6种矿物基填料的氨氮和磷吸附性能比较与作用机制

应虹; 罗艳; 王明湖; 周金波; 王海位; 金树权

doi:10.12153/j.issn.1674-991X.20240225

6种矿物基填料的氨氮和磷吸附性能比较与作用机制

doi: 10.12153/j.issn.1674-991X.20240225

应虹^{1, 2,},
罗艳³,
王明湖⁴,
周金波^{1, 2},
王海位⁵,
金树权^{1, 2, ,}

1.
宁波市农业科学研究院
2.
宁波市特色农产品质量安全检测与控制重点实验室
3.
宁波市生态环境科学研究院
4.
宁波市农业农村绿色发展中心
5.
浙江绿美新特环保科技有限公司

基金项目: 宁波市科技创新2025重大专项“非粮化耕地和中低产田产能提升综合技术模式与应用”（2022Z169）；宁波市农业科学研究院院长基金项目（2023NKYP002）

详细信息

作者简介:
应虹（1993—），女，助理研究员，博士，主要从事土壤和农业生态环境研究，yinghong_adeline@163.com

通讯作者:
金树权（1981—），男，研究员，博士，主要从事土壤和农业生态环境研究，jinshuq@126.com

中图分类号: X703
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- 被引次数: 0
出版历程
- 收稿日期: 2024-04-10
- 录用日期: 2024-08-05
- 修回日期: 2024-06-17

Comparison and mechanism of ammonia nitrogen and phosphorus adsorption properties of six mineral-based fillers

YING Hong^{1, 2
,},
LUO Yan³,
WANG Minghu⁴,
ZHOU Jinbo^{1, 2},
WANG Haiwei⁵,
JIN Shuquan^{1, 2
, ,}

1.
Ningbo Academy of Agricultural Sciences
2.
Ningbo Key Laboratory of Testing and Control for Characteristic Agro-Product Quality and Safety
3.
Ningbo Research Institute of Ecological Environmental Sciences
4.
Center of Green Development, Ningbo Agricultural and Rural Bureau
5.
Zhejiang Lvmeixinte Environment Technology Co., Ltd.

