Controlled‐source audiofrequency magnetotelluric responses of three‐dimensional bodies

Geophysics ◽  
1991 ◽  
Vol 56 (2) ◽  
pp. 255-264 ◽  
Author(s):  
N. B. Boschetto ◽  
G. W. Hohmann
Keyword(s):  
Plane Wave ◽  
Electric Field ◽  
Near Field ◽  
Three Dimensional ◽  
Sole Source ◽  
Far Field ◽  
Field Zone ◽  
Wave Source ◽  
Controlled Source ◽  
Field Response

Modeling the controlled‐source audiofrequency magnetotelluric (CSAMT) responses of simple three‐dimensional (3-D) structures due to a grounded electric bipole confirms that the CSAMT technique accurately simulates plane‐wave results in the far‐field zone of the transmitter. However, at receiver sites located above large conductive or resistive bodies, the presence of the inhomogeneity extends or reduces, respectively, the frequency range of the far‐field zone. Measurements made on the surface beyond a large 3-D body display a small but spatially extensive effect due to decay of the artificial primary field. Situating a 3-D inhomogeneity beneath the source permits an evaluation of “source overprint” effects. When such a body is resistive, a slight shift in the near‐field response to higher frequencies occurs. When a body below the transmitter is conductive, it is possible to make far‐field measurements closer to the transmitter or lower in frequency. However, as the size of the conductor and its secondary‐field response increases, large transition‐zone responses distort the data. For both a plane‐wave source and a finite source, current channeling into a 3-D conductor from conductive overburden enhances the response of a target. The modeled response of a dike‐like conductor shows no better results for either the broadside or collinear configuration. The location and extent of such a body are better defined when measuring the electric field perpendicular to the strike of the prism, but resistivity estimates are better when using the electric field parallel to the strike of the prism, irrespective of transmitter orientation. Models designed from data collected at Marionoak, Tasmania, yield results which indicate that the thin, vertical graphitic unit intersected by drilling is detectable by the CSAMT method, but probably is not the sole source of the large anomaly seen in the CSAMT data.

Controlled‐source audiomagnetotellurics in geothermal exploration

Geophysics ◽  
1982 ◽  
Vol 47 (1) ◽  
pp. 100-116 ◽  
Author(s):  
Stewart K. Sandberg ◽  
Gerald W. Hohmann
Keyword(s):  
Plane Wave ◽  
Hot Springs ◽  
Three Dimensional ◽  
Field Tests ◽  
Transverse Magnetic ◽  
Transverse Magnetic Mode ◽  
Geothermal Exploration ◽  
Wave Source ◽  
Controlled Source ◽  
Contour Maps

Theoretical and field tests indicate that the controlled‐source audiomagnetotelluric (CSAMT) method provides an efficient means of delineating the shallow resistivity pattern above a hydrothermal system. Utilizing a transmitter overcomes the main limitation of conventional audiomagnetotellurics—variable and unreliable natural source fields. Reliable CSAMT measurements can be made with a simple scalar receiver. Our calculations for a half‐space show that the plane‐wave assumption is valid when the transmitter is more than 3 skin depths away in the broadside configuration and more than 5 skin depths away in the collinear configuration. Three‐dimensional (3-D) numerical modeling results for a bipole source 5 skin depths away compare well with those for a plane‐wave source, showing that the method is valid. A CSAMT survey at the Roosevelt Hot Springs geothermal area in Utah produced apparent resistivity contour maps at four frequencies: 32, 98, 977, and 5208 Hz. These maps show the same features as those of a dipole‐dipole resistivity map. We also collected detailed CSAMT data at 10 frequencies on two profiles. Two‐dimensional (2-D) plane‐wave modeling (transverse magnetic mode) of the resulting pseudo‐sections yields models similar to those derived by modeling the dipole‐dipole resistivity data. However, CSAMT resolved details not shown by the resistivity modeling. Thus, high resolution along with an efficient field procedure make CSAMT an attractive tool for geothermal exploration.

Reply to L. Szarka by the authors

Geophysics ◽  
1988 ◽  
Vol 53 (5) ◽  
pp. 727-729
Author(s):  
L. C. Bartel ◽  
R. D. Jacobson
Keyword(s):  
Half Space ◽  
Near Field ◽  
Three Dimensional ◽  
Far Field ◽  
Audio Frequency ◽  
Opportunity To Respond ◽  
Controlled Source ◽  
Electrical Structure ◽  
Homogeneous Half Space ◽  
Correction Scheme

We welcome the opportunity to respond to comments by Szarka on our recent paper. The main points he raised on our near‐field correction scheme for controlled‐source audio‐frequency magnetotelluric (CSAMT) data are the application of the correction scheme and the near‐field/far‐field demarcation in the presence of layers and the application in the presence of electrical structure beneath the transmitter location. In our paper, we addressed the application for three‐dimensional electrical structure beneath the receiver location with the transmitter over a homogeneous half‐space. In this reply we wish to clarify these points and point out possible limitations of our correction scheme.

