Contactless Conductivity Microfluidic Chip for Rapid Determination of Soil Nitrogen and Potassium Content

doi:10.12133/j.smartag.SA202309022

Abstract

Abstract:

Objective The content of nitrogen (N) and potassium (K) in the soil directly affects crop yield, making it a crucial indicator in agricultural production processes. Insufficient levels of the two nutrients can impede crop growth and reduce yield, while excessive levels can result in environmental pollution. Rapidly quantifying the N and K content in soil is of great importance for agricultural production and environmental protection. Methods A rapid and quantitative method was proposed for detecting N and K nutrient ions in soil based on polydimethylsiloxane (PDMS) microfluidic chip electrophoresis and capacitively coupled contactless conductivity detection (C⁴D). Microfluidic chip electrophoresis enables rapid separation of multiple ions in soil. The electrophoresis microfluidic chips have a cross-shaped channel layout and were fabricated using soft lithography technology. The sample was introduced into the microfluidic chip by applying the appropriate injection voltage at both ends of the injection channel. This simple and efficient procedure ensured an accurate sample introduction. Subsequently, an electrophoretic voltage was applied at both ends of the separation channel, creating a capillary zone electrophoresis that enables the rapid separation of different ions. This process offered high separation efficiency, required a short processing time, and had a small sample volume requirement. This enabled the rapid processing and analysis of many samples. C⁴D enabled precise measurement of changes in conductivity. The sensing electrodes were separated from the microfluidic chips and printed onto a printed circuit board (PCB) using an immersion gold process. The ions separated under the action of an electric field and sequentially reach the sensing electrodes. The detection circuit, connected to the sensing electrodes, received and regulated the conductivity signal to reflect the variance in conductivity between the sample and the buffer solution. The sensing electrodes were isolated from the sample solution to prevent interference from the high-voltage electric field used for electrophoresis. Results and Discussions The voltage used for electrophoresis, as well as the operating frequency and excitation voltage of the excitation signal in the detection system, had a significant effect on separation and detection performance. Based on the response characteristics of the system output, the optimal operating frequency of 1 000 kHz, excitation voltage of 50 V, and electrophoresis voltage of 1.5 kV were determined. A peak overshoot was observed in the electrophoresis spectrum, which was associated with the operating frequency of the system. The total noise level of the system was approximately 0.091 mV. The detection limit (S/N = 3) for soil nutrient ions was determined by analyzing a series of standard sample solutions with varying concentrations. The detection limited for potassium (K⁺), ammonium (NH₄⁺), and nitrate (NO₃^‒) standard solutions were 0.5, 0.1 and 0.4 mg/L, respectively. For the quantitative determination of soil nutrient ion concentration, the linear relationship between peak area and corresponding concentration was investigated under optimal experimental conditions. K⁺, NH₄⁺, and NO₃^‒ exhibit a strong linear relationship in the range of 0.5~40 mg/L, with linear correlation coefficients (R²) of 0.994, 0.997, and 0.990, respectively, indicating that this method could accurately quantify N and K ions in soil. At the same time, to evaluate the repeatability of the system, peak height, peak area, and peak time were used as evaluation indicators in repeatability experiments. The relative standard deviation (RSD) was less than 4.4%, indicating that the method shows good repeatability. In addition, to assess the ability of the C⁴D microfluidic system to detect actual soil samples, four collected soil samples were tested using MES/His and PVP/PTAE as running buffers. K⁺, NH₄⁺,Na⁺, Chloride (Cl^‒), NO₃^‒, and sulfate (SO₄^3‒) were separated sequentially within 1 min. The detection efficiency was significantly improved. To evaluate the accuracy of this method, spiked recovery experiments were performed on four soil samples. The recovery rates ranged from 81.74% to 127.76%, indicating the good accuracy of the method. Conclusions This study provides a simple and effective method for the rapid detection of N and K nutrient ions in soil. The method is highly accurate and reliable, and it can quickly and efficiently detect the contents of N and K nutrient ions in soil. This contactless measurement method reduced costs and improved economic efficiency while extending the service life of the sensing electrodes and reducing the frequency of maintenance and replacement. It provided strong support for long-term, continuous conductivity monitoring.

Key words: contactless conductivity detection, microfluidic chip, soil nutrient, polydimethylsiloxane

HONG Yan, WANG Le, WANG Rujing, SU Jingming, LI Hao, ZHANG Jiabao, GUO Hongyan, CHEN Xiangyu. Contactless Conductivity Microfluidic Chip for Rapid Determination of Soil Nitrogen and Potassium Content[J]. Smart Agriculture, 2024, 6(1): 18-27.

