1 |
HUSSAIN B, ASHRAF M N, SHAFEEQ UR R, et al.. Cadmium stress in paddy fields: effects of soil conditions and remediation strategies [J/OL]. Sci. Total Environ. , 2021, 754: 142188 [2022-02-20]. .
|
2 |
ZHAO F J, MA Y, ZHU Y G, et al.. Soil contamination in China: current status and mitigation strategies [J]. Environ. Sci. Technol., 2015, 49(2): 750-759.
|
3 |
SUN Y, XU Y, XU Y, et al.. Reliability and stability of immobilization remediation of Cd polluted soils using sepiolite under pot and field trials [J]. Environ. Pollut., 2016, 208: 739-746.
|
4 |
SHI T, MA J, WU X, et al.. Inventories of heavy metal inputs and outputs to and from agricultural soils: a review [J]. Ecotoxicol. Environ. Saf., 2018, 164: 118-124.
|
5 |
QIAO K, WANG F, LIANG S, et al.. New biofortification tool: wheat TaCNR5 enhances zinc and manganese tolerance and increases zinc and manganese accumulation in rice grains [J]. J. Agric. Food Chem., 2019, 67(35): 9877-9884.
|
6 |
ZHANG L, ZHANG C, DU B, et al.. Effects of node restriction on cadmium accumulation in eight Chinese wheat (Triticum turgidum) cultivars [J/OL]. Sci. Total Environ. , 2020, 725: 138358[2022-02-20]. .
|
7 |
LIANG X, STRAWN D G, CHEN J, et al.. Variation in cadmium accumulation in spring wheat cultivars: uptake and redistribution to grain [J]. Plant Soil, 2017, 421(1-2): 219-231.
|
8 |
LIU N, HUANG X, SUN L, et al.. Screening stably low cadmium and moderately high micronutrients wheat cultivars under three different agricultural environments of China [J/OL]. Chemosphere, 2020, 241: 125065 [2022-02-20]. .
|
9 |
RIZWAN M, ALI S, ABBAS T, et al.. Cadmium minimization in wheat: a critical review [J]. Ecotoxicol. Environ. Saf., 2016, 130: 43-53.
|
10 |
GRUTER R, COSTEROUSSE B, MAYER J, et al.. Long-term organic matter application reduces cadmium but not zinc concentrations in wheat [J]. Sci. Total Environ., 2019, 669: 608-620.
|
11 |
ROMANYA J, BLANCO-MORENO J M, SANS F X. Phosphorus mobilization in low-P arable soils may involve soil organic C depletion [J]. Soil Biol. Biochem., 2017, 113: 250-259.
|
12 |
WEYERS E, STRAWN D G, PEAK D, et al.. Phosphorus speciation in calcareous soils following annual dairy manure amendments [J]. Soil Sci. Soc. Am. J., 2016, 80(6): 1531-1542.
|
13 |
OBURGER E, LEITNER D, JONES D L, et al.. Adsorption and desorption dynamics of citric acid anions in soil [J]. Eur. J. Soil Sci., 2011, 62(5): 733-742.
|
14 |
HU Y, GAO Z, HUANG Y, et al.. Impact of poplar-based phytomanagement on metal bioavailability in low-phosphorus calcareous soil with multi-metal contamination [J]. Sci. Total Environ., 2019, 686: 848-855.
|
15 |
CONG W F, SURIYAGODA L D B, LAMBERS H. Tightening the phosphorus cycle through phosphorus-efficient crop genotypes [J]. Trends Plant Sci., 2020, 25(10): 967-975.
|
16 |
VANCE C P, UHDE-STONE C, ALLAN D L. Phosphorus acquisition and use: critical adaptations by plants for securing a nonrenewable resource [J]. New Phytol., 2003, 157(3): 423-447.
|
17 |
POSTMA J A, DATHE A, LYNCH J P. The optimal lateral root branching density for maize depends on nitrogen and phosphorus availability [J]. Plant Physiol., 2014, 166(2): 590-602.
