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详细信息
美国自然基金委推荐测量湿地脱氮速率专用仪器
反硝化速率和脱氮速率科研的强大工具
高精度溶解气体测量仪器
前言:
氮气(N2)、氧气(O2)、二氧化碳(CO2)是湿地、河流、湖泊、海洋等水体中的重要溶解气体,是生态环境变化过程中的重要参数指标。例如,溶解氧是衡量海气扩散过程、水团混合、大洋环流以及海水中生物化学过程的重要指标;水体中CO2对于研究碳循环和气候变化具有重要作用;而水体中溶解N2则对于研究水体反硝化速率、农业氮肥利用率、水体富营养化等相关问题具有至关重要的作用。目前,测量水体海洋中溶解气体的传统方法是先采集水样,然后在实验室内或者船上进行检测,但由于很多参数会随时空的变化而发生改变,从而得不到实时原位的准确数据。水体及沉积物反硝化速率的测定方法主要有乙炔抑制法、N2通量法、质量平衡法、化学计量法和同位素法,但这些方法大多存在人为扰动大、操作繁琐、误差大的不足,因而无法精确测定淹水环境下的反硝化速率。膜进样质谱仪(MIMS)则能够实时、原位、连续监测水体中的溶解气体(N2、O2、CO2),并且能够精确测定淹水环境下水体、沉积物的反硝化速率,已被国内外众多研究机构广泛应用,并被美国自然科学基金委推荐用来测定湿地脱氮速率。同时,膜进样质谱仪还能够应用于稳定同位素(15N 、18O、13C)的检测、光合呼吸、生物反应器等方面的研究。
主要特点:
- 可实时、原位检测
- 测量精度高、重复性好
- 所需样品量少,仅5ml
- 操作简便,样品分析快,仅90s
- 不需要顶空平衡,可实现水气分离
- 可将空气中高浓度背景气体分离开,避免了样品的污染
- 专用软件(QuickData)高效评估收集的信号和数据
图1 QuickData软件
主要应用:
- 环境(水体、沉积物)反硝化速率的研究
- 原位测量水体(海洋/湖泊/河流/地表水/地下水)中O2、CH4、DMS、CO2和Ar浓度
- 海洋总初级生产力的测定
- 贫瘠水域的呼吸作用研究
- 稳定同位素的测定(15N 、18O、13C)
图2 MIMS在反硝化中的应用,将原状沉积物和上覆水取回在室内进行培养,研究反硝化过程中N2的排放速率
图3 利用已知CH4浓度和测量出来的信号值进行拟合曲线,进而测量未知水体中CH4浓度
图4 MIMS可用于水生生态系统代谢和氧气动力学研究
图5 MIMS可与液相氧电极或叶绿素荧光仪联用测量光合和呼吸作用
MIMS典型应用:
表1 标样连续测定10h后信号偏移情况(李晓波等,2013)
表2 MIMS与IRMS在测量海洋总初级生产力时的数据比较
图7 利用MIMS测量出11种中国典型稻田土壤下的反硝化、厌氧氨氧化、DNRA的贡献率(Shan J et. al, 2016)
参考文献:
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2.赵永强, 夏永秋, 李博伦, 等. 利用膜进样质谱同时测定河流沉积物反硝化和厌氧氨氧化. 农业环境科学学报, 2014, 33(4): 794-802
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