Modeling the Upper Atmosphere and Ionosphere with TIMEGCM

Slides:

Advertisements

Similar presentations

Section 2: The Planetary Boundary Layer

Advertisements

Introduction to the Ionosphere

Science questions What is the source of the SAV variation, the amplitude variation over the solar cycle, and the reason for the phase modulation? How does.

The Neutral Atmosphere Dan Marsh ACD/NCAR. Overview Thermal structure –Heating and cooling Dynamics –Temperature –Gravity waves –Mean winds and tides.

The NCAR TIE-GCM: Model Description, Development, and Validation

MURI,2008 Electric Field Variability and Impact on the Thermosphere Yue Deng 1,2, Astrid Maute 1, Arthur D. Richmond 1 and Ray G. Roble 1 1.HAO National.

ISSI Meeting, Bern January 2014 New 3D photochemical global model with ions in D-region: The instrument for solar-atmospheric relations study Alexei.

Oxygen: Stratosphere, Mesosphere and Thermosphere Part-3 Chemical Rate Equations Ozone Density vs. Altitude Stratospheric Heating Thermal Conductivity.

Modelling the Thermosphere-Ionosphere Response to Space Weather Effects: the Problem with the Inputs Alan Aylward, George Millward, Alex Lotinga Atmospheric.

Gases in Atmospheres Volatiles in Molecular Form (ice or gas): –Carbon dioxide CO 2 (molecular weight = 44) –Oxygen O 2 (molecular weight = 32) –Nitrogen.

H1C: Identify the Impacts of Solar Variability on the Earth’s Atmosphere Phase , Understand our Home in Space Global density, composition, temperature,

CISM Advisory Council Meeting 4 March Ionosphere-Thermosphere Modeling Tim Killeen, Stan Solomon, and the CISM Ionosphere-Thermosphere Team.

Periodic Modulations in Thermospheric Composition by Solar Wind High Speed Streams G. Crowley, A. Reynolds, J. P. Thayer, J. Lei, L.J. Paxton, A.B. Christensen,

5. Simplified Transport Equations We want to derive two fundamental transport properties, diffusion and viscosity. Unable to handle the 13-moment system.

The General Circulation of the Atmosphere Background and Theory.

How do gravity waves determine the global distributions of winds, temperature, density and turbulence within a planetary atmosphere? What is the fundamental.

TIEGCM Code Structure Contents TIEGCMMain TIEGCM InitModel initialization Init AdvanceAdvance model in time Advance DynamicsDynamics and Chemistry Dynamics.

ESS 7 Lectures 15 and 16 November 3 and 5, 2008 The Atmosphere and Ionosphere.

Space Environment Neutral Environment Hydrogen

Collisions and transport phenomena Collisions in partly and fully ionized plasmas Typical collision parameters Conductivity and transport coefficients.

UTSA Estimating Model Parameters from Ionospheric Reverse Engineering (EMPIRE) G. S. Bust and G. Crowley UTSA S. Datta-Barua ASTRA.

The Penetration of Solar Storm Effects into the Earth's Atmosphere Maura Hagan and Ray Roble Gang Lu, Jens Oberheide*, Stan Solomon, Art Richmond National.

How does the Sun drive the dynamics of Earth’s thermosphere and ionosphere Wenbin Wang, Alan Burns, Liying Qian and Stan Solomon High Altitude Observatory.

Altitude (km) January Global AverageTemperature (K) Pressure (hPa) With O( 3 P) Cooling WACCM-X The Whole Atmosphere Community Climate Model – eXtended.

Lecture 16 Simulating from the Sun to the Mud. Space Weather Modeling Framework – 1 [Tóth et al., 2007] The SWMF allows developers to combine models without.

University of Colorado 1 ; Delft University of Technology 2 ; University of Alaska 3 ; Centre National d’Etudes Spatiales 4 ; National Center for Atmospheric.

1 Agenda Topic: Space Weather Modeling and the Whole Atmosphere Model (WAM) Presented By: Rodney Viereck(NWS/NCEP/SWPC) Contributors: Rashid Akmaev (SWPC)

High Altitude Observatory (HAO) – National Center for Atmospheric Research (NCAR) The National Center for Atmospheric Research is operated by the University.

Jeff Forbes (CU), Xiaoli Zhang (CU), Sean Bruinsma (CNES), Jens Oberheide (Clemson U), Jason Leonard (CU) 1 Coupling to the Lower Atmosphere, an Observation-Based.

Neutral Winds in the Upper Atmosphere Qian Wu National Center for Atmospheric Research.

