The Fate and Effects of Organics At Atmospheric Interfaces Joel Thornton Department of Atmospheric Sciences University of Washington, Seattle

Slides:

Advertisements

Similar presentations

Trapping of Hydroxyl Radical and Ozone at Salt Aerosol Surfaces: A Molecular Dynamics Study Martina Roeselová, a Douglas J. Tobias, b R. Benny Gerber,

Advertisements

Gas/Particle Partitioning. Why is gas/particle partitioning important? Dispersion of Pollutants Introduced into the Atmosphere as Determined by Residence.

Development of a Secondary Organic Aerosol Formation Mechanism: Comparison with Smog Chamber Experiments and Atmospheric Measurements Luis Olcese, Joyce.

Chapter 18: Chemical Equilibrium

A model study of laboratory photooxidation experiments of mono- and sesquiterpenes M. Capouet and J.-F. Müller Belgian Institute for Space Aeronomy L.

Copyright © R. R. Dickerson 1 FROM LECTURE 8 Spectroscopy of Simple Molecules Example 1. HCl HCl has a strong dipole and strong transitions near.

Objectives To understand the process of dissolving

Lesson17. Heterogeneous and cloud processes Wide range of physical and chemical of substrate surfaces for heterogeneous reactions to take place. Clouds.

Atmospheric Heterogeneous Chemistry of HO 2 Joel Thornton and Jonathan Abbatt Department of Chemistry University of Toronto $$ Natural Sciences and Engineering.

Nucleation: Formation of Stable Condensed Phase Homogeneous – Homomolecular H 2 O (g)  H 2 O (l) Homogeneous – Heteromolecular nH 2 O (g) + mH 2 SO 4(g)

METO 637 Lesson 13. Air Pollution The Troposphere In the Stratosphere we had high energy photons so that oxygen atoms and ozone dominated the chemistry.

METO 637 Lesson 16.

Properties of Matter Are mass, volume and density intensive or extensive properties? Are taste and smell intensive or extensive properties? Problem Set.

This Week—Tropospheric Chemistry READING: Chapter 11 of text Tropospheric Chemistry Data Set Analysis.

Surface and Interface Chemistry  Thermodynamics of Surfaces (LG and LL Interfaces) Valentim M. B. Nunes Engineering Unit of IPT 2014.

Modeling Elemental Composition of Organic Aerosol: Exploiting Laboratory and Ambient Measurement and the Implications of the Gap Between Them Qi Chen*

A missing sink for radicals Jingqiu Mao (Princeton/GFDL) With Songmiao Fan (GFDL), Daniel Jacob (Harvard), Larry Horowitz (GFDL) and Vaishali Naik (GFDL)

Ch. 8 Solutions, Acids, & Bases I. How Solutions Form  Definitions  Types of Solutions  Dissolving  Rate of Dissolving.

Allison Schwier 25 April The McNeill Group McNeill Group 1 Postdoc 2 Grad Students 1 Fulbright Scholar 1 Visiting Professor 4 Undergrads.

Different heterogeneous routes of the formation of atmospheric ice Anatoli Bogdan Institute of Physical Chemistry, University of Innsbruck Austria and.

Solutions This kind…. Section 15.1 Forming Solutions 1. To understand the process of dissolving 2. To learn why certain substances dissolve in water 3.

TOPIC 1 CHEMISTRY: THE STUDY OF MATTER MRS. PAGE CHEM

Ch. 2 CHEMISTRY. Matter: has mass and takes up space Mass: quantity of matter an object has.

Atoms, Elements, and Compounds- Chapter 6

Glyoxal and Methylglyoxal; Chemistry and Their Effects on Secondary Organic Aerosol Dasa Gu Sungyeon Choi.

OXIDATION AND REPLACEMENT OF OLEIC ACID AT THE AIR/WATER INTERFACE TO UNDERSTAND FAT-COATED AEROSOLS Laura F. Voss, Kandice L. Harper, Gang Ma, Christopher.

Copyright©2000 by Houghton Mifflin Company. All rights reserved. 1 Aqueous Solutions Water is the dissolving medium, or solvent.

Modeling Dynamic Partitioning of Semi-volatile Organic Gases to Size-Distributed Aerosols Rahul A. Zaveri Richard C. Easter Pacific Northwest National.

