1.
Bioavailability of soil inorganic P in the rhizosphere as affected by root-induced chemical changes: a review
by HINSINGER, Philippe
Plant and soil, 2001-12-01, Vol.237 (2), p.173-195
2.
Plant-microbe-soil interactions in the rhizosphere: an evolutionary perspective
by Lambers, Hans
Plant and soil, 2009-08-01, Vol.321 (1/2), p.83-115
3.
Rhizosphere: biophysics, biogeochemistry and ecological relevance
by Hinsinger, Philippe
Plant and soil, 2009-08-01, Vol.321 (1/2), p.117-152
4.
Origins of root-mediated pH changes in the rhizosphere and their responses to environmental constraints: A review
by Hinsinger, Philippe
Plant and soil, 2003-01-01, Vol.248 (1/2), p.43-59
5.
Advances in the rhizosphere: stretching the interface of life
by Mommer, Liesje
Plant and soil, 2016-10-01, Vol.407 (1/2), p.1-8
6.
Acquisition of phosphorus and other poorly mobile nutrients by roots. Where do plant nutrition models fail?
by Hinsinger, Philippe
Plant and soil, 2011-11-01, Vol.348 (1/2), p.29-61
7.
Copper phytotoxicity affects root elongation and iron nutrition in durum wheat (Triticum turgidum durum L.)
by Michaud, Aurélia M
Plant and soil, 2008-01-01, Vol.310 (1/2), p.151-165
8.
Root-induced processes controlling phosphate availability in soils with contrasted P-fertilized treatments
by Devau, Nicolas
Plant and soil, 2011-11-01, Vol.348 (1/2), p.203-218
9.
Copper uptake kinetics in hydroponically-grown durum wheat (Triticum turgidum durum L.) as compared with soil's ability to supply copper
by Bravin, Matthieu N
Plant and soil, 2010-06-01, Vol.331 (1/2), p.91-104
10.
Copper concentration in plants and in the rhizosphere as influenced by the iron status of tomato (Lycopersicon esculentum L.)
by YVES CORNU, Jean
Plant and soil, 2007-03-01, Vol.292 (1/2), p.63-77
11.
Zinc mobilisation from a contaminated soil by three genotypes of tobacco as affected by soil and rhizosphere pH
by Loosemore, Nancy
Plant and soil, 2004-01-01, Vol.260 (1/2), p.19-32
12.
Dynamics of phosphorus fractions in the rhizosphere of common bean (Phaseolus vulgaris L.) and durum wheat (Triticum turgidum durum L.) grown in monocropping and intercropping syst...
by Li, H
Plant and soil, 2008-01-01, Vol.312 (1/2), p.139-150
13.
Copper uptake and phytotoxicity as assessed in situ for durum wheat (Triticum turgidum durum L.) cultivated in Cu-contaminated, former vineyard soils
by MICHAUD, A. M
Plant and soil, 2007-09-01, Vol.298 (1/2), p.99-111
14.
Endogeic earthworms modify soil phosphorus, plant growth and interactions in a legume-cereal intercrop
by Coulis, M
Plant and soil, 2014-06-01, Vol.379 (1/2), p.149-160
15.
Rhizosphere alkalisation — a major driver of copper bioavailability over a broad pH range in an acidic, copper-contaminated soil
by BRAVIN, M. N
Plant and soil, 2009-05-01, Vol.318 (1/2), p.257-268
16.
EDITORIAL: Rhizosphere—perspectives and challenges—a tribute to Lorenz Hiltner 12–17 September 2004—Munich, Germany
by Philippe Hinsinger
Plant and soil, 2006-05-01, Vol.283 (1/2), p.vii-viii
17.
Copper bioavailability and rhizosphere pH changes as affected by nitrogen supply for tomato and oilseed rape cropped on an acidic and a calcareous soil
by CHAIGNON, V
Plant and soil, 2002-06-01, Vol.243 (2), p.219-228
18.
New approaches to studying chemical and physical changes in the rhizosphere: an overview
by Gregory, P.J. (Reading Univ. (United Kingdom). Dept. of Soil Science)
Plant and soil, 1999, Vol.211 (1), p.1-9
19.
Dynamics of phosphorus in the rhizosphere of maize and rape grown on synthetic, phosphated calcite and goethite
by Bertrand, I. (Unite de Formation et de Recherche INRA, Montpellier (France).)
Plant and soil, 1999, Vol.211 (1), p.111-119
20.
Root uptake and translocation of radiocaesium from agricultural soils by various plant species
by STAUNTON, S
Plant and soil, 2003-07-01, Vol.254 (2), p.443-455
