Lecture

Radiation Biology: Basics and Applications

Related lectures (32)

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Explores food irradiation and radioisotope batteries, discussing their applications, advantages, and regulatory aspects in industrial settings.

Introduction to Radiation Biology, Protection and Applications

Introduces radiation detection, energy deposition, radioisotope production, and their applications in various fields.

Nuclear Reactions: Synthesis and Applications

Explores artificial nuclear reactions, their applications in various fields, and the effects of radiation on health.

Radiation Sources: Overview

Explores radiation sources, including fast electrons, heavy charged particles, and neutrons, discussing their applications and characteristics.

Radiation Biophysics: Fundamentals and Applications

Explores the fundamentals of radiation biophysics, covering topics such as radiation units, effects on humans, and medical applications.

Radiation Protection: Basics

Covers the interaction of radiations with matter, dose concepts, and radiation shielding.

Gamma and Neutron Radiography

Explores the historical development and industrial applications of radiography and computerized tomography with X-rays, gammas, and neutrons.

Radiation Sources

Explores radiation sources, including fast electron sources, heavy charged particle sources, and neutron sources, covering processes like beta decay, internal conversion, and Auger electrons.

Radiotherapy: Basics & Classical Methods

Covers the basics and classical methods of radiotherapy, focusing on the application of ionizing radiation to fight cancer.

Radiation Shielding

Explores the principles of radiation shielding using absorbing materials to reduce radiation exposure and covers topics such as radiation interaction mechanisms and Monte Carlo simulations.

Radiation Protection: Interactions and Shielding

Covers the basics of radiation protection, including interactions with matter, dose concepts, and shielding techniques.

Atoms and Radiation: Lineshapes

Explores atoms and radiation lineshapes, covering linewidths, lifetime broadening, and broadening mechanisms, including Lorentzian and Doppler effects.

Microelectronics Vulnerability to Space Environment

Explores the vulnerability of microelectronics to space radiations and mitigation techniques.

Radiation and Antennas: Thin Slot Antenna

Explores radiation and antennas, emphasizing thin slot antennas and their radiation patterns.

Overview and comparison: Imaging Modalities

Covers the comparison of bio-imaging modalities, discussing contrast mechanisms, limitations, SNR, and reconstruction techniques.

Biological effects of ionizing radiation

Explores the biological effects of ionizing radiation and how tissues defend against damage.

Radiotherapy: Modern Techniques

Covers modern radiation therapy techniques, optimizing dose distribution for effective tumor control while minimizing normal tissue complications.

Gamma and Neutron Radiography

Explores the principles and applications of gamma and neutron radiography in industrial settings, highlighting the advantages of using neutrons and discussing special techniques and industrial applications.

Atoms and Radiation: Electromagnetic Wave Propagation

Explores electromagnetic wave propagation, including Poynting vector, irradiance, dipole radiation, dielectric constant, and natural linewidth in atoms and radiation.

Basis of X-ray Imaging

Explores the basics of X-ray imaging, including the discovery of X-rays, electromagnetic radiation interaction, and ionizing radiation effects.