|
18 |
HALING R E, BROWN L K, STEFANSKI A, et al.. Differences in nutrient foraging among Trifolium subterraneum cultivars deliver improved P-acquisition efficiency [J]. Plant Soil, 2018, 424(1): 539-554.
|
19 |
HINSINGER P, PLASSARD C, TANG C X, et al.. Origins of root-mediated pH changes in the rhizosphere and their responses to environmental constraints: a review [J]. Plant Soil, 2003, 248(1): 43-59.
|
20 |
RICHARDSON A E, LYNCH J P, RYAN P R, et al.. Plant and microbial strategies to improve the phosphorus efficiency of agriculture [J]. Plant Soil, 2011, 349(1): 121-156.
|
21 |
PANG J, BANSAL R, ZHAO H, et al.. The carboxylate-releasing phosphorus-mobilizing strategy can be proxied by foliar manganese concentration in a large set of chickpea germplasm under low phosphorus supply [J]. New Phytol., 2018, 219(2): 518-529.
|
22 |
邢维芹, 张红毅, SCHECKEL Kirk G., 等. 铅冶炼污染区小麦籽粒镉含量及低积累品种筛选 [J]. 农业环境科学学报, 2015, 34(10): 2039-2040.
|
|
XING W Q, ZHANG H Y, SCHECKEL K G, et al.. Grain Cd concentrations of 100 wheat(Triticum aestivum L.) varieties and strains grown on lead-smelting contaminated soils and screening for low Cd varieties [J]. J. Agro-Environ. Sci., 2015, 34(10): 2039-2040.
|
23 |
MA S, NAN Z, HU Y, et al.. Phosphorus supply level is more important than wheat variety in safe utilization of cadmium-contaminated calcareous soil [J/OL]. J. Hazard. Mater., 2022, 424: 127224 [2022-02-20]. .
|
24 |
LUO L, MA Y, SANDERS R L, et al.. Phosphorus speciation and transformation in long-term fertilized soil: evidence from chemical fractionation and P K-edge XANES spectroscopy [J]. Nutr. Cycl. Agroecosystems, 2017, 107(2): 215-226.
|
25 |
屈锋,牟世芬,侯小平,等. 小麦根系中有机酸的离子色谱法分析研究 [J]. 色谱, 1995(5): 395-397.
|
|
QU F, MOU S F, HOU X P, et al.. Determination of organic acids in wheat-root by lon chromatography [J]. Chin. J. Chromatography, 1995(5): 395-397.
|
26 |
LAMBERS H, SHANE M W, CRAMER M D, et al.. Root structure and functioning for efficient acquisition of phosphorus: matching morphological and physiological traits [J]. Ann. Bot., 2006, 98(4): 693-713.
|
27 |
SHEN J, YUAN L, ZHANG J, et al.. Phosphorus dynamics: from soil to plant [J]. Plant Physiol., 2011, 156(3): 997-1005.
|
28 |
MANSKE G, ORTIZ-MONASTERIO J, MVAN GINKEL, et al.. Traits associated with improved P-uptake efficiency in CIMMYT’s semidwarf spring bread wheat grown on an acid Andisol in Mexico [J]. Plant Soil, 2000, 221(2): 189-204.
|
29 |
TENG W, DENG Y, CHEN X P, et al.. Characterization of root response to phosphorus supply from morphology to gene analysis in field-grown wheat [J]. J. Exp. Bot., 2013, 64(5): 1403-1411.
|
30 |
SHEN Q, WEN Z, DONG Y, et al.. The responses of root morphology and phosphorus-mobilizing exudations in wheat to increasing shoot phosphorus concentration [J/OL]. Aob Plants, 2018, 10(5): ply054 [2022-02-20]. .
|
31 |
LIU D. Root developmental responses to phosphorus nutrition [J]. J. Integr. Plant Biol., 2021, 63(6): 1065-1090.
|
32 |
LIU B, LI H, ZHU B, et al.. Complementarity in nutrient foraging strategies of absorptive fine roots and arbuscular mycorrhizal fungi across 14 coexisting subtropical tree species [J]. New Phytol., 2015, 208(1): 125-136.
