Table 3.
The relevant article cited in the plant system section.
| Article Title | Author | Reference |
|---|---|---|
| Interaction of the CdSe Quantum Dots with Plant Cell Walls | Djikanović et al. | [174] |
| Fluid Phase Endocytic Uptake of Artificial Nano-Spheres and Fluorescent Quantum Dots by Sycamore Cultured Cells | Etxeberria et al. | [175] |
| Cell Wall: An Important Medium Regulating the Aggregation of Quantum Dots in Maize (Zea Mays L.) Seedlings | Sun et al. | [176] |
| Nanoparticle Charge and Size Control Foliar Delivery Efficiency to Plant Cells and Organelles | Hu et al. | [177] |
| Lipid Exchange Envelope Penetration (LEEP) of Nanoparticles for Plant Engineering: A Universal Localization Mechanism | Wong et al. | [178] |
| In Vivo Plant Flow Cytometry: A First Proof-of-Concept | Nedosekin et al. | [179] |
| The Effect and Fate of Water-Soluble Carbon Nanodots in Maize (Zea Mays L.) | Chen et al. | [180] |
| Uptake and Accumulation of CuO Nanoparticles and CdS/ZnS Quantum Dot Nanoparticles by Schoenoplectus Tabernaemontani in Hydroponic Mesocosms | Zhang et al. | [181] |
| High Efficiency Transport of Quantum Dots into Plant Roots with the Aid of Silwet L-77 | Hu et al. | [182] |
| Surface Coating Determines the Response of Soybean Plants to Cadmium Sulfide Quantum Dots | Majumdar et al. | [183] |
| Effect of Graphene Quantum Dot Size on Plant Growth | Xu et al. | [184] |
| Surface Charge Affects Foliar Uptake, Transport and Physiological Effects of Functionalized Graphene Quantum Dots in Plants | Sun et al. | [185] |
| Size Effect of Graphene Quantum Dots on Photoluminescence | Liu et al. | [186] |
| Carbon Dots Inhibit Root Growth by Disrupting Auxin Biosynthesis and Transport in Arabidopsis | Yan et al. | [187] |