| Origins of root-mediated pH changes in the rhizosphere and their responses to environmental constraints: a review P Hinsinger, C Plassard, C Tang, B Jaillard Plant and soil 248 (1-2), 43-59, 2003 | 1181 | 2003 |
| Improved tolerance of maize plants to salt stress by arbuscular mycorrhiza is related to higher accumulation of soluble sugars in roots G Feng, F Zhang, X Li, C Tian, C Tang, Z Rengel Mycorrhiza 12 (4), 185-190, 2002 | 512 | 2002 |
| Responses of root architecture development to low phosphorus availability: a review YF Niu, RS Chai, GL Jin, H Wang, CX Tang, YS Zhang Annals of botany 112, 391–408, 2013 | 369 | 2013 |
| The role of plant residues in pH change of acid soils differing in initial pH JM Xu, C Tang, ZL Chen Soil Biology and Biochemistry 38 (4), 709-719, 2006 | 304 | 2006 |
| Interspecific facilitation of nutrient uptake by intercropped maize and faba bean L Li, F Zhang, X Li, P Christie, J Sun, S Yang, C Tang Nutrient Cycling in Agroecosystems 65 (1), 61-71, 2003 | 276 | 2003 |
| Crop yields, soil fertility and phosphorus fractions in response to long-term fertilization under the rice monoculture system on a calcareous soil J Shen, R Li, F Zhang, J Fan, C Tang, Z Rengel Field Crops Research 86 (2-3), 225-238, 2004 | 226 | 2004 |
| Chickpea facilitates phosphorus uptake by intercropped wheat from an organic phosphorus source L Li, C Tang, Z Rengel, F Zhang Plant and soil 243 (1-2), 297-303, 2003 | 221 | 2003 |
| Phosphorus deficiency impairs early nodule functioning and enhances proton release in roots of Medicago truncatula L. C Tang, P Hinsinger, JJ Drevon, B Jaillard Annals of Botany 88 (1), 131-138, 2001 | 219 | 2001 |
| Iron deficiency-induced secretion of phenolics facilitates the reutilization of root apoplastic iron in red clover CW Jin, GY You, YF He, C Tang, P Wu, SJ Zheng Plant Physiology 144 (1), 278-285, 2007 | 214 | 2007 |
| Acid phosphatase role in chickpea/maize intercropping SM Li, L Li, FS Zhang, C Tang Annals of botany 94 (2), 297-303, 2004 | 214 | 2004 |
| Potential role of biochars in decreasing soil acidification - a critical review ZM Dai, X Zhang, C Tang, N Muhammad, J Wu, PC Brookes, JM Xu Science of The Total Environment 581, 601–611, 2017 | 196 | 2017 |
| Impact of chemical composition of legume residues and initial soil pH on pH change of a soil after residue incorporation C Tang, Q Yu Plant and Soil 215 (1), 29-38, 1999 | 194 | 1999 |
| Changes in chemical and biological properties of a sodic clay subsoil with addition of organic amendments GJ Clark, N Dodgshun, PWG Sale, C Tang Soil Biology and Biochemistry 39 (11), 2806-2817, 2007 | 175 | 2007 |
| Role of plant cation/anion uptake ratio in soil acidification C Tang, Z Rengel Handbook of Soil Acidity, 57-81, 2003 | 167 | 2003 |
| Changes and availability of P fractions following 65 years of P application to a calcareous soil in a Mediterranean climate DT Vu, C Tang, RD Armstrong Plant and soil 304 (1), 21-33, 2008 | 146 | 2008 |
| Responses of wheat and barley to liming on a sandy soil with subsoil acidity C Tang, Z Rengel, E Diatloff, C Gazey Field Crops Research 80 (3), 235-244, 2003 | 145 | 2003 |
| Excess cation uptake, and extrusion of protons and organic acid anions by Lupinus albus under phosphorus deficiency L Sas, Z Rengel, C Tang Plant Science 160 (6), 1191-1198, 2001 | 144 | 2001 |
| Application of 16S rDNA-PCR amplification and DGGE fingerprinting for detection of shift in microbial community diversity in Cu-, Zn-, and Cd-contaminated paddy soils Z Li, J Xu, C Tang, J Wu, A Muhammad, H Wang Chemosphere 62 (8), 1374-1380, 2006 | 141 | 2006 |
| Effect of short-term legume residue decomposition on soil acidity C Tang, GP Sparling, CDA McLay, C Raphael Soil Research 37 (3), 561-574, 1999 | 140 | 1999 |
| The role of iron in nodulation and nitrogen fixation in Lupinus angustifolius L C Tang, AD Robson, MJ Dilworth New Phytologist 114 (2), 173-182, 1990 | 134 | 1990 |
Peter W SaleAssociate Professor in Agricultural Science, La Trobe UniversityVerified email at latrobe.edu.au