Scott M. Bailey, LWS Workshop March 24, 2004 The Observed Response of the Lower Thermosphere to Solar Energetic Inputs Scott M. Bailey, Erica M. Rodgers,

Ionospheric Research at USU R.W. Schunk, L. Scherliess, J.J. Sojka, D.C. Thompson & L. Zhu Center for Atmospheric & Space Sciences Utah State University.

Introduction to Space Weather Jie Zhang CSI 662 / PHYS 660 Spring, 2012 Copyright © Ionosphere II: Radio Waves April 12, 2012.

Ionospheric Current and Aurora CSI 662 / ASTR 769 Lect. 12 Spring 2007 April 24, 2007 References: Prolss: Chap , P (main) Tascione: Chap.

An introduction to our active ionosphere begin

Response of the Earth’s environment to solar radiative forcing

The Thermosphere/Ionosphere Response to Solar Activity During the October/November 2003 Storms P. R. Straus 1, G. Crowley 2, R. R. Meier 3, L. J. Paxton.

Topics in Space Weather Earth Atmosphere & Ionosphere

NCAR Advanced Study Program (ASP) Seminar, February 13, Solar Semidiurnal Tide in the Atmosphere Jeff Forbes Department of Aerospace Engineering.

ESS 200C Lecture 13 The Earth’s Ionosphere

University of Colorado/CIRES – NOAA/SWPC NADIR MURI, Boulder, CO, October, 2008 Mariangel Fedrizzi, Timothy J. Fuller-Rowell, Tomoko Matsuo Numerical.

TIEGCM Main advance Advance model in time readsource Read source history rdsource apex Call apex module apxmka apxmall input Read user input nc_rdhist.

III/1 Atmospheric transport and chemistry lecture I.Introduction II.Fundamental concepts in atmospheric dynamics: Brewer-Dobson circulation and waves III.Radiative.

ATMOSPHERE OBJECTIVE 1 1.What are the structural components of the

Lecture 15 Modeling the Inner Magnetosphere. The Inner Magnetosphere The inner magnetosphere includes the ring current made up of electrons and ions in.

Energy inputs from Magnetosphere to the Ionosphere/Thermosphere ASP research review Yue Deng April 12 nd, 2007.

Coupled Thermosphere Ionosphere Plasmasphere Model with self-consistent Electrodynamics (CTIPe) Global thermosphere km, solves momentum, energy,

Impact of midnight thermosphere dynamics on the equatorial ionospheric vertical drifts Tzu-Wei Fang 1,2 R. Akmaev 2, R. Stoneback 3, T. Fuller-Rowell 1,2,

Variations of hydrogen in the thermosphere: nature and causes

Using the Mars climate Database for aerobraking ( km)

The Ionosphere and Thermosphere GEM 2013 Student Tutorial

Atmosphere-Ionosphere Wave Coupling as Revealed in Swarm Plasma Densities and Drifts Jeffrey M. Forbes Department of Aerospace Engineering Sciences, University.

Welcome to Equatorial-PRIMO

GOMOS measurements of O3, NO2, and NO3 compared to model simulations

Upper Atmosphere Basics - I Neutral Atmosphere Vertical Structure

Ionospheric Models Levan Lomidze Center for Atmospheric and Space Sciences Utah State University CEDAR-GEM Student Workshop, June.

Thermosphere-Ionosphere Issues for DASI - I:

The ionosphere is much more structured and variable than ever predicted. Solar Driven Model Since 2000, we have seen more, very clear evidence that the.

Prospects for real-time physics-based thermosphere ionosphere models for neutral density specification and forecast Tim Fuller-Rowell, Mariangel Fedrizzi,

Ionosphere, Magnetosphere and Thermosphere Anthea Coster

Astrid Maute, Art Richmond, Ben Foster

ATMOSPHERE OBJECTIVE 1 1.What are the structural components of the

Earth’s Ionosphere Lecture 13

Energy conversion boundaries

Han-Li Liu, Raymond G. Roble, Arthur D. Richmond, Stanley C

Oxygen: Stratosphere, Mesosphere and Thermosphere Part-3

The Upper Atmosphere: Problems in Developing Realistic Models

Department of Physics and Astronomy, University of Louisville, KY, USA

VarSITI Closing Simposium, Sofia, Bulgaria, June 2019

Presentation transcript:

Modeling the Upper Atmosphere and Ionosphere with TIMEGCM Geoff Crowley Atmospheric & Space Technology Research Associates (ASTRA) www.astraspace.net TIMEGCM: Thermosphere-Ionosphere-Mesosphere-Electrodynamics-General Circulation Model ASPEN: Advanced SPace ENvironment Model

