Convert milligray [mGy] to femtogray [fGy] Online | Free radiation-absorbed-dose Converter

Milligray [mGy]: A Common Unit in Radiation Dosimetry

The milligray (mGy) is a unit of absorbed radiation dose equal to 10⁻³ grays (Gy), or one-thousandth of a gray. It is widely used in medical, environmental, and industrial applications where moderate levels of ionizing radiation are involved. In medical imaging, such as X-rays, CT scans, and fluoroscopy, radiation doses are often measured in milligrays. For example, a typical chest X-ray may deliver a dose of around 0.1 mGy, while a CT scan can range from 2 to 20 mGy depending on the body part and procedure. The mGy is also used in radiation therapy planning to define exposure to surrounding healthy tissues that must be minimized. In environmental and occupational safety, monitoring radiation exposure in milligrays helps ensure that workers and the public remain within safe limits set by regulatory bodies. The unit is practical because it provides a manageable scale between very small doses (like microgray) and larger therapeutic doses (measured in grays). Understanding and using the milligray is essential for balancing diagnostic or industrial effectiveness with radiation protection and patient or worker safety.

Femtogray [fGy]: A Tiny Unit of Radiation Dose

The femtogray (fGy) is a unit of absorbed radiation dose equal to 10⁻¹⁵ grays (Gy). The gray (Gy) is the standard SI unit used to measure the amount of ionizing radiation energy absorbed per kilogram of matter. One femtogray, therefore, represents a quadrillionth (0.000000000000001) of a gray. This unit is extremely small and is primarily used in theoretical research, nanodosimetry, or highly sensitive radiation studies where even the smallest levels of energy absorption can have measurable effects on microscopic or molecular systems. While real-world applications like medical imaging or radiation therapy use much larger units such as milligray (mGy) or gray (Gy), the femtogray can help researchers simulate or analyze interactions of radiation with DNA, proteins, or other cellular components. Although it is impractical for most everyday uses due to its tiny scale, the femtogray plays a valuable role in scientific fields requiring ultra-precise radiation dose measurements. It demonstrates how finely scientists can scale radiation measurements to better understand the effects of energy on matter at the smallest biological or atomic levels.