[2] NOH Y D, KOMARNENI S, PARK M. Mineral-based slow release fertilizers: a review［J］. Korean Journal of Soil Science and Fertilizer, 2015, 48(1): 1-7.

[3] AL N S E, TJPRC. A review on changes in fertilizers, from coated controlled release fertilizers (CRFs) to nanocomposites of CRFs［J］. International Journal of Agricultural Science and Research, 2019, 9(2): 53-74.

[4] GIRIJAVENI V, REDDY K S, SHARMA K L, et al. Role of zeolites in improving nutrient and water storage capacity of soil and their impact on overall soil quality and crop performance［M］//Soil Science: Fundamentals to Recent Advances. Singapore: Springer Singapore, 2021: 449-467.

[5] NAKHLI S A A, DELKASH M, BAKHSHAYESH B E, et al. Application of zeolites for sustainable agriculture: a review on water and nutrient retention［J］. Water, Air, & Soil Pollution, 2017, 228(12): 1-34.

[6] AGUSTINA T E, RIZKY I. Characterization and utilization of zeolite for NPK slow release fertilizer［J］. International Journal of Engineering, 2018, 31(4): 276-283.

[7] SOLTYS L, MYRONYUK I, TATARCHUK T, et al. Zeolite-based composites as slow release fertilizers (review)［J］. Фｉзика ｉ хｉмｉя твердого тｉла, 2020, 21(1): 89-104.

[12] LOUHAR G, VERMA S, DAHIYA G. Zeolites: a potential source of soil amendments to improve soil properties［J］. Chem Sci Rev Lett, 2020, 9(35): 777-785.

[13] HE X B, HUANG Z B. Zeolite application for enhancing water infiltration and retention in loess soil［J］. Resources, Conservation and Recycling, 2001, 34(1): 45-52.

[14] GHOLIZADEH-SARABI S, SEPASKHAH A R. Effect of zeolite and saline water application on saturated hydraulic conductivity and infiltration in different soil textures［J］. Archives of Agronomy and Soil Science, 2013, 59(5): 753-764.

[15] DE CAMPOS BERNARDI A C, ANCHO OLIVIERA P P, DE MELO MONTE M B, et al. Brazilian sedimentary zeolite use in agriculture［J］. Microporous and Mesoporous Materials, 2013, 167: 16-21.

[16] TALEBNEZHAD R, SEPASKHAH A R. Effects of bentonite on water infiltration in a loamy sand soil［J］. Archives of Agronomy and Soil Science, 2013, 59(10): 1409-1418.

[17] WEA T Y, UNONIS M N A, KHAIRUDDIN M I, et al. Mechanism in using commercial high efficient zeolite-base greenfeed slow release fertilizers［J］. Journal of Agricultural Chemistry and Environment, 2018, 7(1): 1-9.

[18] GREER F R, SHANNON M. Infant methemoglobinemia: the role of dietary nitrate in food and water［J］. Pediatrics, 2005, 116(3): 784-786.

[19] PEA-HARO S, LLOPIS-ALBERT C, PULIDO-VELAZQUEZ M, et al. Fertilizer standards for controlling groundwater nitrate pollution from agriculture: El Salobral-Los Llanos case study, Spain［J］. Journal of Hydrology, 2010, 392(3/4): 174-187.

[20] ENGLERT A H, RUBIO J. Characterization and environmental application of a Chilean natural zeolite［J］. International Journal of Mineral Processing, 2005, 75(1): 21-29.

[21] SFECHIS S, VIDICAN R, SANDOR M, et al. Using assessment of zeolite amendments in agriculture［J］. ProEnvironment, 2015, 8(21): 85-88.

[22] TORMA S, VILCEK J, ADAMISIN P, et al. Influence of natural zeolite on nitrogen dynamics in soil［J］. Turkish Journal of Agriculture and Forestry, 2014, 38: 739-744.

[23] SEPASKHAH A R, YOUSEFI F. Effects of zeolite application on nitrate and ammonium retention of a loamy soil under saturated conditions［J］. Soil Research, 2007, 45(5): 368.