摘要

摘要:
为高效去除污染水体中的氨氮（${\mathrm{NH}}_4^+ $-N）和磷酸盐（${\mathrm{PO}}_4^{3-} $-P），筛选生态修复工程中吸附性能优异的矿物基填料，选取了3种天然填料（沸石、蛭石、火山岩）和3种加工型填料（陶粒、生物滤料、除磷滤料）开展${\mathrm{NH}}_4^+ $-N、${\mathrm{PO}}_4^{3-} $-P的吸附动力学和等温线试验，结合X射线衍射、电子扫描显微镜等表征手段，对不同矿物基填料的吸附特性与作用机制进行对比和分析。结果表明：6种矿物基填料的${\mathrm{NH}}_4^+ $-N和${\mathrm{PO}}_4^{3-} $-P吸附动力学过程均符合伪二级动力学方程，吸附速率主要受化学吸附过程控制。Langmuir和Freundlich方程都能很好地拟合不同矿物基填料的等温吸附曲线，${\mathrm{NH}}_4^+ $-N的理论吸附容量排序为沸石（5.941 6 mg/g）>蛭石（3.695 3 mg/g）>生物滤料（3.250 0 mg/g）>除磷滤料（3.138 9 mg/g）>火山岩（1.000 0 mg/g）>陶粒（0.857 1 mg/g），${\mathrm{PO}}_4^{3-} $-P的吸附容量大小为除磷滤料（4.242 4 mg/g）>生物滤料（2.791 7 mg/g）>蛭石（1.625 0 mg/g）>陶粒（1.210 5 mg/g）>火山岩（1.157 9 mg/g）>沸石（0.562 5 mg/g）。矿物基填料对${\mathrm{NH}}_4^+ $-N和${\mathrm{PO}}_4^{3-} $-P的吸附特性与其比表面积、微孔结构、矿物组成和金属元素含量等因素相关，其中沸石的比表面积和阳离子交换量最大，对${\mathrm{NH}}_4^+ $-N的吸附能力最强，生物滤料和除磷滤料中含有托贝莫来石、Ca、Fe等与磷结合能力较强的成分，对${\mathrm{PO}}_4^{3-} $-P的去除效果明显。综合来看，沸石和蛭石可用于${\mathrm{NH}}_4^+ $-N污染水体的治理，生物滤料和除磷滤料可用于处理含磷污水，而治理同时含有${\mathrm{NH}}_4^+ $-N和磷的污染水体时，可组合使用多种矿物基填料。对比其他填料，自主开发制备的生物滤料和除磷滤料在同步脱氮除磷方面具有明显优势，可作为氮、磷污染水体生态修复工程的优选基质。
- 矿物基填料 /
- 氨氮 /
- 磷 /
- 吸附 /
- 生态修复
Abstract:
In order to efficiently remove ammonia nitrogen (${\mathrm{NH}}_4^+ $-N) and phosphates (${\mathrm{PO}}_4^{3-} $-P) from contaminated water and screen mineral-based fillers with excellent adsorption performance used in ecological restoration projects, three natural fillers (zeolite, vermiculite, volcanic rock) and three artificial fillers (ceramsite, biological filter, phosphorus removal filter) were selected to carry out experiments on the adsorption kinetics and isotherm of ammonia nitrogen and phosphorus. The adsorption properties and mechanisms of different mineral-based fillers were compared and analyzed by characterization methods such as X-ray diffraction and scanning electron microscopy. The results showed that the adsorption kinetics of ${\mathrm{NH}}_4^+ $-N and ${\mathrm{PO}}_4^{3-} $-P of the six mineral-based fillers complied with the pseudo-second-order kinetic equation, and the chemisorption process mainly controlled the adsorption rates. Both Langmuir and Freundlich equations could well describe the isothermal adsorption curves, and the theoretical adsorption capacity of ${\mathrm{NH}}_4^+ $-N was ranked as zeolite (5.9416 mg/g) > vermiculite (3.6953 mg/g) > biological filter (3.2500 mg/g) > phosphorus removal filter (3.1389 mg/g) > volcanic rock (1.0000 mg/g) > ceramsite (0.8571 mg/g). The adsorption capacity of ${\mathrm{PO}}_4^{3-} $-P was as follows: phosphorus removal filter (4.2424 mg/g) > biological filter (2.7917 mg/g) > vermiculite (1.6250 mg/g) > ceramsite (1.2105 mg/g) > volcanic rock (1.1579 mg/g) > zeolite (0.5625 mg/g). The adsorption properties of different mineral-based fillers for ${\mathrm{NH}}_4^+ $-N and ${\mathrm{PO}}_4^{3-} $-P were related to their specific surface area, micropore structure, mineral composition and metal element content, etc. Among them, zeolite had the largest specific surface area and cation exchange capacity, thus exhibiting the strongest adsorption capacity for ${\mathrm{NH}}_4^+ $-N. The biological filter and phosphorus removal filter contained tobermolite, calcium, iron and other components with strong phosphorus binding ability, which removed ${\mathrm{PO}}_4^{3-} $-P from contaminated water obviously. On the whole, zeolite and vermiculite could be used for the treatment of ammonia nitrogen contaminated water, and biological filter and phosphorus removal filter could be chosen to remove phosphorus. When treating contaminated water containing both ammonia nitrogen and phosphorus, a variety of mineral-based fillers could be combined. Compared with other mineral fillers, the self-developed biological and phosphorus removal filters had obvious advantages in the simultaneous removal of nitrogen and phosphorus, and could be used as the optimal substrate fillers for ecological restoration projects of contaminated water.
- mineral-based fillers /
- ammonia nitrogen /
- phosphorus /
- adsorption /
- ecological restoration

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图 1 不同矿物基填料的XRD图谱

注：C—CaCO₃；Q—石英；M—珍珠云母；P—金云母；G—斜方钙沸石；H—片沸石；T—托贝莫来石；Ca—硅钙石。

Figure 1. XRD patten of different mineral-based fillers

下载: 全尺寸图片幻灯片

图 2 不同矿物基填料的扫描电子显微镜图

Figure 2. SEM pictures of different mineral-based fillers

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图 3 不同矿物基填料对水体中${\bf{NH}}_4^+ $-N的吸附动力学、吸附等温线及拟合结果

Figure 3. Adsorption kinetics and adsorption isotherms of ${\mathrm{NH}}_4^+ $-N on different mineral-based fillers and their fitting lines

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图 4 不同矿物基填料对水体中${\bf{PO}}_4^{3-} $-P的吸附动力学、吸附等温线及拟合结果

Figure 4. Adsorption kinetics and adsorption isotherms of ${\mathrm{PO}}_4^{3-} $-P on different mineral-based fillers and their fitting lines

下载: 全尺寸图片幻灯片

表 1 矿物基填料的比表面积、主要元素组成和阳离子交换量分析

Table 1. Specific surface area, main element composition and cation exchange capacity of mineral-based fillers

