CMR Header

CCMC Metadata Registry (CMR)

Menu Page

Go to:

 CMR: View Simulation Model Info

NAIRAS (2.0)

Nowcast of Atmospheric Ionizing Radiation for Aviation Safety Model

Model Description 

The NAIRAS model predicts biologically hazardous radiation exposure to commercial aircrews and passengers from the ever-present galactic cosmic rays and the episodic, transient solar energetic particles. 

It provides data-driven, global, real-time predictions of radiation exposure rates from galactic cosmic rays (GCR) and solar energetic particles (SEPs) on a geographic 1 × 1 degree latitude and longitude grid, and from the surface of the Earth to 90 km with a vertical resolution of 1 km. The real-time, global predictions are updated every hour. Deterministic, physics-based models are employed to transport cosmic rays through the heliosphere, Earth's magnetosphere, and the neutral atmosphere (Mertens et al., 2012, 2013). GCR are transported through the heliosphere using a modification of the 2010 Badhwar and O'Neill GCR model (Mertens et al., 2013), denoted H-BON10, while the energy spectra of SEPs are specified in situ outside the magnetosphere using NOAA Geostationary Operational Environmental Satellite (GOES) ion flux measurements (Mertens et al., 2010, 2012). Transport through the magnetosphere is parameterized in terms of effective vertical cutoff rigidity, which is based on charged particle trajectory tracing in a dynamically varying geomagnetic field (Kress et al., 2010; Mertens et al., 2010). Cosmic rays are transported through the neutral atmosphere using the High Charge (Z) and Energy TRaNsport (HZETRN) code (Slaba, Blattnig, & Badavi, 2010; Slaba, Blattnig, Aghara, et al., 2010; Wilson et al., 1991). An initial validation of the NAIRAS model version 1.0 was presented for GCR exposures by Mertens et al. (2013). Recently, NAIRAS was updated to HZETRN2015, which includes pion-initiated electromagnetic cascade processes (Norman et al., 2012; Slaba et al., 2013). In addition, a correction was derived for the primary cosmic ray proton and alpha flux in the H-BON10 model, during solar cycle minimum conditions, based on measurements from the satellite-borne Payload for Antimatter Exploration and Light-nuclei Astrophysics (PAMELA) experiment (Adriani et al., 2013, 2016).

Model Figure(s) :

Model Inputs Description 

1. ACE (EPAM) and GOES (SEM) data to derive the incident SEP spectral fluence rates (5 min averaged).
2. Geomagnetic cutoff rigidities based on IGRF and TS05 (needs input for these models, realtime Dst, solar wind and IMF from ACE/DSCOVR)
3. Atmospheric depth altitude: NCAR/NCEP pressure vs. geopotential height data  (extended by invovling NRLMSIS model)

Model Outputs Description 

Radiation exposure rates GCRs and SEPs on a geographic 1 × 1 degree latitude and longitude grid, and from the surface of the Earth to 90 km with a vertical resolution of 1 km.

Model Caveats 


	
	
	
	
Change Log
		
	

	

	
	 
	
Model Acknowledgement/Publication Policy (if any)
		
	

	

	
	
	
Model Domains:
		
	

	
		High_Latitude_Ionosphere/Auroral_Region

	
		Global_Ionosphere

	
	
	
Space Weather Impacts:
		
	

	
		Solar energetic particles - SEPs (human exploration, aviation safety, aerospace assets functionality)

	
		Galactic cosmic rays - GCRs (human exploration, aviation safety, aerospace assets functionality)

	
	
	
Phenomena :

	

	
Simulation Type(s):
		
	

	
		Physics-based

	
		
	
Temporal Dependence Possible? (whether the code results depend on physical time?)
		
	

		true

		
    
Model is available at? 
    	
	

		CCMC

		
	
Source code of the model is publicly available?

		false

		
	 
CCMC Model Status (e.g. onboarding, use in production, retired, only hosting output, only source is available): 
    	
	

		retired

	
	
Code Language: 
		
	

		


	
Regions (this is automatically mapped based on model domain):

	
		Earth.NearSurface.AuroralRegion

	
		Earth.NearSurface.Ionosphere

	
	
	

		Contacts
		
		:
	

	
		Chris.Mertens, ModelDeveloper 
		

	
		Yihua.Zheng, ModelHostContact 
		

	

	

		Acknowledgement/Institution
		
		:
	

	

	
	
	

		Relevant Links
		
		:
	

	
		NAIRAS at Space Environment: http://sol.spacenvironment.net/~nairas/
		
		

	
		Real-time Atmospheric Effective Radiation Dose Rates from the NAIRAS model: http://bit.ly/NAIRAS-products
		
		

	

	

		Publications
		
		:
	

	
		
  • 
		
			
				Meier, M. M., Copeland, K., Matthiä, D., Mertens, C. J., & Schennetten, K. ( 2018). First steps toward the verification of models for the assessment of the radiation exposure at aviation altitudes during quiet space weather conditions. Space Weather, 16, 1269-1276. https://doi.org/10.1029/2018SW001984
			
			
			
		
		
    • 
	
		
  • 
		
			
				Mertens, C. J., Meier, M. M., Brown, S., Norman, R. B., and Xu, X. ( 2013), NAIRAS aircraft radiation model development, dose climatology, and initial validation, Space Weather, 11, 603‐ 635, doi:10.1002/swe.20100.
			
			
			
		
		
    • 
	
		
  • 
		
			
				Mertens, C. J., B. T. Kress, M. Wiltberger, S. R. Blattnig, T. S. Slaba, S. C. Solomon, and M. Engel (2010),Geomagnetic influence on aircraft radiation exposure during a solar energetic particle event in October 2003, Space Weather, 8, S03006, doi:10.1029/2009SW000487.
			
			
			
		
		
    • 
	
		
  • 
		
			
				Mertens, C. J., B. T. Kress, M. Wiltberger, W. K. Tobiska, B. Grajewski, and X. Xu, Atmospheric ionizing radiation from galactic and solar cosmic rays, in Current Topics in Ionizing Radiation Research, Edited by Mitsuru Nenoi, InTech Publisher (ISBN 978-953-51-0196-3), 2012. web link    10.5772/32664
			
			
			
		
		
    • 
	

	
    
		Model Access Information
		
		:
	
    
	
	
	
    
		Linked to Other Spase Resource(s) (example: another SimulationModel)
		
		:
	
    
	
	
	


            		
    
    
    
    
        
            




CMR Footer




    
 


    
Curator: Chiu Wiegand |
NASA Official: Dr. Masha Kuznetsova |
Privacy and Security Notices |
Accessibility |
CCMC Data Collection Consent Agreement