[24] BAERLOCHER C, MCCUSKER L B, OLSON D H. P42/mmc［M］//Atlas of Zeolite Framework Types. Amsterdam: Elsevier, 2007: 74-75.

[25] HUANG Z T, PETROVIC A M. Clinoptilolite zeolite influence on nitrate leaching and nitrogen use efficiency in simulated sand based golf greens［J］. Journal of Environmental Quality, 1994, 23(6): 1190-1194.

[26] PIN-VILLARREAL A R, BAWAZIR A S, SHUKLA M K, et al. Retention and transport of nitrate and ammonium in loamy sand amended with clinoptilolite zeolite［J］. Journal of Irrigation and Drainage Engineering, 2013, 139(9): 755-765.

[27] ASILIAN H, MORTAZAVI S B, KAZEMIAN H, et al. Removal of ammonia from air, using three Iranian natural zeolites［J］. Iranian Journal of Public Health, 2004, 33(1): 45-51.

[28] AHMED O, YAP C H, MUHAMAD A B N. Minimizing ammonia loss from urea through mixing with zeolite and acid sulphate soil［J］. International Journal of Physical Sciences, 2010, 5: 2198-2202.

[29] KURODA K, HANAJIMA D, FUKUMOTO Y, et al. Isolation of thermophilic ammonium-tolerant bacterium and its application to reduce ammonia emission during composting of animal wastes［J］. Bioscience, Biotechnology, and Biochemistry, 2004, 68(2): 286-292.

[30] BAUTISTA J M, KIM H, AHN D H, et al. Changes in physicochemical properties and gaseous emissions of composting swine manure amended with alum and zeolite［J］. Korean Journal of Chemical Engineering, 2011, 28(1): 189-194.

[31] LEGGO P J. The efficacy of the organo-zeolitic bio-fertilizer［J］. Agrotechnology, 2015, 4(1): 1000130.

[32] QIAN J H, DORAN J W, WEIER K L, et al. Soil denitrification and nitrous oxide losses under corn irrigated with high-nitrate groundwater［J］. Journal of Environmental Quality, 1997, 26(2): 348-360.

[33] TAHERI-SODEJANI H, GHOBADINIA M, TABATABAEI S H, et al. Using natural zeolite for contamination reduction of agricultural soil irrigated with treated urban wastewater［J］. Desalination and Water Treatment, 2015, 54(10): 2723-2730.

[34] BHARDWAJ D, SHARMA M, SHARMA P, et al. Synthesis and surfactant modification of clinoptilolite and montmorillonite for the removal of nitrate and preparation of slow release nitrogen fertilizer［J］. Journal of Hazardous Materials, 2012, 227/228: 292-300.

[35] PAGLIARI P H, STROCK J S, ROSEN C J. Changes in soil pH and extractable phosphorus following application of Turkey manure incinerator ash and triple superphosphate［J］. Communications in Soil Science and Plant Analysis, 2010, 41(12): 1502-1512.

[36] RAJPU T. Influence of incubation period, temperature and different phosphate levels on phosphate adsorption in soil［J］. American Journal of Agricultural and Biological Sciences, 2014, 9(2): 251-260.

[37] SHARPLEY A N, HERRON S, DANIEL T. Overcoming the challenges of phosphorus-based management in poultry farming［J］. Journal of Soil and Water Conservation, 2007, 62(6): 375-389.

[38] TELES A P B, RODRIGUES M, PAVINATO P S. Solubility and efficiency of rock phosphate fertilizers partially acidulated with zeolite and pillared clay as additives［J］. Agronomy, 2020, 10(7): 918.

[39] PICKERING H W, MENZIES N W, HUNTER M N. Zeolite/rock phosphate: a novel slow release phosphorus fertilizer for potted plant production［J］. Scientia Horticulturae, 2002, 94(3/4): 333-343.

[40] WU P X, LIAO Z W. Study on structural characteristics of pillared clay modified phosphate fertilizers and its increase efficiency mechanism［J］. Journal of Zhejiang University Science B, 2005, 6(3): 195-201.