|
33 |
CHEN W, KOIDE R T, ADAMS T S, et al.. Root morphology and mycorrhizal symbioses together shape nutrient foraging strategies of temperate trees [J]. Proc. Nat. Acad. Sci. USA, 2016, 113(31): 8741-8746.
|
34 |
LI H, LIU B, MCCORMACK M L, et al.. Diverse belowground resource strategies underlie plant species coexistence and spatial distribution in three grasslands along a precipitation gradient [J]. New Phytol., 2017, 216(4): 1140-1150.
|
35 |
MA Z, GUO D, XU X, et al.. Evolutionary history resolves global organization of root functional traits [J]. Nature, 2018, 555(7694): 94-97.
|
36 |
LAMBERS H, HAYES P E, LALIBERTE E, et al.. Leaf manganese accumulation and phosphorus-acquisition efficiency [J]. Trends Plant Sci., 2015, 20(2): 83-90.
|
37 |
WANG Y, LAMBERS H. Root-released organic anions in response to low phosphorus availability: recent progress, challenges and future perspectives [J]. Plant Soil, 2020, 447(1): 135-156.
|
38 |
刘胜亮, 朱舒亮, 李静, 等. 不同有机酸对磷酸三钙溶解能力的研究 [J]. 江西农业大学学报, 2017, 39(5): 1010-1016.
|
|
LIU S L, ZHU S L, LI J, et al.. A study on the ability of different organic acids to dissolve tricalcium phosphate [J]. Acta Agric. Univ. Jiangxiensis, 2017, 39(5): 1010-1016.
|
39 |
ROBIN A L, SANKHLA D. Essential Guide to Food Additives. [M]. 4th Ed n. London: The Royal Society of Chemistry, 2013: 44-64.
|
40 |
YANG P, CHEN H J, FAN H Y, et al.. Phosphorus supply alters the root metabolism of Chinese flowering cabbage (Brassica campestris L. ssp. varchinensis. utilis Tsen et Lee) and the mobilization of Cd bound to lepidocrocite in soil [J/OL]. Environ. Exp. Bot., 2019, 167: 103827 [2020-02-20]. .
|
41 |
EDAYILAM N, MONTGOMERY D, FERGUSON B, et al.. Phosphorus stress-induced changes in plant root exudation could potentially facilitate uranium mobilization from stable mineral forms [J]. Environ. Sci. Technol., 2018, 52(14): 7652-7662.
|
42 |
MAGDZIAK Z, MLECZEK M, RUTKOWSKI P, et al.. Diversity of low-molecular weight organic acids synthesized by salix growing in soils characterized by different Cu, Pb and Zn concentrations [J]. Acta Physiol. Plant, 2017, 39(6): 1-15.
|
43 |
刘桂华, 敖明, 柴冠群, 等. 低分子有机酸对贵州黄壤中镉释放及形态的影响[J]. 土壤通报, 2018, 49(6): 1473-1479.
|
|
LIU G H, AO M, CHAI G Q, et al.. Effects of organic acids with low molecular weight on the extraction and fractionations of cadmium in yellow soil of Guizhou [J]. Chin. J. Soil Sci., 2018, 49(6): 1473-1479.
|
44 |
胡浩, 潘杰, 曾清如, 等. 低分子有机酸淋溶对土壤中重金属Pb Cd Cu和Zn的影响[J]. 农业环境科学学报, 2008 (4): 1611-1616.
|
|
HU H, PAN J, ZENG Q R, et al.. The effects of soil leaching with low molecular weight organic acids on Pb, Cd, Cu and Zn [J]. J. Agro-Environ. Sci., 2008(4): 1611-1616.
|
45 |
魏佳, 李取生, 徐智敏, 等. 多种有机酸对土壤中碳酸镉的活化效应[J]. 环境工程学报, 2017, 11(9): 5298-5306.
|
|
WEI J, LI Q S, XU Z M, et al.. Mobilization effects of various organic acids on cadmium carbonate in soil [J]. Chin. J. Environ. Eng., 2017, 11(9): 5298-5306.
|