Laboratory characterization and astronomical detection of the

nitrosylium (nitrosyl) ion , NO+

Stéphane Bailleux stephane.bailleux@univ-lille1.fr

University of Lille

June 18, 2014 　– 69th ISMS Meeting

Atmospher ic NO +

D- & E- regions of the ionosphere (60 – 130 km)

NO+ and O2+ : most abundant ions (Dalgarno & Fox, 1994)

photo–ionization (UV + X–rays) of N2, NO, O2

low exothermicity : major source and sink of other species(N , O, NO)

Signi f icant IR emi t ter in the thermosphere :

N+ + O 2 → NO+ (v ) + O

O+ + N 2 → NO+ (v ) + N

EnviSat satellite / MIPAS spectrometer (40 – 170 km) 38 ro-vibrational lines (López-Puertas et al, 2006)

Astro-chemistry of NO +

NO (X ²Π ) de tec ted in : Sgr B2 (Liszt & Turner, 1978)

L134N (McGonagle et al, 1990)

Orion–KL, W33A, W51M (Ziurys et al, 1991)

NO + i n space i f T s o u r c e s < 15 K Herbst & Klemperer (1973) , Alberti & Douglas (1975) Pickles & Williams (1977) , S ingh & Mac ie l (1980)

Many N–bear ing spec ies de tec ted , e .g .HCN , HNC , NO , HNO , …

NH3 , N2H+ , NH4

+ , …

CN ( – ) , C3N ( – ) , C5N ( – ) , …

NO/H 2

~ 10– 8

Molecular propert ies

First ionization energy of NO : 9.264 eV

Reactivity : X 1Σ+ (close-shell)

isoelectronic with CO, N2

I (14N) = 1 ⇒ quadrupolar (hyperfine)

structure

stable

reexp = 1.063 Å (rNO ≃ 1.15 Å)

µ ≃ 0.36 D

Spectroscopy of NO +

Electronic emission : A 1Π – X 1Σ+

J = 1 – 0 : ~119 187 ±30 MHz (Alberti & Douglas,

1975)

NO+ in Ne matrix (Jacox & Thompson, 1990)

fundamental vibrations (cm–1) :

14N16O+ : 2345.2 15N16O+ : 2303.8 14N18O+ :

2284.2

Hi–resolution spectroscopy I R ( d i o d e l a s e r ) : 8 t r a n s i t i o n s

MMW : 2 lines (Bowman, Herbst & De Lucia, 1982)J = 2 – 1 @ 238.38 GHz + hyperfine

structure (14N)

J = 3 – 2 @ 357.56 GHz

Extended negat ive glow discharge

to pump

N2

LN2 solenoid

pressuregauge

NO orN2 + O2

ano

de

320 MHz

10 MHz PLL

feedback

IF

12 -18 GHzlocal

oscillator

~10 MHzRef.

oscillator

10 MHzRb atomic

clockPhase

SensitiveDetector

InSb

Oscilloscope

phasemodulation

BWO

pre-amplifier

LN2-cooled absorption cell

ballast 5 kV /8 mA

BWOpower supply

Laboratory measurements

v J’ n ( 1 4NO+ ) n ( 1 5 NO + )0 5 595 886.721 (15) 574 822.400 (120)

6 715 019.297 (40) 689 744.91600007 834 127.480 (40) 804 645.051 (50)8 953 207.189 (50) 919 518.648 (60)9 1 072 254.440000000 1 034 362.020000000

1 5 590 225.390 (50) 569 461.03300006 708 225.5590000 708 225.55900007 826 201.235 (80) 797 136.944 (60)8 944 148.548 (75) 910 936.1490000

2 5 584 542.326 (50)

J = 1 ← 0 tr iplet not observed ( 1 4NO + v = 0)

119 191.84 MHz (F = 1 ← 1)

119 193.88 MHz (F = 2 ← 1) F = J +

IN

119 196.94 MHz (F = 0 ← 1)