[41] BANSIWAL A K, RAYALU S S, LABHASETWAR N K, et al. Surfactant-modified zeolite as a slow release fertilizer for phosphorus［J］. Journal of Agricultural and Food Chemistry, 2006, 54(13): 4773-4779.

[42] LANCELLOTTI I, TOSCHI T, PASSAGLIA E, et al. Release of agronomical nutrient from zeolitite substrate containing phosphatic waste［J］. Environmental Science and Pollution Research International, 2014, 21(23): 13237-13242.

[43] FUJINUMA R, HUNTER M, MENZIES N. Sunflowers drive acid dissolution of rock phosphate when banded with ammonium zeolite［J］. Acta Horticulturae, 2015(1104): 21-28.

[44] MING D W, ALLEN E R. Use of natural zeolites in agronomy, horticulture and environmental soil remediation［J］. Reviews in Mineralogy and Geochemistry, 2001, 45(1): 619-654.

[45] MORAETIS D, PAPAGIANNIDOU S, PRATIKAKIS A, et al. Effect of zeolite application on potassium release in sandy soils amended with municipal compost［J］. Desalination and Water Treatment, 2016, 57(28): 13273-13284.

[46] GL A, EROUL D, ONGUN A R. Comparison of the use of zeolite and perlite as substrate for crisp-head lettuce［J］. Scientia Horticulturae, 2005, 106(4): 464-471.

[47] RABAI K, KASIM O. Use of formulated nitrogen, phosphorus, and potassium compound fertilizerusing clinoptilolite zeolite in maize (zea mays L.) cultivation［J］. Emirates Journal of Food and Agriculture, 2013, 25(9): 713.

[48] LIN L, LEI Z F, WANG L, et al. Adsorption mechanisms of high-levels of ammonium onto natural and NaCl-modified zeolites［J］. Separation and Purification Technology, 2013, 103: 15-20.

[49] ESLAMI M, KHORASSANI R, FOTOVAT A, et al. NH+4-K+ co-loaded clinoptilolite as a binary fertilizer［J］. Archives of Agronomy and Soil Science, 2020, 66(1): 33-45.

[50] HASBULLAH N A, AHMED O H, AB MAJID N M. Effects of amending phosphatic fertilizers with clinoptilolite zeolite on phosphorus availability and its fractionation in an acid soil［J］. Applied Sciences, 2020, 10(9): 3162.

[51] ZHENG J L, CHEN T T, WU Q, et al. Effect of zeolite application on phenology, grain yield and grain quality in rice under water stress［J］. Agricultural Water Management, 2018, 206: 241-251.

[55] CATLI N J, MIGO V P, ALFAFARA C G, et al. Optimization of the production of a complete fertilizer formulation by batch impregnation using clinoptilolite zeolite as carrier［J］. IOP Conference Series: Materials Science and Engineering, 2020, 778(1): 012066.

[56] SZATANIK-KLOC A, SZEREMENT J, ADAMCZUK A, et al. Effect of low zeolite doses on plants and soil physicochemical properties［J］. Materials (Basel, Switzerland), 2021, 14(10): 2617.

[57] OZBAHCE A, TARI A F, GNLAL E, et al. The effect of zeolite applications on yield components and nutrient uptake of common bean under water stress［J］. Archives of Agronomy and Soil Science, 2015, 61(5): 615-626.

[58] IPPOLITO J A, TARKALSON D D, LEHRSCH G A. Zeolite soil application method affects inorganic nitrogen, moisture, and corn growth［J］. Soil Science, 2011, 176(3): 136-142.

[59] ZWINGMANN N, SINGH B, MACKINNON I D R, et al. Zeolite from alkali modified kaolin increases NH+4 retention by sandy soil: column experiments［J］. Applied Clay Science, 2009, 46(1): 7-12.