Development of a Near-IR Cavity Enhanced Absorption Spectrometer for the detection of atmospheric oxidation products and amines Nathan C. Eddingsaas Breanna.

 o (100 nm) Relative Humidity Carrier Gas Stream NaCl Mg/Na Dependence.

ISSAOS 2008 l‘Aquila, September 2008 Aerosol Mass Spectrometry: The Aerosol mass Spectrometer Hugh Coe School of Earth, Atmospheric and Environmental Sciences.

Chapter 15: Solutions 15.1 Solubility 15.2 Solution Composition 15.3 Mass Percent 15.4 Molarity 15.7 Neutralization Reactions.

QUESTIONS 1.What molar fraction of HNO 3 do you expect to partition into fog droplets at room temperature? How does this compare to the fraction that would.

Matter Anything that has mass and takes up space.

The study of liquid-solid and glass transitions in finely divided aqueous systems Anatoli Bogdan Institute of Physical Chemistry, University of Innsbruck.

Reminders Quiz#2 and meet Alissa and Mine on Wednesday –Quiz covers Bonding, 0-D, 1-D, 2-D, Lab #2 –Multiple choice, short answer, long answer (graphical.

Physical Properties of Matter

Gas and Aerosol Partitioning Over the Equatorial Pacific Wenxian Zhang April 21, 2009.

The Land Breeze and ClNO 2 production over Santa Monica Bay Nick Wagner, Steven S. Brown, William P. Dubé, Brian M. Lerner, Eric J. Williams, Wayne Angevine,

1 The roles of H 2 SO 4 and organic species in the growth of newly formed particles in the rural environment Wu Zhijun Leibniz-Institute for Tropospheric.

Secondary Organic Aerosols

1 Solutions One substance dissolved in another substance.

KINETICS OF SURFACE-BOUND BENZO[A]PYRENE AND OZONE ON ORGANIC AND INORGANIC AEROSOLS N.-O. A. Kwamena, J. A. Thornton, J. P. D. Abbatt Department of Chemistry,

Prakash V. Bhave, Ph.D. Physical Scientist PM Model Performance Workshop February 10, 2004 Postprocessing Model Output for Comparison to Ambient Data.

1 Properties of Solutions Brown, LeMay Ch 13 AP Chemistry CaCl 2 (aq)

Liquid-Liquid Phase Separation In Mixed Organic-Inorganic Aerosols Institute For Atmosphere And Climate Science – ETH Zurich Gabriela Ciobanu Göteborg,

1 On the relationship between nitryl chloride (ClNO 2 ) and molecular chlorine (Cl 2 ) in coastal California Joel Thornton and Theran Riedel Department.

Matter and Composition What is matter?  MATTER is anything which has mass and occupies space.  Matter is all things that we can see, feel, and smell.

Simulating the Oxygen Content of Organic Aerosol in a Global Model

Biologically Important Molecules. I.Water Biologically Important Molecules I.Water A. Structure - polar covalent bonds.

Unit 8 Solution Chemistry

2006 Graduate Student Symposium Measurement of HCl (g) in troposphere and lower stratosphere with CIMS technique Analytical characteristics and its implications.

Yunseok Im and Myoseon Jang

Solutions and Acids and Bases. Matter synthesis.com/webbook/31_matter/matter2.jpg.

Properties of Matter 3.1. Quick Review  Matter is anything that: a) has mass, and b) takes up space  Mass = a measure of the amount of “stuff” (or material)

1 Solutions One substance dissolved in another substance.

METO 621 CHEM Lesson 4. Total Ozone Field March 11, 1990 Nimbus 7 TOMS (Hudson et al., 2003)

Many mass spectra are observed in addition to those of nitrogen (28amu) and benzene (78amu) molecules between 1 and 80amu, when the discharge is not generated.

Nitrous Oxide Focus Group Nitrous Oxide Focus Group launch event Friday February 22 nd, 2008 Dr Jan Kaiser Dr Parvadha Suntharalingam The stratospheric.

OsloCTM2  3D global chemical transport model  Standard tropospheric chemistry/stratospheric chemistry or both. Gas phase chemistry + essential heteorogenous.

Objective  To develop methods for analysis of compounds in organic aerosol particles Why is this important?  Environmental impact  Alternative fuels.

