62 lines
3.1 KiB
Markdown
62 lines
3.1 KiB
Markdown
---
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title: NUCE 2100 Class 2
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allDay: false
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startTime: 18:00
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endTime: 20:30
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date: 2024-09-10
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completed: null
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---
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# Module 3.1 - Radiation Terminology and Units
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>[!note] Radiation Activity Units
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>Activity is measured in disintegrations per unit time.
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> - Historical Unit: The Curie
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> - 1 Curie = 3.7 x 10^10 disintegrations per second
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> = 2.22 x 10^12 disintegrations per minute
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> - SI Unit: The Becquerel
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> - 1 Bq = 1 disintegration per second
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>
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1. Ionization is what causes all observable effects of radiation.
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1. Breaks chemical bonds, disturbs chemical processes
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2. The number of ionization events a single particle of radiation can cause is dependent on energy
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1. Number of ionization DENSITY is determined by the linear energy transfer, in units of energy per unit length
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1. Alpha SUPER high
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2. Beta mid
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3. Gamma low
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2. But different rays can only penetrate certain materials
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1. Ionization density is inversely proportional to penetration
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>[!note] **Exposure:**
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>The $\gamma$ and x ray radiation field incident on a body. Measured by the specific ionization produced by it in the neighboring air.
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>Measured in photon flux. Amount of energy transferred from the photons ot a unit mass of air.
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>Traditional unit for exposure is the roentgen (R)
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>1 R is the amount of radiation required to **liberate** positive or negative charges of one electrostatic unit of charge (esu = 3.33E-10 Coulomb) in 1 cm^3 of dry air at STP.
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>1 R = 1 esu/cm^3 where $\rho$ = 1.293 kg/m^3
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>An old unit. First attempt and standardizing field of radiation measurement
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>[!note] Absorbed Dose
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>Actual damage to matter depends on how much energy is absorbed.
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>SI unit: rad ("Radiation Absorbed Dose"): 1 rad = 100 ergs/gm
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>[!attention] SI Units for Radiation Quantities
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>• Decay rate: Becquerel (Bq): 1Bq = 1 disintegration/second (dps), whereas 1 Curie = 3.7 x 1010 dps
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>• Deposited energy: Gray (Gy): 1 Gy = 100 rads = 1 joule/kg *
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>• Biological radiation effect: Sievert (Sv): 1 Sv = 100 rem
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>
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>* Recall 1 erg = 10-7 joule
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Concentrations of ionizations within a single cell are more damaging then spread out ionization over many cells.
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Biological damage is proportional to absorbed dose, as well as LET for that type of radiaiton.
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>[!note] Relative Biological Effectiveness (RBE)
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>Compares biological effects of different types of radiation.
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>$$\text{RBE} = \frac{\text{Dose of 250 keV X-rays producing an effect}}{\text{Dose of reference radiation for same effect}}$$
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>RBE is highly dependent on the type of radiation.
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>The upper limit of the RBE for a specific type of radiation is called the **quality factor**.
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>Multiplying the absorbed dose by the quality factor gives the effective or **equivalent dose** (QF x rad = rem)
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# Module 3.2 - Radiation Damage in Biological Systems
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Ionizing radiation in the body can cause problems in multiple ways. One way is by creating highly reactive free radicals. Water for example breaks down into hydrogen peroxide. Which is really not good for life.
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# Module 3.3 - Radiation Protection Standards
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# Module 3.4 - Estimating Radiation Dose Rates
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# Module 3.5 - Radiation Shielding |