,38(9):3662-3671.
[21]焦宇欣,李东阳,龚天成,等.基于光谱色谱分析热解温度对沼渣生物炭DOM组成特性的影响[J].环境科学研究,2021,34(10):2468-2476.
[22]MOODY C S,WORRALL F.Modeling rates of DOC degradation using DOM composition and hydroclimatic variables[J].Journal of Geophysical Research:Biogeosciences,2017,122:1175-1191.
[23]HU S,LU C,ZHANG C,et al.Effects of fresh and degraded dissolved organic matter derived from maize straw on copper sorption onto farmland loess[J].Journal of Soil and Sediments,2016,16(2):327-338.
[24]谢理,杨浩,渠晓霞,等 滇池典型陆生和水生植物溶解性有机质组分的光谱分析[J].环境科学研究,2013,26(1):72-79.
[25]庞燕华,陈莉娜,张晟,等.热处理后水稻土溶解性有机质光谱特征的变化[J].农业环境科学学报,2018,37(3):505-514.
[26]凌宇,闫国凯,王海燕,等.6种农业废弃物初期碳源及溶解性有机物释放机制[J].环境科学,2021,42(5):2422-2431.
[27]PEDERSEN J A,SIMPSON M A,BOCKHEIM J G,et al.Characterization of soil organic carbon in drained thaw-lake basins of arctic alaska using NMR and FTIR photoacoustic spectroscopy[J].Organic Geochemistry,2011,42(8):947-954.
[28]常汉达,王晶,张凤华.基于傅里叶红外光谱弃耕地开垦前后土壤有机质结构变化分析[J].土壤通报,2019,50(2):333-340.
[29]KAAL J,CORTIZAD A M,BIESTER H.Downstream changes in molecular composition of DOM along a headwater stream in the harz mountains(Central Germany) as determined by FTIR,pyrolysis-GC-MS and THM-GC-MS[J].Journal of Analytical and Applied Pyrolysis,2017,126:50-61.
[30]卜贵军,于静,邸慧慧,等.红外光谱结合二维相关分析研究堆肥过程腐殖酸演化规律[J].光谱学与光谱分析,2015,35(2):362-366
.[31]WEI J,ZHAO X,ZHAO Y,et al.Variation in spectral characteristics of dissolved organic matter derived from rape straw of plants grown in Se-amended soil[J].Journal of Integrative Agriculture,2020,19(7):1876-1884.[32]YANG M,REHMAN M S U,YAN T,et al.Treatment of different parts of corn stover for high yield and lower polydispersity lignin extraction with high-boiling alkaline solvent[J].Bioresource Technology,2018,249:737-743.
[33]翁诗甫,徐怡庄.傅里叶变换红外光谱分析[M].3版.北京:化学工业出版社,2016:490-506.
[34]曹莹菲,张红,赵聪,等.秸秆腐解过程中结构的变化特征[J].农业环境科学学报,2016,35(5):976-984.
[35]寇巍,赵勇,闫昌国,等.膨化预处理玉米秸秆提高还原糖酶解产率的效果[J].农业工程学报,2010,26(11):265-269.
[36]张倩,董靖,吉芳英,等.新建人工深水湖泊沉积物上覆水和孔隙水中溶解性有机质的光谱特征[J].湖泊科学,2018,30(1):112-120.
[37]鲁遥,王朋,尹梦楠,等.不同类型土壤胡敏酸提取物环境持久性自由基特征及影响因素[J].化工进展,2021,40(5):2917-2927.
[38]李艳,魏丹,王伟,等.秸秆-牛粪发酵过程中溶解性有机质的荧光光谱特征[J].光谱学与光谱分析,2021,41(9):2846-2852.
[39]张海洋,杨清贤,杨倩,等.水环境中秸秆源溶解有机质的组成及光化学活性特征[J].中国环境科学,2020,40(6):204-211.
[40]范春辉,张颖超,王家宏.pH值对秸秆腐殖化溶解性有机质紫外光谱和荧光光谱的影响[J].光谱学与光谱分析,2015,35(7):1933-1937.
[41]倪文海,刘欢,刘振涛,等.水稻秸杆腐解过程溶解性有机质红外光谱研究[J].土壤,2013,45(2):1220-1226.
[42]朱文飞,李晓洁,刘长风,等.沈阳市黑臭水体表层水DOM紫外光谱特征分析[J].环境工程学报,2019,13(3):569-576.
[43]曹莹菲,张红,刘克,等.不同处理方式的作物秸秆田间腐解特性研究[J].农业机械学报,2016,47(9):212-219.
[44]张红,吕家珑,曹莹菲,等.不同植物秸秆腐解特性与土壤微生物功能多样性研究[J].土壤学报,2014,51(4):743-752.

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备注/Memo

收稿日期:2022-07-06

基金项目:甘肃省自然科学基金项目“玉米秸秆腐蚀释放溶解性有机质对氟喹诺酮类抗生素的消减作用”(20JR5RA499);天水师范学院项目“秸秆还田溶解性有机质的光谱特性及对黄绵土Pb/Zn赋存形态调控”。
第一作者:周向军(1980-),男,硕士,副教授,从事环境化学和生物化学研究。

更新日期/Last Update: 2022-12-26