Figures/Tables 9

Fig. 1

Fig. 2

Fig. 3

Fig. 4

Fig. 5

Fig. 6

Table 1

Fig. 7

Fig. 8

References 29

1	POTDAR R P, SHIROLKAR M M, VERMA A J, et al. Determination of soil nutrients (NPK) using optical methods: A mini review[J]. Journal of plant nutrition, 2021, 44(12): 1826-1839.
2	DELPHINE M, BARDGETT R D, FINLAY R D, et al. A plant perspective on nitrogen cycling in the rhizosphere[J]. Functional ecology, 2019, 33(4): 540-552.
3	陶曙华, 王洁敏, 苗雪雪, 等. 高氯酸-氢氟酸联合消解法测定土壤中全量氮磷钾[J].中国测试, 2022, 48(9): 78-83.
	TAO S H, WANG J M, MIAO X X, et al. Determination the total amount of nitrogen, phosphorus and potassium in the soil by perchloric acid-hydrofluoric acid digesting system[J]. China measurement & test, 2022, 48(9): 78-83.
4	PAN X Y, LYU J L, DYCK M, et al. Bibliometric analysis of soil nutrient research between 1992 and 2020[J]. Agriculture, 2021, 11(3): ID 223.
5	CHEN Z H, DOLFING J, ZHUANG S Y, et al. Periphytic biofilms-mediated microbial interactions and their impact on the nitrogen cycle in rice paddies[J]. Eco-environment & health, 2022, 1(3): 172-180.
6	李学兰, 李德成, 郑光辉, 等. 可见-近红外与中红外光谱预测土壤养分的比较研究[J/OL]. 土壤学报. [2023-09-10].
	LI X L, LI D C, ZHENG G H, et al. Comparative study on prediction of soil nutrients by visible-near infrared and mid-infrared spectroscopy[J/OL]. Acta pedologica sinica. [2023-09-10].
7	BRONDI A M, DANIEL J S P, DE CASTRO V X M, et al. Quantification of humic and fulvic acids, macro- and micronutrients and C/N ratio in organic fertilizers[J]. Communications in soil science and plant analysis, 2016, 47(22): 2506-2513.
8	刘雪梅. 近红外漫反射光谱检测土壤有机质和速效N的研究[J]. 中国农机化学报, 2013, 34(2): 202-206.
	LIU X M. Near infrared diffuse reflectance spectra detection of soil organic matter and available N[J]. Journal of Chinese agricultural mechanization, 2013, 34(2): 202-206.
9	BARTHÈS B G, BRUNET D, HIEN E, et al. Determining the distributions of soil carbon and nitrogen in particle size fractions using near-infrared reflectance spectrum of bulk soil samples[J]. Soil biology and biochemistry, 2008, 40(6): 1533-1537.
10	BECHLIN M A, FORTUNATO F M, SILVA R MDA, et al. A simple and fast method for assessment of the nitrogen-phosphorus-potassium rating of fertilizers using high-resolution continuum source atomic and molecular absorption spectrometry[J]. Spectrochimica acta part B: Atomic spectroscopy, 2014, 101: 240-244.
11	WEI Y Y, WANG R J, ZHANG J Q, et al. Partition management of soil nutrients based on capacitive coupled contactless conductivity detection[J]. Agriculture, 2023, 13(2): ID 313.
12	张俊卿, 高钧, 陈翔宇,等. 土壤钾离子非接触电导检测装置设计与试验[J]. 农业机械学报, 2018, 49(S1): 360-364, 392.
	ZHANG J Q, GAO J, CHEN X Y, et al. Design and experiment of capacitively-coupled contactless conductivity detection device for rapid measurement of soil potassium ion[J]. Transactions of the Chinese society for agricultural machinery, 2018, 49(S1): 360-364, 392.
13	PAUL P, SÄNGER-VAN DE GRIEND C, ADAMS E, et al. Recent advances in the capillary electrophoresis analysis of antibiotics with capacitively coupled contactless conductivity detection[J]. Journal of pharmaceutical and biomedical analysis, 2018, 158: 405-15.
14	TŮMA P. Determination of amino acids by capillary and microchip electrophoresis with contactless conductivity detection: Theory, instrumentation and applications[J]. Talanta, 2021, 224: ID 121922.
15	ZHANG J Q, WANG R J, JIN Z, et al. Development of on-site rapid detection device for soil macronutrients based on capillary electrophoresis and capacitively coupled contactless conductivity detection (C⁴D) method[J]. Chemosensors, 2022, 10(2): ID 84.
16	张俊卿, 陈翔宇, 王儒敬, 等. 用于水肥系统的养分离子快检装置研制与试验[J]. 农业工程学报, 2022, 38(2): 102-110.