Hydrodynamic Study of Terahertz Three-Dimensional Plasma Resonances in InGaAs Diodes

2011 ◽  
Vol 324 ◽  
pp. 415-418
Author(s):  
Pierre Ziadé ◽  
Hugues Marinchio ◽  
Christophe Palermo ◽  
Ziad Kallassy ◽  
Luca Varani
Keyword(s):  
Electric Field ◽  
Field Effect Transistors ◽  
Plasma Frequency ◽  
Three Dimensional ◽  
Optical Excitation ◽  
Poisson Solver ◽  
Hydrodynamic Approach ◽  
Field Response ◽  
Hydrodynamic Study ◽  
Excitation Conditions

We investigate the presence of plasma resonances in InGaAs n+−n−n+ diodes under different optical excitation conditions. In particular, we study the case of diodes submitted to an optical photoexcitation presenting a beating in the terahertz frequency domain. For this purpose, we calculate the electric field response in the middle of the n and n+ regions using a hydrodynamic approach self-consistently coupled to a one-dimensional Poisson solver. In particular, the analysis of the electric field response to an optical beating as a function of the doping and the geometry of the devices allows us to evidence in all the considered cases the presence of resonances in both n and n+ regions. However, while the observed resonances agree with the theoretical 3D plasma frequency in the n+ external regions, we point out a shift towards higher frequencies in the n region. We show that this shift towards the n+ 3D plasma frequency is due to the strong coupling between the two region modes, and tends to disappear when the n region lengthens, whereas the influence of the n+ regions length on the resonance frequency is negligible. Moreover, we show that the amplitude of the plasma resonances can be enhanced at high doping levels and by increasing the level of the optical photoexcitation. The obtained results show clearly that the resonances associated with 3D plasma waves in InGaAs diodes lie in the THz domain for typical values of dopings and lengths, thus opening new possibilities to exploit not only field effect transistors but also diodes as solid-state terahertz devices operating at room temperature.

On: “Results of a controlled‐source audiofrequency magnetotelluric survey at the Puhimau thermal area, Kilauea Volcano, Hawaii, by L. C. Bartel and R. D. Jacobson (GEOPHYSICS, 52, 665–677, May 1987)

Geophysics ◽  
1988 ◽  
Vol 53 (5) ◽  
pp. 726-727 ◽  
Author(s):  
Lásaló Szarka
Keyword(s):  
Near Field ◽  
Kilauea Volcano ◽  
Far Field ◽  
Gradual Change ◽  
Demarcation Line ◽  
Controlled Source ◽  
Layered Earth ◽  
Kīlauea Volcano ◽  
Subsurface Layers

A growing number of papers being published on the CSAMT-MT curve transformation, which — as the authors state — allows a simpler magnetotelluric interpretation of the corrected CSAMT curves. The concept of near‐field corrections is based on electromagnetic relations over a homogeneous earth, and the effects of subsurface layers or lateral inhomogeneities are usually neglected. Bartel and Jacobson (1987) especially suppress the bounds of the near‐field correction: After presenting several near‐field correction curves over a homogeneous earth in their Figure 2 (which includes an idealistic demarcation line instead of a gradual change between near‐field and far‐field regions), they simply add that “…for a layered earth a similar demarcation occurs between the far‐ and near‐field regimes.” Further, the problem of lateral inhomogeneities is not mentioned in the paper. Such a description might lead to an oversimplification. I should like here to underline both limitations.

The effects of source polarization in CSAMT data over two massive sulfide deposits in Australia

Geophysics ◽  
1993 ◽  
Vol 58 (12) ◽  
pp. 1764-1772 ◽  
Author(s):  
Richard Kellett ◽  
John Bishop ◽  
Emmett Van Reed
Keyword(s):  
Structural Information ◽  
Near Field ◽  
Real Data ◽  
Black Shales ◽  
Electromagnetic Response ◽  
Resistivity Structure ◽  
Field Zone ◽  
Controlled Source ◽  
Source Field ◽  
Eastern Australia

Since the advent of the controlled‐source audio‐magnetotelluric method it has been recognized that the location and orientation of the bipole source is important in determining the response of the earth at the receiver. In this study, two‐dimensional (2-D) far‐field modeling has been used to illustrate the frequency-domain electromagnetic response of a simple conductive dike for two orthogonal polarizations of the source field. The current gathered from the surrounding media by the dike, when the electric field is parallel to the strike direction (E‐polarization), produces a strong anomaly not seen in the perpendicular H‐polarization. This model response has been identified in real data sets over the Rosebery and Flying Doctor orebodies of eastern Australia. In the case of Rosebery the E‐polarization data yielded little structural information because the penetration of the signal was reduced by strong current channeling in the orebody and adjacent black shales. At the Flying Doctor prospect the model predictions held but changes in the extent of the near‐field zone, for the two bipole locations, dominate the data. The changes in the source field observed over the Flying Doctor prospect are interpreted as evidence for anisotropy in the regional resistivity structure. The controlled‐source is a fundamental component of the CSAMT system, and the choice of the bipole location and orientation must be made considering the geology of the target region and the surrounding regional resistivity structure.

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