Composition and variation of noise recorded at the Yellowknife Seismic Array, 1991–2007

[1] We analyze seismic noise recorded on the 18 short-period, vertical component seismometers of the Yellowknife Seismic Array (YKA). YKA has an aperture of 23 km and is sited on cratonic lithosphere in an area with low cultural noise. These properties make it ideal for studying natural seismic noise at periods of 1–3 s. We calculated frequency-wave number spectra in this band for over 6,000 time windows that were extracted once per day for 17 years (1991–2007). Slowness analysis reveals a rich variety of seismic phases originating from distinct source regions: Rg waves from the Great Slave Lake; Lg waves from the Atlantic, Pacific, and Arctic Oceans; and teleseismic P waves from the north Pacific and equatorial mid-Atlantic regions. The surface wave energy is generated along coastlines, while the body wave energy is generated at least in part in deep-water, pelagic regions. Surface waves tend to dominate at the longer periods and, just as in earthquake seismograms, Lg is the most prominent arrival. Although the periods we study are slightly shorter than the classic double-frequency microseismic band of 4–10 s, the noise at YKA has clear seasonal behavior that is consistent with the ocean wave climate in the Northern Hemisphere. The temporal variation of most of the noise sources can be well fit using just two Fourier components: yearly and biyearly terms that combine to give a fast rise in microseismic power from mid-June through mid-October, followed by a gradual decline. The exception is the Rg energy from the Great Slave Lake, which shows a sharp drop in noise power over a 2-week period in November as the lake freezes. The Lg noise from the east has a small but statistically significant positive slope, perhaps implying increased ocean wave activity in the North Atlantic over the last 17 years.

[1]  D. Weichert,et al.  The Canadian seismic array monitor processing system (cansam) , 1976, Bulletin of the Seismological Society of America.

[2]  Peter D. Bromirski,et al.  Vibrations from the “Perfect Storm” , 2001 .

[3]  Nicholas E. Graham,et al.  Ocean wave height determined from inland seismometer data: Implications for investigating wave climate changes in the NE Pacific , 1999 .

[4]  Sharon Kedar,et al.  The origin of deep ocean microseisms in the North Atlantic Ocean , 2007, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[5]  Michel Campillo,et al.  High-Resolution Surface-Wave Tomography from Ambient Seismic Noise , 2005, Science.

[6]  J. Lefèvre,et al.  Source locations of secondary microseisms in western Europe: Evidence for both coastal and pelagic sources , 2007 .

[7]  J. Lei,et al.  Global P-wave tomography: On the effect of various mantle and core phases , 2006 .

[8]  Peter Gerstoft,et al.  Global P, PP, and PKP wave microseisms observed from distant storms , 2008 .

[9]  Frank Krüger,et al.  Ocean-generated microseismic noise located with the Gräfenberg array , 1998 .

[10]  Richard C. Aster,et al.  Multidecadal Climate-induced Variability in Microseisms , 2008 .

[11]  J. Capon High-resolution frequency-wavenumber spectrum analysis , 1969 .

[12]  Robert H. Shumway,et al.  Mixed Signal Processing for Regional and Teleseismic Arrays , 2006 .

[13]  Peter Gerstoft,et al.  Surface wave tomography from microseisms in Southern California , 2005 .

[14]  Robert K. Cessaro,et al.  Sources of primary and secondary microseisms , 1994, Bulletin of the Seismological Society of America.

[15]  Keith D. Koper,et al.  Short Note Seasonal Anisotropy in Short-Period Seismic Noise Recorded in South Asia , 2008 .

[16]  Keith McCamy,et al.  Microseisms: Coastal and pelagic sources , 1969 .

[17]  Robert North,et al.  Estimation of Background Noise for International Monitoring System Seismic Stations , 2002 .

[18]  B. O. Ruud,et al.  Rg observations from four continents: inverse- and forward-modelling experiments , 1993 .

[19]  Michael H. Ritzwoller,et al.  Source location of the 26 sec microseism from cross‐correlations of ambient seismic noise , 2006 .

[20]  Ralph A. Stephen,et al.  Mid‐ocean microseisms , 2005 .

[21]  Michel Campillo,et al.  A study of the seismic noise from its long-range correlation properties , 2006 .

[22]  I. Bondár,et al.  Teleseismic slowness-azimuth station corrections for the International Monitoring System Seismic Network , 1999 .

[23]  H.-H. Essen,et al.  Microseismological evidence for a changing wave climate in the northeast Atlantic Ocean , 2000, Nature.

[24]  Frank L. Vernon,et al.  Strong directivity of ocean‐generated seismic noise , 2004 .

[25]  Zoltan A. Der,et al.  Spatial coherence structure and attenuation of the Lg phase, site effects, and the interpretation of the Lg coda , 1984 .

[26]  R. Courtland Earth science: Harnessing the Hum , 2008, Nature.

[27]  Xiao‐Bi Xie,et al.  Explosion-Source Energy Partitioning and Lg-Wave Excitation: Contributions of Free-Surface Scattering , 2008 .

[28]  Michael H. Ritzwoller,et al.  Characteristics of ambient seismic noise as a source for surface wave tomography , 2008 .

[29]  M. Longuet-Higgins A theory of the origin of microseisms , 1950, Philosophical Transactions of the Royal Society of London. Series A, Mathematical and Physical Sciences.

[30]  E. R. Engdahl,et al.  Constraints on seismic velocities in the Earth from traveltimes , 1995 .

[31]  Peter Gerstoft,et al.  When Katrina hit California , 2006 .

[32]  T. Tanimoto Geophysics: Humming a different tune , 2008, Nature.

[33]  R. Widmer-Schnidrig,et al.  The horizontal hum of the Earth: A global background of spheroidal and toroidal modes , 2008 .

[34]  F. Anglin Detection capabilities of the Yellowknife seismic array and regional seismicity , 1971, Bulletin of the Seismological Society of America.