矿物基填料	比表面积/(m²/g)			元素组成/%								阳离子交换量/ (cmol/kg)
矿物基填料	总表面积	微孔内表面积	外表面积	O	Si	Al	Fe	Ca	K	Na	Mg	阳离子交换量/ (cmol/kg)
沸石	30.491	6.880	23.611	40.573	35.461	7.846	2.884	5.015	3.937	1.683	1.198	55.983
蛭石	13.045	4.436	8.609	33.075	17.955	7.996	22.393	1.417	6.308	0.415	7.621	15.629
火山岩	4.733		5.029	28.249	26.219	10.268	16.395	8.516	1.926	2.788	3.011	4.967
陶粒	4.372		4.372	29.729	31.489	11.988	13.261	1.873	5.398	1.373	2.516	6.767
生物滤料	13.786	2.192	11.594	33.136	19.809	8.491	13.37	14.524	2.137	1.829	3.534	22.043
除磷滤料	10.003	1.761	8.242	33.123	19.048	8.269	13.621	15.237	2.335	1.759	3.219	20.432

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表 2 矿物基填料对水体中${\bf{NH}}_4^+ $-N和${\bf{PO}}_4^{3-} $-P的吸附动力学的伪二级动力学方程拟合结果

Table 2. Fitted results of ${\mathrm{NH}}_4^+ $-N and ${\mathrm{PO}}_4^{3-} $-P adsorption kinetics on mineral-based fillers with the pseudo-second-order kinetic equation

矿物基填料	${\mathrm{NH}}_4^+ $-N			${\mathrm{PO}}_4^{3-} $-P
矿物基填料	k₂/ 〔g/(mg∙h)〕	q_e/(mg/g)	R²	k₂/ 〔g/(mg∙h)〕	q_e/(mg/g)	R²
沸石	20.333 7	0.938 1	1.000 0	−16.1523	0.044 8	0.992 0
蛭石	1.238 5	0.759 4	0.998 7	1.1627	0.169 2	0.973 1
火山岩	−13.309 4	0.259 9	0.998 0	−8.2869	0.029 9	0.899 9
陶粒	−68.248 9	0.026 6	0.996 1	−9.0916	0.031 1	0.968 9
生物滤料	−2.236 8	0.234 8	0.990 2	0.3417	0.529 9	0.978 6
除磷滤料	3.872 1	0.156 6	0.985 1	0.1072	0.602 0	0.860 9

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表 3 矿物基填料对水体中${\bf{NH}}_4^+ $-N吸附等温线的Langmuir和Freundlich方程拟合结果

Table 3. Fitted results of ${\mathrm{NH}}_4^+ $-N adsorption isotherms on mineral-based fillers with Langmuir and Freundlich equation

矿物基填料	Langmiur模型			Freundlich模型
矿物基填料	q_m/(mg/g)	K_L/(L/mg)	R²	K_F/(mg/g)·(mg/L)^−b	b	R²
沸石	5.941 6	0.054 8	0.981 2	0.656 7	0.502 0	0.982 7
蛭石	3.695 3	0.012 8	0.992 0	0.173 0	0.523 0	0.993 4
火山岩	1.000 0	0.006 5	0.997 5	0.038 3	0.495 1	0.989 9
陶粒	0.857 1	0.002 1	0.993 1	0.005 8	0.704 3	0.981 1
生物滤料	3.250 0	0.005 6	0.984 3	0.062 6	0.622 8	0.963 4
除磷滤料	3.138 9	0.003 6	0.986 4	0.032 8	0.690 2	0.970 2

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表 4 矿物基填料对水体中${\bf{PO}}_4^{3-} $-P吸附等温线的Langmuir和Freundlich方程拟合结果

Table 4. Fitting results of ${\rm{PO}}_4^{3-} $-P adsorption isotherms on mineral-based fillers with Langmuir and Freundlich equation

矿物基填料	Langmiur模型			Freundlich模型
矿物基填料	q_m/(mg/g)	K_L/(L/mg)	R²	K_F/(mg/g)·(mg/L)^−b	b	R²
沸石	0.562 5	0.001 6	0.969 4	0.001 3	0.868 8	0.962 4
蛭石	1.625 0	0.002 4	0.999 2	0.007 1	0.814 9	0.996 3
火山岩	1.157 9	0.001 9	0.967 7	0.003 2	0.868 7	0.958 5
陶粒	1.210 5	0.001 9	0.957 1	0.003 3	0.873 8	0.946 9
生物滤料	2.791 7	0.004 8	0.988 9	0.031 6	0.724 6	0.996 0
除磷滤料	4.242 4	0.006 6	0.947 4	0.079 4	0.662 2	0.965 1

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