44 citations as recorded by crossref.

1. Soil processes drive the biological silicon feedback loop J. Cornelis et al.
2. The phytolith carbon sequestration concept: Fact or fiction? A comment on “Occurrence, turnover and carbon sequestration potential of phytoliths in terrestrial ecosystems by Song et al. doi: 10.1016/j.earscirev.2016.04.007” G. Santos & A. Alexandre
3. Biogeochemical silicon cycle and carbon sequestration in agricultural ecosystems Z. Song et al.
4. Phytolith Radiocarbon Dating: A Review of Previous Studies in China and the Current State of the Debate X. Zuo & H. Lu
5. 3D shape analysis of grass silica short cell phytoliths: a new method for fossil classification and analysis of shape evolution T. Gallaher et al.
6. Advance of research on modern soil phytolith C. Wen et al.
7. Phytolith radiocarbon dating in archaeological and paleoecological research: a case study of phytoliths from modern Neotropical plants and a review of the previous dating evidence D. Piperno
8. Influence of different extraction methods on prehistoric phytolith radiocarbon dating X. Zuo et al.
9. Možnosti a limity radiouhlíkového datování se zaměřením na netypické archeologické vzorky J. Bíšková et al.
10. Location, speciation, and quantification of carbon in silica phytoliths using synchrotron scanning transmission X-ray microspectroscopy D. Negrao et al.
11. Phytoliths as proxies of the past I. Rashid et al.
12. Sonication improves the efficiency, efficacy and safety of phytolith extraction U. Lombardo et al.
13. When the carbon being dated is not what you think it is: Insights from phytolith carbon research G. Santos et al.
14. Issues and directions in phytolith analysis T. Hart
15. TEMPORARY REMOVAL: High potential of phytoliths in terrestrial carbon sequestration at a centennial–millennial scale: Reply to comments by Santos and Alexandre Z. Song et al.
16. Plant silicon content in forests of north China and its implications for phytolith carbon sequestration X. Yang et al.
17. Direct uptake of organically derived carbon by grass roots and allocation in leaves and phytoliths: 13C labeling evidence A. Alexandre et al.
18. Phytolith‐occluded carbon in leaves of Dendrocalamus Ronganensis influenced by drought during growing season R. Li et al.
19. New highlights of phytolith structure and occluded carbon location: 3-D X-ray microscopy and NanoSIMS results A. Alexandre et al.
20. Silicon in the Soil–Plant Continuum: Intricate Feedback Mechanisms within Ecosystems O. Katz et al.
21. Comment on "Possible source of ancient carbon in phytolith concentrates from harvested grasses" by G. M. Santos et al. (2012) L. Sullivan & J. Parr
22. A new method for extracting the insoluble occluded carbon in archaeological and modern phytoliths: Detection of 14C depleted carbon fraction and implications for radiocarbon dating Y. Asscher et al.
23. Publisher’s Note
24. Radiocarbon dating of prehistoric phytoliths: a preliminary study of archaeological sites in China X. Zuo et al.
25. Silicon Fertilization for Carbon Sequestration Through PhytOC Production in Plants M. Suji et al.
26. Occurrence, turnover and carbon sequestration potential of phytoliths in terrestrial ecosystems Z. Song et al.
27. From radiocarbon analysis to interpretation: A comment on “Phytolith Radiocarbon Dating in Archaeological and Paleoecological Research: A Case Study of Phytoliths from Modern Neotropical Plants and a Review of the Previous Dating Evidence”, Journal of Archaeological Science (2015), doi: 10.1016/j.jas.2015.06.002.” by Dolores R. Piperno G. Santos et al.
28. Towards producing pure phytolith concentrates from plants that are suitable for carbon isotopic analysis R. Corbineau et al.
29. Influence of increasing combustion temperature on the AMS 14C dating of modern crop phytoliths J. Yin et al.
30. Elemental composition of grass phytoliths: Environmental control and effect on dissolution O. Pokrovsky et al.
31. Combined Silicon-Phosphorus Fertilization Affects the Biomass and Phytolith Stock of Rice Plants Z. Li et al.
32. The development of phytoliths in plants and its influence on their chemistry and isotopic composition. Implications for palaeoecology and archaeology M. Hodson
33. Plant exploitation in Neolithic Sudan: A review in the light of new data from the cemeteries R12 and Ghaba W. Out et al.
34. The effects of crop varieties and environmental conditions on the stability of phytolith-occluded carbon in wheat and rice E. Zhao et al.
35. Unambiguous evidence of old soil carbon in grass biosilica particles P. Reyerson et al.
36. The carbon isotopic composition of occluded carbon in phytoliths: A comparative study of phytolith extraction methods B. Roy et al.
37. Holocene Soil Evolution in South Siberia Based on Phytolith Records and Genetic Soil Analysis (Russia) D. Gavrilov et al.
38. Impact of climate and lithology on soil phytolith-occluded carbon accumulation in eastern China X. Zhang et al.
39. Phytolith-Occluded Carbon Storages in Forest Litter Layers in Southern China: Implications for Evaluation of Long-Term Forest Carbon Budget X. Zhang et al.
40. Plant growth conditions alter phytolith carbon K. Gallagher et al.
41. Dynamic Nuclear Polarization NMR as a new tool to investigate the nature of organic compounds occluded in plant silica particles A. Masion et al.
42. A review of carbon isotopes of phytoliths: implications for phytolith-occluded carbon sources S. Yang et al.
43. Dating rice remains through phytolith carbon-14 study reveals domestication at the beginning of the Holocene X. Zuo et al.
44. Determining phytolith-occluded organic carbon sequestration using an upgraded optimized extraction method: indicating for a missing carbon pool N. Han et al.