ISSI%20Meeting,%20Bern%2019-23%20January%202014 - PowerPoint PPT Presentation

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ISSI%20Meeting,%20Bern%2019-23%20January%202014

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ISSI Meeting, Bern 19-23 January 2014 New 3D photochemical global model with ions in D-region: The instrument for solar-atmospheric relations study – PowerPoint PPT presentation

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Title: ISSI%20Meeting,%20Bern%2019-23%20January%202014


1
ISSI Meeting, Bern 19-23 January 2014
  • New 3D photochemical global model
  • with ions in D-region The instrument for
    solar-atmospheric relations study
  •  
  • Alexei Krivolutsky
  • Lidiya Cherepanova, Tatyana Vyushkova,
  • and Alexander Repnev
  • Laboratory for Atmospheric Chemistry and Dynamics
  • Central Aerological Observatory, Dolgoprudny,
    Moscow Region
  • Russia

2
Outline
  • 1. Model description
  • 2. Results of simulations
  • - neutral compounds
  • - electrons
  • - other ions.
  • 3. Effects of solar cycle
  • 4. Conclusions

3
MODELCHARM I (CHemical Atmospheric Research
Model with Ions)(Krivolutsky et al., 2015)

  • Heights 0-90 km
  • P, L photochemical sources and losses
  • U, V, W wind components, µ mixing ratio
  • number of species neutrals 41 ions 23
  • number of chemical reactions (total) 194
  • Photodissociation and ionization rates (total)
    48
  • Methods chemical families for neutrals (Turco,
    Whitten, 1974)
  • electroneutrality for ions
  • Prathers scheme for advection
    ( Prather, 1986)
  • Resolution 2 km ? 5 ? 5 deg., Time step 100 s

4
List of neutral species
  • Families
  • Ox O3 O(3P) O(1D)
  • NOy N NO NO2 NO3 2N2O5 HNO3 HO2NO2
    ClNO3N(2D)
  • ClyCl ClO OClO ClOO HOCl HCl
  • HOxH OH HO2 2H2O2
  • others
  • CH3, CH2O, CH3O2, CH3O2H, CH3O, CHO, CO.
  • ?2(1?g)
  • Source-gases
  • CH4, CO2, N2O, ?F2Cl2, CFCl3, H2, Cl4, Cl2,
    ??3Cl, CH2Cl,
  • ?2, N2 (fixed profiles), H2O(fixed global
    field/HALOE).

5
PHOTODISSOCIATION RATES (CHARM-I)
  • O2h? ? OO(1D) N2O5h? ? NO2NO3
    H2Oh? ? HOH
  • O2h? ? OO HNO3h? ? OHNO2
    CF2Cl2h? ? products
  • O3h? ? OO2 CLONO2h? ? ClNO3
    CFCl3h? ? products
  • O3h? ? O(1D)O2 HClh? ? HCl
    CH4h? ? CH3H
  • H2O2h? ? OHOH ClOh? ? ClO
    CH4h? ? CH2H2
  • NO2h? ? NOO(1 D) NO3h? ? NOO2
    CCl4h? ? products
  • HNO3h? ? HNO3 H2O2h? ? OHOH
    CH3Clh? ? CH3Cl
  • HOClh? ? ClHO CO2h? ? COO
    N2Oh? ? N2O(1D)
  • N2O5h? ? 2NO2O HO2NO2h? ? HO2NO2
    Cl2h? ? ClCl
  • NOh? ? NO NO2h? ? NOO
    NO3h? ? NO2O

6
List of ionized compounds
  • Positive
  • O2 O4 O2(H2O) H (H2O) H (H2O)3
  • H (H2O)4 H (H2O)2
  • NON2 NOCO2 NO(H2O) NO(H2O)2
    NO(H2O)3 NO
  •  Negative e
  • O2 - O3- O4- CO4- O- OH- CO3- O2
    - (H2O) HCO3-
  •  
  •  

7
Ionization
  • 1-10 nm ( X-Rays)
  • 102,7-111,8 nm ?2(1?g)
  •   q(z)n(O2(1?g))?0,549?10-9exp(-2,406? 10-20
  • N(O2)2,614?10-9 exp(-8,508?10-20N(O2))?
  • 121,6 nm ( La ) NO
  • GCRs (Heaps, 1978)
  •  

8
ARM -Atmospheric Research Model
(GCM)(Krivolutsky et al., 2012)
  • Altitudes 0-135 ??
  • Resolutions vertical 1 km
  • longitudinal 100 latitudinal 50
  • time step 5 min.
  • Paramaterizations
  • Heating - ?2, ?3, ?2? (Strobel, 1978 Chou et
    al., 2002)
  • IR cooling- ??2, ?3, H2O, N?
  • ( Chou et al., 2002 Fomichev, 2003 Kockarts,
    1980),
  • IGWs (Lindzen, 1981)
  • Planetary waves at lower boundary (S1,2.3)

9
Global temperature field for July
(?)(Krivolutsky et al, 2012)
10
Zonal wind structure (m/s) for July (Krivolutsky
et. al, 2012)
  • Height (km)

11
Amplitude of D tidal component in zonal wind
(m/s)
July
(Krivolutsky et al., 2012) Height
(km)

latitude


12
Amplitude of SD tidal component in zonal
wind (m/s)
July
(Krivolutsky et al., 2012)
Height (km)
latitude
13
Neutral compounds O3 ( ppmv) January
14
Neutral compounds NOy ( ppbv)
January(CHARM-I)
15
Neutral compounds HNO3 ( ppbv) January
(CHARM-I)
16
Neutral compounds N2O ( ppbv) January
17
Calculated ionization rate by La
18
Electron density, 80 km
(number/cm3) 1st
January (0000 UT)
Latitude
Longitude
50

0
-50
0
50
100
150
200
250
300
350
19
IONS electron density, 60 km (number/cm3)
1st January (0000 UT)
20
NO (number/cm3) at 80 km 1st January
(0000 UT)
21
NO (number/cm3) at 70 km 1st January
(0000 UT)
22
O2 (number/cm3) at 80 km 1st January
(0000 UT)
23
O2 (number/cm3) at 70 km 1st January
(0000 UT)
24
O-2 (number/cm3) at 80 km1st January (0000
UT)
25
O-2 (number/cm3) at 60 km1st January
(0000 UT)
26
1st January (noon)
27
1st January (noon)
28
1st January (noon)
29
electrons (number/m3) 45 N (noon)
30
POSITIVE IONS O2 (number/m3) 45 N (noon)
31
POSITIVE IONS H(H2O)4 (number/m3) 45 N
(noon)
32
POSITIVE IONS O2H2O45 N (noon)
33
  • Effects of solar cycle simulated
  • with CHARM-I

34
Solar cycle in UV radiation(Matthew et al., 2012)
35
Solar UV variations (164,5 ??)
36
Solar UV spectrum variations used in model runs
37
Ozone change () max-min
38
Ox change () max-min
39
HOx change () max-min
40
NOy change () max-min
41
Simulated changes in electron density ()between
max. and min. of solar cycle(January)
42
Simulated changes in NO ()between max. and
min. of solar cycle (January)
43
Simulated changes in NO (H2O) ()between max.
and min. of solar cycle (January)
44
Simulated changes in O2 ()between max. and
min. of solar cycle (January)
45
Concluding remarks
  • 1. It seems that CHARM-I reproduces ion and
    neutral composition well.
  • 2. UV variations disturb neutrals ( ozone etc)
    and ion composition due to its interactions.
  • 3. Solar cycle in ionization was included
  • only by La , Lß
  • 4. Effect of particles will be included.

46
Thank you for your attention!
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