ASPEN-TIMEGCM

Simulating Mars and Earth Temperatures, Chemistry & Winds

Think I’ll develop another GCM this afternoon So it’s Easy …….. Right? Think I’ll develop another GCM this afternoon

Simplified Physics of Upper Atmosphere Joule Heating Particle Heating Solar EUV Chemical Heating Tides Gravity Waves Composition Temperature Winds E-fields Electron Density Boundary Conds Diffusion Coeffs Chemistry Solar EUV

Important Inputs to the Thermosphere – Ionosphere System Solar EUV Input OUTPUT High Latitude Inputs E-fields Particles Neutral density Composition Temperature Wind Electron density Dynamo E-fields Coupled Thermosphere –Ionosphere-Electrodynamics Tides and Gravity Waves

MODEL - %DIFFERENCE (Storm – Quiet) MODEL - QUIET - 12UT Neutral Temperature 12 UT MODEL - %DIFFERENCE (Storm – Quiet) MODEL - STORM - 12UT

MODEL - %DIFFERENCE (Storm – Quiet) MODEL - QUIET - 12UT Meridional Wind 12 UT MODEL - %DIFFERENCE (Storm – Quiet) MODEL - STORM - 12UT

Most Realistic High Latitude Inputs Data Inputs: 180 magnetometers 3 DMSP satellites X SuperDARNs

Time runs right to left TIMEGCM+AMIE 325 (11/21) 324 (11/20) 323 (11/19) 322 (11/18) 325 (11/21) 324 (11/20) 323 (11/19) 322 (11/18) Time runs right to left 325 (11/21) 325 (11/21) 324 (11/20) 324 (11/20) 323 (11/19) 323 (11/19) 322 (11/18) 322 (11/18) 325 (11/21) 324 (11/20) 323 (11/19) 322 (11/18) TIMEGCM+AMIE

Vertical Coordinate System If Zp is the pressure level (usually ranging from –17 to +5), and Po is the base pressure P = Po exp (-Zp) (ASPEN has 88 pressure levels; 30 to 600 km) Density is r = Po exp (-Zp) Mbar / (Kb T), where Kb is the Boltzman constant (gas constant / Avogadro number). Units depend on the choice of Po and Kb. If Kb = 1.38e-16 erg/K then density is in g/cm3. Horizontal Coordinates -87.5S (5) +87.5N latitude ; -180E (5) +180E longitude (72*36 grid points)

Energy equation Many terms Molecular conduction radiation advection adiab. heating The leap-frog method is employed with vertical thermal conductivity treated implicitly to second order accuracy. This leads to a tridiagonal scheme requiring boundary conditions at the top and bottom of the domain as implied by the differential equation. Advection is treated implicitly to fourth order in the horizontal, second order in the vertical

Heating Terms Cooling Terms Dynamical terms QEUV EUV (1-1050 Å) (EUVEFF= 5%) QSRC O2 -Schumann-Runge continuum (1300 -1750 Å) QSRB O2 -Schumann-Runge bands (1750-2000 Å) QO3 O3- Lyman a (1215.67 Å) O3- Hartley, Huggins and Chappuis (203-850 nm) QO2 O2- Lyman a (1215.67 Å) O2 Herzberg (2000-2420 Å) QNC Exothermic neutral-neutral chemistry (NOX, HOX, OX, CH4, O(1D) quench, CLX) Atomic O recombination Heating from O(1D) quenching QIC Exothermic ion-neutral chemistry QA Non-Maxwellian auroral electrons (AUREFF= 5%) QP Photoelectrons (X-rays, EUV, and Night) (EFF=5%) QEI Collisions between e-, ions and neutrals QDH 4th order diffusion heating QGW Gravity Waves QM Viscous Dissipation QJ Joule heating QT Total Heating Cooling Terms O(3P) 63 mm O(3P) fine structure NO 5.3 mm Nitric Oxide CO2 15 mm Carbon Dioxide O3 9.6 mm Ozone Km Molecular Conduction DIFKT Eddy Diffusion Cooling Dynamical terms Adiabatic cooling Horizontal Advection Vertical Advection

NEUTRAL GAS HEATING

Global Mean Heating and Cooling Terms (Solar Min.) Figure 2. Diurnal global mean deg K/day a) f) e) d) c) b) Global Mean Heating and Cooling Terms (Solar Min.) 275 km 150 150 120 103 90 90 50 Neutral Temperature Heating (K/day) Cooling (K/day) Heating (K/day) Cooling (K/day)

Effect of Season On Heating (SMAX) Equinox Solstice

Continuity equation molecular diffusion eddy diffusion Horiz. advection Vert. adv. Production Recombination The leap-frog method is employed leading to a tridiagonal scheme requiring boundary conditions at the top and bottom of the domain.

