PUBLICATIONS
Articles in peer-review journals
22. Thoumazeau A, Bessou C, Renevier MS, Trap J, Marichal R, Mareschal L, Decaens T, Bottinelli N, Jaillard B, Chevallier T, Suvannang N, Sajjaphan K, Thaler P, Gay F, Brauman A (2019) Biofunctool®: a new framework to assess the impact of land management on soil quality. Part A: concept and validation of the set of indicators. Ecological Indicators, 97, 100-110.
21. Ranoarisoa MP, Morel C, Andriamananjara A, Jourdan C, Bernard L, Becquer T, Rabeharisoa L, Rahajaharilaza K, Plassard C, Blanchart E, Trap J (2018) Effects of a bacterivorous nematode on rice 32P uptake and root architecture in a high P-sorbing ferrallitic soil. Soil Biology and Biochemistry, 122, 39-49.
20. Razanamalala K, Fanomezana RA, Razafimbelo T, Chevallier T, Trap J, Blanchart E, Bernard L (2018). The priming effect generated by stoichiometric decomposition and nutrient mining in cultivated tropical soils: Actors and drivers. Applied Soil Ecology, 126, 21-33.
19. Peerawat M, BLaud A, Trap J, Chevallier T, Alonso P, Gay F, Thaler P, Spor A, Sebag D, Choosai C, Suvannang N, Sajjaphan K, Brauman A (2018) Rubber plantation ageing controls soil biodiversity after land conversion from cassava. Agriculture, Ecosystems & Environment 257:92-102
18. Trap J, Akpa‐Vinceslas M, Margerie P, Boudsocq S, Richard F, Decaëns T, Aubert M (2018) Slow decomposition of leaf litter from mature Fagus sylvatica trees promotes offspring nitrogen acquisition by interacting with ectomycorrhizal fungi J Ecol 105:528-539
17. Ranoarisoa MP, Blanchart E, vom Brocke K, Ramanantsoanirina A, Sester M, Plassard C, Cournac L, Trap J (2017) Attractancy of bacterivorous nematodes to root-adhering soils differs according to rice cultivars. Rhizosphere 3:128-131
16. Razanamalala K, Razafimbelo T, Maron PA, Ranjard L, Chemidlin N, Lelièvre M, Ramaroson VH, Marsden C, Becquer T, Trap J, Blanchart E, Bernard L. (2017) Soil microbial diversity drives the priming effect along climate gradients: a case study in Madagascar. The ISME journal 12(2) 451
15. Aubert M, Trap J, Chauvat M, Hedde M, Bureau F (2017) Forest humus forms as a playground for studying aboveground-belowground relationships: Part 2, a case study along the dynamic of a broad lived plain forest ecosystem Applied Soil Ecology. 123: 391-397
14. Trap J, Bonkowski M, Plassard C, Villenave C, Blanchart E (2016) Ecological importance of soil bacterivores for ecosystem functions Plant and Soil 398:1-24
13. Trap J, Akpa‐Vinceslas M, Margerie P, Boudsocq S, Richard F, Decaëns T, Aubert M (2016) Slow decomposition of leaf litter from mature Fagus sylvatica trees promotes offspring nitrogen acquisition by interacting with ectomycorrhizal fungi J Ecol 105(2): 528-539
12. Trap J, Bernard L, Brauman A, Pablo A-L, Plassard C, Ranoarisoa MP, Blanchart E (2015) Plant roots increase bacterivorous nematode dispersion through nonuniform glass-bead media J Nematol 47:296
11. Forey E, Trap J, Aubert M (2015) Liming impacts Fagus sylvatica leaf traits and litter decomposition 25 years after amendment Forest Ecology and Management 353:67-76
10. Becquer A, Trap J, Irshad U, Ali MA, Plassard C (2014) From soil to plant, the journey of P through trophic relationships and ectomycorrhizal association Frontiers in plant science 5:1-7
9. Trap J, Hättenschwiler S, Gattin I, Aubert M (2013) Forest ageing: An unexpected driver of beech leaf litter quality variability in European forests with strong consequences on soil processes Forest Ecology and Management 302:338
8. Trap J, Bureau F, Perez G, Aubert M (2013) PLS-regressions highlight litter quality as the major predictor of humus form shift along forest maturation Soil Biology and Biochemistry 57:969-971
7. Trap J, Riah W, Akpa-Vinceslas M, Bailleul C, Laval K, Trinsoutrot-Gattin I (2012) Improved effectiveness and efficiency in measuring soil enzymes as universal soil quality indicators using microplate fluorimetry Soil Biology and Biochemistry 45:98-101
6. Chauvat M, Trap J, Perez G, kkAubert M (2011) Changes within soil springtails assemblages across a 135-yr chronosequence of beech forest Soil Organisms 83:405-418
5. Trap J, Laval K, Akpa-Vinceslas M, Gangneux C, Decaëns T, Aubert M (2011) Humus macro-morphology and soil microbial community changes along a 130-yr-old Fagus sylvatica chronosequence Soil Biology & Biochemistry:1553-1562
4. Trap J, Bureau F, Brethes A, Jabiol B, Ponge, JF, Chauvat M, Decaens T, Aubert M. (2011) Does moder development along a pure beech (Fagus sylvatica L.) chronosequence result from changes in litter production or in decomposition rates? Soil Biology and Biochemistry 43:1-8.
3. Trap J, Bureau F, Akpa-Vinceslas M, Decaëns T, Aubert M (2011) Changes in humus forms and soil N pathways along a 130-yr-old pure beech forest chronosequence Ann For Sci 68:596-606
2. Aubert M, Margerie P, Trap J, Bureau F (2010) Aboveground-belowground relationships in temperate forests: plant litter composes and microbiota orchestrates. Forest Ecology and Management 259:563-572.
1. Trap J, Bureau F, Akpa-Vinceslas M, Chevalier R, Aubert M (2009) Changes in soil N mineralization and nitrification pathways along a mixed forest chronosequence. Forest Ecology Management 258:1284-1293.