11/8/ Radical Enhanced Atomic Layer Chemical Vapor Deposition (REALCVD) SFR Workshop November 8, 2000 Frank Greer, John Coburn, David Frazer, David.

Surface Tension Measurements of Organic, Inorganic and Mixed Aqueous Solutions Acknowledgments Thanks to the UNH Chemistry Department and Dr. Greenslade’s.

Effect of surfactant Effect of morphology

OH KINETICS IN A SHIELDED ATMOSPHERIC PRESSURE PLASMA JET

Heterogeneous Chemistry of Gas-Phase Oxidants and Organic Aerosols Cindy DeForest Hauser, Davidson College, Davidson, NC Atmospheric Aerosols Affect.

Continuous measurement of airborne particles and gases

New Developments in Heterogeneous Aerosol Processes Affecting NOx and SO2 Randall Martin.

by Christopher R. Ruehl, James F. Davies, and Kevin R. Wilson

Determination of uptake coefficients ClO radicals with surfaces of sea

Presentation transcript:

The Fate and Effects of Organics At Atmospheric Interfaces Joel Thornton Department of Atmospheric Sciences University of Washington, Seattle Co-authors: V. Faye McNeill, Glenn Wolfe, Rob Wood

University of Washington, Seattle Department of Atmospheric Sciences Organics at Aerosol Interfaces Courtesy of PNNLO’Dowd, et al Nature Sea spray particles --likely contain organics that partition to surface --fatty acids, amino acids, proteinaceous material Pollution/Biogenic --phase separation possible even if “Water Soluble” Courtesy of Claudia Marcolli ETH, Zurich

University of Washington, Seattle Department of Atmospheric Sciences Kinetic limitation to water uptake Organics at Aerosol Interfaces ?? N2O5N2O5 OH NO 3 O 3 ?? SVOC H2OH2O

University of Washington, Seattle Department of Atmospheric Sciences Film Effects on Cloud Drop Number …an unconstrained problem FFC distributed by mass (open diamonds) FFC distributed by SA (circles) FFC only in 50% of the aerosol particles (+’s) See also: Feingold & Chuang, JAS 2006 Nenes, et al, GRL 2002

University of Washington, Seattle Department of Atmospheric Sciences Barrier to reactive uptake Organics at Aerosol Interfaces ?? N2O5N2O5 OH NO 3 O 3 ?? SVOC H2OH2O

University of Washington, Seattle Department of Atmospheric Sciences Barrier to Reactive Uptake (N 2 O 5 ) McNeill, et al JPC A 2007 McNeill, et al ACP 2006 Thornton, et al JPC A 2005 Antilla, et al, JPC A 2006 Folkers, et al, GRL 2003 Park, et al, JPC A 2007 (ASAP) Badger, et al, JPC A 2006 “Multilayer” “Monolayer”

University of Washington, Seattle Department of Atmospheric Sciences Aerosol Generation Atomizer solutions Dilute salt + trace soluble surfactant 60% RH: particles contain ~ ≤10 wt% surfactant R p ~ 150 nm Aerosol out Compressed N 2 ATOMIZER Vapor Deposition Salt particles coated with fatty acid by vapor deposition Coating thickness determined by CIMS calibration

University of Washington, Seattle Department of Atmospheric Sciences Surface Active Organics in Sea Salt Oleic Acid Hydrophilic Head + Hydrophobic Tail Palmitic Acid SDS Na+ - O 3 SO

University of Washington, Seattle Department of Atmospheric Sciences Suppression of N 2 O 5 Uptake See McNeill, et al ACP wt% per particle 1.5x10 14 molec/cm 2 (0.75 of a monolayer) in constant ratio to NaCl D p ~ 300 nm Wall loss 10 wt% SDS NaCl only

University of Washington, Seattle Department of Atmospheric Sciences Suppression of N 2 O 5 Uptake What different results with different films tell us. C12, C16, C18 McNeill, et al Antilla, et al, JPC A 2006 Folkers, et al, GRL  N2O5 very sensitive to availability of surface water 2.Film organization important 3.Perhaps a chain length effect 4.Underlying composition?