[60] WEBER M A, BARBARICK K A, WESTFALL D G. Ammonium adsorption by a zeolite in a static and a dynamic system［J］. Journal of Environmental Quality, 1983, 12(4): 549-552.

[61] PERRIN T S, DROST D T, BOETTINGER J L, et al. Ammonium-loaded clinoptilolite: a slow-release nitrogen fertilizer for sweet corn［J］. Journal of Plant Nutrition, 1998, 21(3): 515-530.

[62] MALEKIAN R, ABEDI-KOUPAI J, ESLAMIAN S S. Influences of clinoptilolite and surfactant-modified clinoptilolite zeolite on nitrate leaching and plant growth［J］. Journal of Hazardous Materials, 2011, 185(2/3): 970-976.

[64] DUBEY A, MAILAPALLI D R. Zeolite coated urea fertilizer using different binders: fabrication, material properties and nitrogen release studies［J］. Environmental Technology & Innovation, 2019, 16: 100452.

[65] MIHOK F, MACKO J, ORIAK A, et al. Controlled nitrogen release fertilizer based on zeolite clinoptilolite: study of preparation process and release properties using molecular dynamics［J］. Current Research in Green and Sustainable Chemistry, 2020, 3: 100030.

[66] TSINTSKALADZE G, EPRIKASHVILI L, URUSHADZE T, et al. Nanomodified natural zeolite as a fertilizer of prolonged activity［J］. Annals of Agrarian Science, 2016, 14(3): 163-168.

[67] JHA V K, HAYASHI S. Modification on natural clinoptilolite zeolite for its NH+4 retention capacity［J］. Journal of Hazardous Materials, 2009, 169(1/2/3): 29-35.

[68] LI Z H, ZHANG Y P. Use of surfactant-modified zeolite to carry and slowly release sulfate［J］. Desalination and Water Treatment, 2010, 21(1/2/3): 73-78.

[69] THIRUNAVUKKARASU M, SUBRAMANIAN K S. Surface modified nano-zeolite used as carrier for slow release of sulphur［J］. Journal of Applied and Natural Science, 2014, 6(1): 19-26.

[70] KHAN M Z H, ISLAM M R, NAHAR N, et al. Synthesis and characterization of nanozeolite based composite fertilizer for sustainable release and use efficiency of nutrients［J］. Heliyon, 2021, 7(1): e06091.

[71] PIMSEN R, PORRAWATKUL P, NUENGMATCHA P, et al. Efficiency enhancement of slow release of fertilizer using nanozeolite-chitosan/sago starch-based biopolymer composite［J］. Journal of Coatings Technology and Research, 2021, 18(5): 1321-1332.

[72] LATEEF A, NAZIR R, JAMIL N, et al. Synthesis and characterization of zeolite based nano-composite: an environment friendly slow release fertilizer［J］. Microporous and Mesoporous Materials, 2016, 232: 174-183.

[73] JUMAER I, SUMARNI W, NINGRUM L W, et al. Using of low grade zeolite based fly ash as slow release agent for zea mays growth［J］. Journal of Physics: Conference Series, 2020, 1567(2): 022036.

[74] LI J, ZHUANG X G, FONT O, et al. Synthesis of merlinoite from Chinese coal fly ashes and its potential utilization as slow release K-fertilizer［J］. Journal of Hazardous Materials, 2014, 265: 242-252.

[75] FLORES C G, SCHNEIDER H, MARCILIO N R, et al. Potassic zeolites from Brazilian coal ash for use as a fertilizer in agriculture［J］. Waste Management, 2017, 70: 263-271.

[78] HERMASSI M, VALDERRAMA C, FONT O, et al. Phosphate recovery from aqueous solution by K-zeolite synthesized from fly ash for subsequent valorisation as slow release fertilizer［J］. Science of the Total Environment, 2020, 731: 139002.

[79] BONETTI B, WALDOW E C, TRAPP G, et al. Production of zeolitic materials in pilot scale based on coal ash for phosphate and potassium adsorption in order to obtain fertilizer［J］. Environmental Science and Pollution Research International, 2021, 28(3): 2638-2654.