Bowman et al. (1982)

cm–1

14NO+

Constants (MHz) NO+

1 4NO +   1 5NO +

our work Bowman et al our workrotation  

B0 59 597.139 (6) 59 597.132 (16) 57 490.109 (8)

D0 0.16943 (6) 0.171 (1) 0.15776 (7)

B1 59 031.032 (9) 56 954.176 (2)

D1 0.16991 (9) 0.15776

B2 58 462.854 (64)

D2 0.1724 (13)

quadrupole

eQq0 -6.715 (40) -6.76 (10)

IRAM 30 m telescope (Pico Veleta, Spain)

Line surveys

3, 2 & 1 mm

198 kHz resolution

3 mm

50 kHz resolution

Target : cold , dark core B–1b

(1200 M☉)

1s t detected in B1–b : HCNO , CH3O , NH4+, NH3D+

D–fractionation : NH3D+ , ND3 , D2CS , …

rich chemistry in B1–bB1–b : helps understanding star formation

2 very dense cores

N(H 2 ) = 1023 cm–2

n(H 2 ) = 105 cm–3

T = 12 –15 K

Molecular clouds in Perseus© Adam Block

2 velocity components

6.5 km s–1 : 1.5 1012 cm–²

7.5 km s–1 : 6.5 1011 cm–²

6 hyperfine components (6.5 km s–1)

NO+ J = 2 – 1

0 5 10 15VLSR (km s–1)

Predicted line profi le from a model

with 2 velocity components

ONLY NO+ MATCHES THIS LINE IN THE MADEX CODE (4900 SPECIES)

NO+ J = 2 – 1238.38 GHz

HCNO J = 4 – 3

HSCN

J = ³/₂ – ¹/₂F = ⁵/₂ – ³/₂

NO150 176 MHz

JKaKc = 101 – 000HNO new species

NO HNO

XNO / XNO+ ≃ 510

XNO / XHNO ≃ 550

XNO+ / XHNO ≃ 1

91 751 MHz

81 477 MHz

Time–dependent gas–phase model

1117 species

1117 reactions

Pathways in cold, dense clouds

charge transfert : H+ + NO → NO+ + H

ion – molecule : N+ + CO → NO+ + C

proton elimination : H+ + HNO → NO+ + H2

dissociat ive recombination : NO + + e → N + O

model : typical dark cloud

n(H2) ≃ 105 cm–3

T ≃ 10 K

XNO+

pred ≃ X

NO+obs

XNO

pred ≃ 4 X

NO

obs

XHNO

pred ≃ 150 X

HNO

obs

Ab

un

da

nc

e r

ela

tiv

e t

o H

2

T i m e ( y r s )

Predicted abundances

only 1 line detected

no satisfactory chemical formation path

matches the low observed HNO abundance

better models needed (reactions at the

surfaces of grains, …)

Interstellar species containing N and O poorly

studied

Concluding remarks

Co–authors

E. Alekseev (Inst. Radio–Astronomy, Karkhov)

J. Cernicharo & B. Tercero (Dep. Astrophysics, Madrid)

A. Fuente & R. Bachiller (Obs. Astronomy, Spain)

E. Roueff & M. Gerin (Obs. Paris–Meudon)

S. P. Treviño–Morales (IRAM, Spain)

N. Marcelino (NRAO)

B. Lef loch (Inst. Planetologie & Astrophysique, Grenoble, Fr)

Y10 (we) 2 376.593 (3) cm–1

Y20000 -16.286 (1) cm–1

U01 /µµµ 59 882.95 (5) MHz

Y01 (Be) 59 879.38 (5) MHz

D01N111 -1.52 (2)

Y11 (-ae) -563.94 (2) MHz

Y2111 (we) -1.084 (5) MHz

Y02 (-De) -169.19 (9) kHzY122 (we) -0.43 (10) kHz

Dunham analysis (14N16O+)

Ev,J /ℎ = ∑ Ylm (v +½)l Jm (J+1)m

Y01 =

U01 /µ (1 + me D01N/MN)

U01 (reBO)²= 505 379.005(36)

re

BO = 1.0631546 (5) Å

Complete spectrum (1.7 GHz)