University of Washington, Seattle Department of Atmospheric Sciences Oxidant attack Organics at Atmospheric Interfaces ?? N2O5N2O5 OH NO 3 O 3 ?? SVOC H2OH2O

University of Washington, Seattle Department of Atmospheric Sciences Surface Active Organics in Sea Salt Oleic Acid Hydrophilic Head + Hydrophobic Tail Palmitic Acid

University of Washington, Seattle Department of Atmospheric Sciences Oxidation – CI-AMS Aerosols O 3 or NO 3 /N 2 O 5 Turbo Drag and Mech. pumps Quadrupole Octopole Ion Guide CDC 210 Po Ion Source Mech. pump volatilization Turbo Drag and Mech. pumps Quadrupole Octopole Ion Guide CDC 210 Po Ion Source Mech. pump volatilization Aerosols and OH Precursors: HONO, H 2 O 2 or O nm lamp Photo-reactor Flow Tube Chemical Ionization Mass Spectrometer Impactor

University of Washington, Seattle Department of Atmospheric Sciences Negative Ion Detection of Organics I amu I - H 2 O 145 amu I - oleic acid 409 amu 150 ºC Chemical ionization H2OH2O I -

University of Washington, Seattle Department of Atmospheric Sciences Negative Ion Detection of Organics 150 ºC Chemical ionization H2OH2O I - Impaction prior to volatilizationContinuous in-stream volatilization

University of Washington, Seattle Department of Atmospheric Sciences O 3 Oxidation of Oleate in Aq. Particles RH ~ 65% Decays consistent with 1 st order kinetics A range of O 3 concentrations and compositions examined Oleate + O 3  Products k I = 0.03 s -1 O 3 = 5 ppm O O O

University of Washington, Seattle Department of Atmospheric Sciences O 3 Oxidation of Oleate in Aq. Particles Mechanistic Information Decay constants are well described by Langmuir-Hinshelwood model K O3 ~ 4x cm 3 molec -1 Compare to – on other surfaces

University of Washington, Seattle Department of Atmospheric Sciences Inefficient O 3 Oxidation of Oleate Apparent Reaction Probability 1x10 -5 <  < 4x10 -5  Factor of lower than studies using pure oleic acid aerosols or coated walls. consistent w/single monolayer and reacto-diffusive length estimates O3O3 l~30 nm pure oleic  ~ nm thick oleic  ~ 2x10 -5

University of Washington, Seattle Department of Atmospheric Sciences OH Oxidation of Fatty Acids OH

University of Washington, Seattle Department of Atmospheric Sciences OH Oxidation of Fatty Acids Use SO 2 oxidation to constrain OH avg in reactor  OH determined w/chemical model using constrained OH avg  OH ~ 0.1 OH

University of Washington, Seattle Department of Atmospheric Sciences Oxidation Summary  O 3 oxidation of unsaturated fatty acids at the surface follow Langmuir-Hinshelwood mechanism.  oleic O3 ~ 1x10 -5  OH oxidation of saturated fatty acids at the surface of solid or aqueous particles is efficient:  OH ~ 0.1 Widely applicable mechanism: Poschl, et al JPC A 2001 Mmereki, et al JPC A 2003 Kwamena, et al JPC A 2004 McNeill, et al JPC A 2007 Rate may depend on underlying substrate Bertram, et al JPC 2000:  OH > 0.2 Molina, et al GRL:  OH > 0.2 Rate does not appear to depend on underlying substrate

University of Washington, Seattle Department of Atmospheric Sciences Implications: Film Lifetime  LH mechanism: alkenoic acid lifetime depends on K O3  Slower oxidation of oleate more consistent with atmospheric observations Robinson, et al JGR 2006  We infer  OH ~ 0.1 for palmitic and oleic acid on NaCl (s) and NaCl (aq) Range based on observed K O3 values saturated surfactant lifetime unsaturated surfactant lifetime oxidation lifetime (hours)

University of Washington, Seattle Department of Atmospheric Sciences Organics at Atmospheric Interfaces ?? N2O5N2O5 OH NO 3 O 3 ?? SVOC H2OH2O

University of Washington, Seattle Department of Atmospheric Sciences Oleate Ozonolysis Products I - oleic I - azelaic I - 9-oxononanoic I - nonanoic Signal (cps) Products consistent with those previously identified using pure oleic acid (+ some others) Dominant products are particle bound at room temperature

University of Washington, Seattle Department of Atmospheric Sciences OH Oxidation Products I - oleic

University of Washington, Seattle Department of Atmospheric Sciences Are Products Particle Bound?  Partitioning of ~ 90% of nonanoic acid to particles at room temperature not expected. Nonanoic acid an oligomeric unit?  OH oxidation products are numerous, some clearly small acids (formic, acetic) suggesting that volatilization by oxidation of surface organics is important source of OVOC and loss of aerosol HC.