	ZHANG J Q, CHEN X Y, WANG R J, et al. Development and experiment of the rapid detection device of the nutrient ion concentrations for fertigation system[J]. Transactions of the Chinese society of agricultural engineering, 2022, 38(2): 102-110.
17	OU X W, CHEN P, HUANG X Z, et al. Microfluidic chip electrophoresis for biochemical analysis[J]. Journal of separation science, 2020, 43(1): 258-270.
18	RIBEIRO DA SILVA M, ZABOROWSKA I, CARILLO S, et al. A rapid, simple and sensitive microfluidic chip electrophoresis mass spectrometry method for monitoring amino acids in cell culture media[J]. Journal of chromatography A, 2021, 1651: ID 462336.
19	DE CASTRO COSTA B M, GRIVEAU S, D'ORLYE F, et al. Microchip electrophoresis and electrochemical detection: A review on a growing synergistic implementation[J]. Electrochimica acta, 2021, 391: ID 138928.
20	TŮMA P. Progress in on-line, at-line, and in-line coupling of sample treatment with capillary and microchip electrophoresis over the past 10 years: A review[J]. Analytica chimica acta, 2023, 1261: ID 341249.
21	CHONG K C, THANG L Y, QUIRINO J P, et al. Monitoring of vancomycin in human plasma via portable microchip electrophoresis with contactless conductivity detector and multi-stacking strategy[J]. Journal of chromatography A, 2017, 1485: 142-6.
22	TŮMA P. Monitoring of biologically active substances in clinical samples by capillary and microchip electrophoresis with contactless conductivity detection: A review[J]. Analytica chimica acta, 2022, 1225: ID 340161.
23	PINHEIRO K M P, DUARTE L M, RODRIGUES M F, et al. Determination of naphthenic acids in produced water by using microchip electrophoresis with integrated contactless conductivity detection[J]. Journal of chromatography A, 2022, 1677: ID 463307.
24	FREITAS C B, MOREIRA R C, DE OLIVEIRA TAVARES M G, et al. Monitoring of nitrite, nitrate, chloride and sulfate in environmental samples using electrophoresis microchips coupled with contactless conductivity detection[J]. Talanta, 2016, 147: 335-341.
25	PINHEIRO K M P, MOREIRA R C, REZENDE K C A, et al. Rapid separation of post-blast explosive residues on glass electrophoresis microchips[J]. Electrophoresis, 2019, 40(3): 462-468.
26	ALHAKIMI A, 陈缵光. 微流控芯片非接触电导法测定药品中的精氨酸布洛芬含量[J]. 分析测试学报, 2017, 36(9): 1129-1132.
	ALHAKIMI A, CHEN Z G. Determination of ibuprofen arginine by contactless conductivity detection with microfluidic chip[J]. Journal of instrumental analysis, 2017, 36(9): 1129-1132.
27	SMOLKA M, PUCHBERGER-ENENGL D, BIPOUN M, et al. A mobile lab-on-a-chip device for on-site soil nutrient analysis[J]. Precision agriculture, 2017, 18(2): 152-168.
28	XU Z, WANG X R, WEBER R J, et al. Nutrient sensing using chip scale electrophoresis and in situ soil solution extraction[J]. IEEE sensors journal, 2017, 17(14): 4330-4339.
29	THREDGOLD L D, KHODAKOV D A, ELLIS A V, et al. Optimization of physical parameters of 'injected' metal electrodes for capacitively coupled contactless conductivity detection on poly (dimethylsiloxane) microchips[C]// Proc. SPIE 8923, Micro/Nano Materials, Devices, and Systems. Burlingame, California, USA: SPIE. 2013: ID 89234D.

离子	峰高/mV	峰面积/mV×min	出峰时间/min
K⁺	3.32	1.88	1.82
NH₄ ⁺	3.84	1.3	4.34
NO₃ ^‒	2.32	3.29	0.82

[1]	WANG Rujing. Agricultural Sensor: Research Progress, Challenges and Perspectives [J]. Smart Agriculture, 2024, 6(1): 1-17.
[2]	TANG Chaoli, LI Hao, WANG Rujing, WANG Le, HUANG Qing, WANG Dapeng, ZHANG Jiabao, CHEN Xiangyu. Automatic Identification Method for Spectral Peaks of Soil Nutrient Ions Using Contactless Conductivity Detection [J]. Smart Agriculture, 2024, 6(1): 36-45.
[3]	JIAO Leizi, DONG Daming, ZHAO Xiande, TIAN Hongwu. Near-Field Telemetry Detection of Soil Nutrient Based on Modulated Near-Infrared Reflectance Spectrum [J]. Smart Agriculture, 2020, 2(2): 59-66.