Nitrogen Chemistry (Simplified for This Talk) Each species equation includes horizontal and vertical advection, photo-chemical production and loss, and vertical molecular and eddy diffusion.

Neutral Species The model includes 15 separate neutral species, not counting some excited states which are also tracked. O, N2, O2, CO2, CO, O3, H, H2, H2O, HO2, N, NO, NO2, Ar, and He. Ionized Species The model includes 6 ion species O+, N+, O2+, N2+, NO+, and H+ with ionization primarily from solar EUV and x-rays, together with auroral particles.

Momentum equations Zonal velocity Meridional velocity Coriolis Rayleigh friction Coriolis Pressure gradients gravity wave drag ion drag Viscosity (Molecular and Eddy) momentum advection Meridional velocity The Leap frog method is employed with vertical molecular viscosity treated implicitly to second order accuracy. Since the zonal and meridional momentum equations are coupled through Coriolis and off-diagonal ion drag terms, the system reduces to a diagonal block matrix scheme, where (2 x 2) matrices and two component vectors are used at each level. Boundary conditions for the zonal (u) and meridional ( v) wind components are needed at the top and bottom of the model.

Momentum Forcing Terms (u,v) = neutral velocity (cm/s) (ui, vi) = ion velocity (cm/s) Pressure gradients f = 2 W sin(colatitude) (s-1) part of Coriolis forcing Molecular viscosity = Km (g/cm/s) Eddy viscosity (vertical) = DIFKV (g/cm/s) Momentum advection GWU, GWV = gravity wave drag RAYK = Rayleigh friction lij = ion drag tensor (must have units of s-1)

Balance of Forces

NUMERICAL EXPERIMENTS b) NUMERICAL EXPERIMENTS Electric Potential c) d) Electron Density

Conjugate Enhancements

MODEL COUPLING #1 ASPEN-IDA3D-AMIE (AIA) Self-consistently coupled - each output feeding the input of the other. Each algorithm has strengths that address the weaknesses of others. Coupled together, a more accurate specification of ionosphere and thermospheric state variables is obtained. Output: complete, data-driven specification (and prediction) of ionospheric and thermospheric state variables. Particularly: High latitude conductances High latitude field aligned currents (FAI) High latitude potentials High latitude Joule heating Global Electron density, neutral winds, neutral composition etc. AMIE TIMEGCM IDA4D  Ne Background Ne , Q, E TIMEGCM-IDA3D-AMIE interaction  FAC

EFFECT OF ADDING IDA4D ELECTRON DENSITY TO TGCM NEUTRALS 50 SH GUVI Raw GUVI Binned ASPEN IDA3D/ASPEN AMIE Figure 4. Comparisons of Hall Conductance from GUVI, ASPEN, IDA3D/ASPEN, and AMIE for November 20, 2003 for GUVI orbit 10564 (~17:29 UT) in apex magnetic latitude and magnetic local time coordinates.

Conductance Affects Field Aligned Currents from AMIE

SAMI3 (ionos-plasmasphere) RCM (inner magnetosphere) MODEL COUPLING #2 Extension to Plasmasphere/Inner Magnetos. SAMI3 (ionos-plasmasphere) RCM (inner magnetosphere) TIMEGCM

SAMI3 (ionos-plasmasphere) RCM (inner magnetosphere) MODEL COUPLING #3 Addition of Hydrogen Geocorona SAMI3 (ionos-plasmasphere) RCM (inner magnetosphere) Hydrogen Geocorona (2-4 RE) TIMEGCM

SAMI3 (ionos-plasmasphere) RCM (inner magnetosphere) MODEL COUPLING #4 Coupling to Lower Atmosphere?? SAMI3 (ionos-plasmasphere) RCM (inner magnetosphere) Hydrogen Geocorona (2-4 RE) TIMEGCM NOGAPS NCEP http://uap-www.nrl.navy.mil/dynamics/html/nogaps.html

How to Think About About Upper Atmosphere GCMs They are numerical laboratories Can do controlled (numerical) experiments They approximate reality Good “first stop” for atmospheric predictions Useful framework for understanding a system Useful framework for data analysis, and can be studied for mechanisms Useful place to test ideas (what if …..) Necessary first step to space-weather forecasting

Summary Thermosphere-Ionosphere-Mesosphere-Electrodynamics-General Circulation Model 30-600 km Fully coupled thermodynamics, chemistry Inputs - tidal, solar, high latitude Outputs Neutral: Temp, Wind, Density, Composition Ionosphere: Electron density, ions (dynamo E-field) Extensively Validated Various model coupling studies Provides useful background fields and test-bed e.g. gravity wave propagation