University of Washington, Seattle Department of Atmospheric Sciences Take Home Points  Monolayer films significantly suppress the rates of gas- aerosol reactions, especially of hydrolysis reactions— likely a result of reduced water availability in the near- surface region.  OH oxidation of organics at the interface likely proceeds by true heterogeneous mechanism. Rapid,  OH ~ 0.1 (but not  OH ~ 1) for thin films.  Ozone oxidation of unsaturated surface organics appears to follow a very general Langmuir-Hinshelwood mechanism (often with similar rate constants).  Fate of oxidation products requires more investigation.

University of Washington, Seattle Department of Atmospheric Sciences Some of the Unresolved Issues  What extant of oxidation is required to remove barrier effect?  Is there a reservoir of surface active species in atmospheric particles that would replace those that get oxidized at the surface?  How does cloud processing change the surface composition of residual particles?  Need more field evidence for barrier effects and mixing state of organics in atmospheric particles

University of Washington, Seattle Department of Atmospheric Sciences Acknowledgements Anna Moon Glenn Wolfe Faye McNeill Reddy Yatavelli

University of Washington, Seattle Department of Atmospheric Sciences UW-CIMS Instrument < 150 kg < 1.5 kW < 0.75 m 3 >5 cps/ppt NO 3

University of Washington, Seattle Department of Atmospheric Sciences Palmitic Acid + OH on Salt Particles Palmitic Acid is efficiently oxidized by OH. By varying the OH source, we change the average OH in the reactor. Using  OH = 1 in a detailed model of the gas-particle interaction best reproduces the observed behavior.

University of Washington, Seattle Department of Atmospheric Sciences Aerosol Characterization SEM-EDAX: “Single Particle” Composition For every particle examined: internally mixed w/NaCl as dominant component

University of Washington, Seattle Department of Atmospheric Sciences Effects and Fate of Surface Active Organics Barrier to gas-aerosol mass transport? Enhance partitioning of semi-volatile organics? Surface bound organics bear the brunt of oxidant attack; source of volatile organics? N 2 O 5 ?? OxOx ? ? What are the rates and mechanisms for surface film oxidation and destruction?

University of Washington, Seattle Department of Atmospheric Sciences Working Questions--Salient Results Are the kinetics of alkenoic acid ozonolysis the same in mixed aqueous particles as for the pure substance? Does the oxidation of alkenoic acids occur at the gas- aerosol interface in mixed aqueous particles? Are ozonation products particle bound at room temperature? What dictates the lifetime of alkenoics in a surface film?

University of Washington, Seattle Department of Atmospheric Sciences Suppression of N 2 O 5 Uptake See McNeill, et al ACP wt% per particle “0.05 M” at 65% RH 3.4x10 6 molec/particle 1.5x10 14 molec/cm 2 (0.75 of a monolayer) in constant ratio to NaCl D p ~ 300 nm

University of Washington, Seattle Department of Atmospheric Sciences Recent Work on Barrier Effect Clifford, et al, PCCP 2007 See also Daumer, et al, JAS 1992 Xiong, et al, ES&T v32, 1998

University of Washington, Seattle Department of Atmospheric Sciences Suppression of N 2 O 5 Uptake C6 Thornton & Abbatt Do different results with different reactants and films tell us anything? C12, C18 McNeill, et al C8 Clifford, et al C12, C16, C18 McNeill, et al

University of Washington, Seattle Department of Atmospheric Sciences Suppression of N 2 O 5 Uptake Do different results with different reactants and films tell us anything? C6 Thornton & Abbatt C12, C18 McNeill, et al C8 Clifford, et al C12, C16, C18 McNeill, et al Antilla, et al, JPC A 2006 Folkers, et al, GRL 2003