In the aftermath of nuclear devastation, we turn our attention to the plight of plants that have been subjected to lethal doses of radiation. Astonishingly, these resilient organisms may not display any overt signs of distress for a period ranging from 2 to 5 weeks following exposure. Amidst the ruins, they stand tall and retain their vibrant green hue. Remarkably, various physiological processes, including photosynthesis, amino acid synthesis, and protein synthesis, continue unabated, and in some instances, even at an accelerated pace. Consequently, limited growth persists, and certain plants may even summon the strength to produce delicate blossoms. However, beneath this facade of vitality, a disruption unfolds within the intricate realms of cell division and tissue development. New growth is stunted, and the plant’s natural developmental sequence is abruptly halted. When exposed to superlethal doses, unmistakable signs of premature aging manifest, causing leaves to wither and fall. Conversely, plants exposed to sublethal doses may exhibit an outward appearance of health, yet fail to reach their full potential. They remain dwarfed, mired in a vegetative state, and their fruit or grain fails to come to fruition. Furthermore, when subjected to even lower doses, plants react to the ordeal of radiation much like they would to adverse temperature or moisture conditions. At these critical levels, radiation exposure serves as an additional burden upon these beleaguered organisms, exacerbating the challenges imposed by nutrient deficiencies, moisture scarcity, extreme temperatures, disease, or infestation by insidious insects. The cumulative effect of these compounding adversities can irreversibly tip the delicate balance, leading to disastrous outcomes that decimate final yields.