Underwater cryotrap - membrane inlet system (CT-MIS) for improved in situ analysis of gases by mass spectrometry. Torben Gentz & Michael Schlüter Alfred Wegener Institute for Polar and Marine Research Bremerhaven, Germany Presented at the 8thWorkshop on Harsh Environment Mass Spectrometry, St Petersburg, FL September 20, 2011
Outline Background Motivation Design of the Cryotrap Peltier element and stirling cooler. Why high resolution measurements? Improving detection limit and security system. Redesign of the sample inlet compartment Mass spectrometer, cryotrap, under water pump Field applications Summary 3D-measurements at gas flares
Background Worldwide distribution of gas flares and seepages. Man-made gas releases ^_ PM Pockmarks #* XY_SGD Active submarine!( MV_on_Sea Mud Volcanos Improved online and onside methods are required for the detection of gas flares, seepages as well as the calculation of mass fluxes of methane released from the seafloor.
Hydroacoustic and visual detection of gas release Hugh, colourfull impression Small source area with steep gas gradients Acoustic image of gas bubble plumes in the water column. Diameter of gas release: 5 cm Gas release in the North Sea Gas release at the Hakon Mosby Mud Volcano, Barent Sea continental slope
Gas analysis: State of the art Water column and sediment sampling Gas analysis by gas chromatography Phase separation (gas phase from aqueous phase): Headspace technique for analysis of discrete samples Problems: -time consuming, -coarse spatial and temporal resolution
Need for new methods Mono-parameter instruments HydroC, Contros Poly-parameter instruments Mets, Franatech Inspectr200-200, AML, by T. Short and G. Kibelka R. Camilli, H. Hemond, Trends Anal. Chem. 23 (2004) 307. Short, R. T. and others, J Am Soc Mass Spectr 12 (2001). : 676-682. Nereus/Kemonaut, by R. Camilli, H.F. Hemond
Motivation: getting rite of the water vapor 70 times magnification 320 times magnification Water vapor is the main gas that permeates through this membrane? Downgrades the detection limit Affects on the ionization effency Could cause condensation in the analytical line Downgrades the life time of the filament Indicate a high pressure in the analytical line For several applications including investigations of natural as well as manmade gas seepages there is a strong demand for: 1. Improve detection limit 2. Security System in case of membrane rupture
First step: Shipboard Cryo-Trap Intesity m/z=15 [Amps] coupled to the Inspectr200-200 Calibration MS 09.06.2008 3.00E-10 2.00E-10 1.00E-10 0.00E+00 y = 2,0412E-13x + 4,0236E-11 R² = 0,9985 0 200 400 600 800 1000 1200 CH4 [nmol L -1 ] Inspectr200-200 External membrane inlet system Cryo-trap: Dewar flask with -100 C ethanol Cooling Thermostats or liquid nitrogen Improved signal noise ratio at m/z 15 Higher ionisation effency High emission at the ion source Improved detection limit: From > 100nmol L -1 to 16 nmol L -1 CH 4 Schlueter, M., and T. Gentz. 2008. Application of Membrane Inlet Mass Spectrometry for Online and In Situ Analysis of Methane in Aquatic Environments. J Am Soc Mass Spectr 19: 1395-1402.
How to get a Cryo-Trap System to operate under water? Requirements for under water applications: (1) temperatures below -85 C have to be reached, (2) a small waste-heat production is required, (3) the energy consumption has to be below 10 W, (4) large quantity of water vapor need to be trapped (5) service life time of more than 10 hours is favorable (6) a short cool down time below 60 min is necessary, and (7) the system should be robust, of small dimensions and low weight The system was intended to be designed for application with different sensor systems (IR,MS) and for non lab environments.
Peltier element and stirling cooler. Requirements: (1) temperatures below -85 C have to be reached, (2) a small waste-heat production is required, (3) the energy consumption has to be below 10 W, Peltier element, Whatson Marlow, MI4040 Micro Stirling Cooler, Ricor K508
Comparison Temperature [ C] 100 80 60 40 20 0-20 -40-60 -80-100 -85 C 0 5 10 15 20 25 Time [min] Peltier element, Whatson Marlow, MI4040 B Temperarture [ C] 100 80 60 40 20 0-20 -40-60 -80-100 Heat sink Heat sink Cooling site Cooling side 0 150 300 1200 1300 Time [min] Micro Stirling Cooler, Ricor K508-85 C A Peltier element: 80 W at 6.8 V. Stirling cooler: 6 W at 24 V
Performance of the cryo-trap Requirements: (4) large quantity of water vapor need to be trapped (5) service life time of more than 10 hours is favorable (6) a short cool down time below 60 min is necessary Pressure [Torr] 6e-4 5e-4 4e-4 3e-4 2e-4 1e-4 96% 98% Temperature Water vapor Pressure 2.0e-7 1.8e-7 1.5e-7 1.3e-7 1.0e-7 7.5e-8 5.0e-8 2.5e-8 Water vapor [Amps] 40 20 0-20 -40-60 -80 Temperature [ C] 0 0 25 50 75 100 125 150 175 200 1325-100 Time [min]
Under water Cryo-Trap Requirements: (7) The system should be robust, of small dimensions and low weight Analyzer unit Connection to the sensor unit Specifications: Length: 290mm Outer diameter: 190mm Cooler unit Membrane unit Max depth: 200m Inner diameter: 180mm Weight: 5.1 kg Cooling area: 20mm Material: Aluminum
Cryo-Trap and redesign Design of the Inspectr200-200 (AML) Analyzer unit MIS & Gear pump Sample inlet Redesign of the Cryo trap & UWMS 1/8 Capillary Heater control Power supply Sensor unit (dry) CT-MIS (sample unit)
Application in harsh environments Deployment of the under water gas analyser system
How to find and 500m 280m investigate gas flares? Hydroacoustic in the water column Multibeam echosounding: High resolution bathymetrie of the seafloor Under water observation and measurements 500m Gas release 4 x 5 m 280m
Under water gas analyser, sampler and observing system Mode of deployment: Towed system by research vessel Mobile underwater platforms CT-UWMS Camera / Spot light CTD Syringe sampler Oxygen optode Energy supply Turbity sensor Bubble counter
3D-concentration This 24000 points allows calculation of budgets, gas fluxes etc. field of CH 4 Gas Bubbles CH 4(Dissolved) [nm/l]
Summary Under water cryo trap membrane inlet system for underwater and other harsh environment: improves detection limits reduce the internal pressure significantly expand the lifetime of the analyser secure the analyser for inflowing water is easily to adapt to other sensors The improved detection limit of the UWMS by the CT enhanced the computation of mass budgets as well as the search for gas flares, since small CH 4 concentration gradients are guiding to the gas flares.
Thank you for your attention www.awi.de Torben.Gentz@awi.de