Temperature and Power Output of the Lava Lake in Halema'uma'u Crater, Hawaii, Using a Space-Based Hyperspectral Imager

Space-based remote sensing has the potential to monitor volcanic activity on a global basis. We use infrared hyperspectral data measured from space to study the temperature field and power output for a long-lived lava lake at Halema'uma'u crater, Hawaii. Overflights were made on two days: a night collect October 16, 2009, and a day collect on December 27, 2009. The basic data are short-wave infrared (SWIR) optical spectra recorded in the 900-2500 nm wavelength range. Spectra in the lava lake show strongly elevated radiance at SWIR wavelengths. We illustrate how corrections are made to account for solar radiance in the day image and for atmospheric water vapor for both images. We assume that the spectrum at each pixel can be modeled as a linear combination of cool and hot components, weighted by the area of each component. The inversion uses an exhaustive search algorithm over all possible combinations of hot temperature and fractional area of the hot component, with the cool component set to ambient temperature. Temperature and fractional area calculations can be used to compute radiant flux (power) emitted from each pixel, and from the lake as a whole. Power output changes from 15.1 MW in October to 24.0 MW in December. Approximately 223 Kg/s ( ~ 0.07 m3/s) of molten basalt is required to maintain the observed power output of the lava lake.

[1]  Michael James,et al.  Surface temperature measurements of active lava flows on Kilauea volcano, Hawai′i , 2002 .

[2]  A. Harris,et al.  Thermal observations of degassing open conduits and fumaroles at Stromboli and Vulcano using remotely sensed data , 1997 .

[3]  D. Rothery,et al.  Volcano monitoring using short wavelength infrared data from satellites , 1988 .

[4]  Clive Oppenheimer,et al.  Thermal distributions of hot volcanic surfaces constrained using three infrared bands of remote sensing data , 1993 .

[5]  John P. Kerekes,et al.  Understanding radiative transfer in the midwave infrared: a precursor to full-spectrum atmospheric compensation , 2004, SPIE Defense + Commercial Sensing.

[6]  S. Hook,et al.  The ASTER spectral library version 2.0 , 2009 .

[7]  Robert Wright,et al.  On the retrieval of lava-flow surface temperatures from infrared satellite data , 2003 .

[8]  Michael S. Ramsey,et al.  Strategies, insights, and the recent advances in volcanic monitoring and mapping with data from NASA's Earth Observing System , 2004 .

[9]  E. Pilger,et al.  Radiant flux from Earth's subaerially erupting volcanoes , 2008 .

[10]  Paul E. Lewis,et al.  MODTRAN5: 2006 update , 2006, SPIE Defense + Commercial Sensing.

[11]  P. Mouginis-Mark,et al.  COOLING RATE OF AN ACTIVE HAWAIIAN LAVA FLOW FROM NIGHTTIME SPECTRORADIOMETER MEASUREMENTS , 1992 .

[12]  Maria Fabrizia Buongiorno,et al.  Spatial variations in lava flow field thermal structure and effusion rate derived from very high spatial resolution hyperspectral (MIVIS) data , 2009 .

[13]  Clive Oppenheimer,et al.  Lava flow cooling estimated from Landsat Thematic Mapper infrared data: The Lonquimay Eruption (Chile, 1989) , 1991 .

[14]  Clive Oppenheimer,et al.  Infrared image analysis of volcanic thermal features: Láscar Volcano, Chile, 1984–1992 , 1993 .

[15]  David Makowski,et al.  Advanced Responsive Tactically-Effective Military Imaging Spectrometer (ARTEMIS) Design , 2006, 2006 IEEE International Symposium on Geoscience and Remote Sensing.

[16]  J. Dozier A method for satellite identification of surface temperature fields of subpixel resolution , 1981 .

[17]  M. Wooster,et al.  Testing the accuracy of solar-reflected radiation corrections applied during satellite shortwave infrared thermal analysis of active volcanoes , 2001 .

[18]  R. Wright,et al.  Cooling rate of some active lavas determined using an orbital imaging spectrometer , 2010 .

[19]  Clive Oppenheimer,et al.  Mass flux measurements at active lava lakes: Implications for magma recycling , 1999 .