层裂对区域震相Lg波的影响
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摘要
地下核爆炸Lg波的激发机制,目前尚未十分清楚.普遍接受的观点是:伴随层裂源的补偿线性矢量偶极源激发的Rg波的散射形成的S波,是Lg波的最主要贡献因素.本文利用频谱比对方法,结合合成理论地震图方法,基于东哈萨克斯坦地区速度模型,分析了东哈萨克斯坦地壳速度模型下的层裂对区域震相Lg波的影响,并进一步分析了该地区的实际观测资料.结果表明,层裂时间函数对Lg波具有扇贝形调制作用;Lg波振幅谱的低谷点源自于补偿线性矢量偶极(CLVD)源激发的Rg波.这一结果也表明,东哈萨克斯坦速度模型下的Lg波受层裂的调制作用,与内华达试验区的Lg波是一样的,进一步支持了Patton和Taylor的观点,对于进一步理解及更好地利用Lg波具有重要理论指导意义.
The generation mechanism of Lg wave from underground nuclear explosion is still not clear at present. The general viewpoint is that the S wave generated by the near-source scattering of explosion-generated Rg appears to be the primary contributor to the low-frequency Lg (0.2~2.0 Hz) from nuclear explosions. The viewpoint is supported by the analysis of regional data from several Yucca flats, NTS explosions by Patton and Taylor, who further indicated that the prominent low-frequency spectral null in Lg is due to Rg from a compensated linear vector dipole (CLVD) source. In this paper, the data from Kazakstan Test Sites are investigated by a spectral ratio method. We have found that the spectral ratio of Lg waves is characterized by a spectral scalloping and a pronounced null, and the spectral null does not shift with spall dwell times, showing a strong dependence on shot depth and a very good agreement with those expected from Rg due to a CLVD source.
The generation mechanism of Lg wave from underground nuclear explosion is still not clear at present. The general viewpoint is that the S wave generated by the near-source scattering of explosion-generated Rg appears to be the primary contributor to the low-frequency Lg (0.2~2.0 Hz) from nuclear explosions. The viewpoint is supported by the analysis of regional data from several Yucca flats, NTS explosions by Patton and Taylor, who further indicated that the prominent low-frequency spectral null in Lg is due to Rg from a compensated linear vector dipole (CLVD) source. In this paper, the data from Kazakstan Test Sites are investigated by a spectral ratio method. We have found that the spectral ratio of Lg waves is characterized by a spectral scalloping and a pronounced null, and the spectral null does not shift with spall dwell times, showing a strong dependence on shot depth and a very good agreement with those expected from Rg due to a CLVD source.
引文
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ChenXF.1999.Seismogramsynthesisinmultilayeredhalf spacePartI.Theoreticalformulations[J].EarthquakeRe searchinChina,13:149~174
ChenXF,ZhangHM.2001.AnefficientmethodforcomputingGreen′sfunctionsforalayeredhalf spaceatlargeepi centraldistances[J].BullSeismSocAmer,91:58~869
GuptaIN,ZhangTR,WagnerRA.1997.Low FrequencyLgfromNTSandKazakhnuclearexplosions observations andinterpretation[J].BullSeismSocAmer,87:1115~1125
GuptaIN,ChanWW,WangerRA.1992.Acomparisonofregionalphasesfromundergroundnuclearexplosionsat EastKazakhandNevadaTestSites[J].BullSeismSocAmer,82:352~382
McLaughlinKL,BarkerTG,DaySM,etal.1988.EffectsofDepthofBurialonExplosionandEarthquakeRegion alSeismograms:RegionalDiscriminationandYieldEstimation[R].Jolla,California:S CUBEDReportSSS R889844
PattonHJ,TaylorSR.1995.AnalysisofLgspectralratiosfromNTSexplosions:Implicationsforthesourcemecha nismsofspallandthegenerationofLgwaves[J].BullSeismSocAmer,85:220~236
StumpBW.1985.Constrainsonexplosivesourcewithspallfromnuclearsourcewaveforms[J].BullSeismSocAmer,74:361~378
TaylorSR,DennyMD.1989.RegionaldiscriminationbetweenNTSexplosionWesternUSearthquakes[J].BullSeism SocAmer,79:1142~1176
WallaceTC.1991.Bodywaveobservationsoftectonicrelease[A].In:TaylorSR,PattonHJ,RichardsPGeds.Ex plosionSourcePhenomenology[C].WashingtonDC:AmericanGeophysicalUnion,65:161~170
ZhangH,ChenXF,ChangS.2003.Anefficientmethodforcomputingsyntheticseismogramsforalayeredhalf space withsourcesandreceiversatcloseorsamedepth[J].PureApplGeophys,160:467~486
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