Capacitive electromagnetic formation surveillance using passive source

The invention claimed is: 1. A method of monitoring a hydrocarbon-bearing formation, the method comprising: measuring, by an electromagnetic sensor positioned adjacent a borehole in the hydrocarbon-bearing formation, passive, naturally-occurring, electromagnetic signals generated by interaction of solar wind with earth's magnetosphere adjacent the borehole; measuring over a period of time, by a borehole sensor positioned within the borehole, electromagnetic signals generated within the borehole, wherein the electromagnetic signals change over the period of time due to variations in fluid distributions within the hydrocarbon-bearing formation, wherein the electromagnetic signals are measured over a range of frequencies over the period of time; determining, by one or more processors, electromagnetic changes to the electromagnetic signals generated within the borehole and to the passive, naturally-occurring electromagnetic signals over the period of time; and generating a computational model of the hydrocarbon-bearing formation based in part on the electromagnetic changes, wherein determining the electromagnetic changes to the electromagnetic signals over the period of time comprises: determining, from among the range of frequencies, a sub-range of frequencies at which a majority of the electromagnetic changes over the period of time were measured and a magnitude of the electromagnetic changes at the sub-range of frequencies; numerically determining an attenuation of changes to the passive, naturally-occurring electromagnetic signals over the period of time based on the sub-range of frequencies and based on a resistivity of the hydrocarbon-bearing formation; and determining an intensity of electric and magnetic field variations resulting from the naturally-occurring electromagnetic signals to determine corresponding field variations within the borehole. 2. The method of claim 1 , wherein the electromagnetic signals are naturally generated and measured within the borehole. 3. The method of claim 1 , wherein the borehole sensor comprises a tri-axial electromagnetic sensor configured to measure magnetic signals and electric field signals within the borehole. 4. The method of claim 1 , wherein either the electromagnetic sensor or the borehole sensor comprises a capacitive electric sensor. 5. The method of claim 1 , wherein the period of time over which the electromagnetic signals are measured is in an order of weeks or more. 6. The method of claim 1 , wherein determining the electromagnetic changes to the electromagnetic signals over the period of time comprises: for a plurality of time instants in the period of time: identifying an electromagnetic signal value measured at each time instant of the plurality of time instants; and identifying a passive, naturally-occurring, electromagnetic signal measured at each corresponding time instant of the plurality of time instants; and determining a ratio of the electromagnetic signal value and the passive, naturally-occurring, electromagnetic signal measured at each corresponding time instant of the plurality of time instants. 7. The method of claim 1 further comprising: processing the passive, naturally-occurring, electromagnetic signals generated by the interaction of solar wind with earth's magnetosphere adjacent the borehole by stacking to reduce an effect of noise; and processing the electromagnetic signals generated within the borehole by stacking to reduce an effect of noise. 8. A hydrocarbon-bearing formation monitoring system comprising: an electromagnetic sensor positioned adjacent to a borehole formed in a hydrocarbon-bearing formation, the electromagnetic sensor configured to measure passive, naturally-occurring, electromagnetic signals generated by interaction of solar wind with earth's magnetosphere adjacent the borehole, wherein the electromagnetic sensor comprises: a first capacitive electric-field sensor comprising: a first plurality of plates configured to detect fluctuating passive, naturally-occurring electric signals adjacent the borehole, and first electrical circuitry connected to the first plurality of plates, wherein the fluctuating passive, naturally-occurring electric signals induce a first displacement current in the first electrical circuitry; a borehole sensor positioned within the borehole, the borehole sensor configured to measure, over a period of time, electromagnetic signals generated within the borehole, wherein the electromagnetic signals change over the period of time due to variations in fluid distributions within the hydrocarbon-bearing formation; and a computer system comprising: one or more processors; and a computer-readable medium storing instructions executable by the one or more processors to perform operations comprising: determining electromagnetic changes to the electromagnetic signals generated within the borehole and to the passive, naturally-occurring electromagnetic signals over the period of time; and generating a computational model of the hydrocarbon-bearing formation based in part on the electromagnetic changes. 9. The system of claim 8 , wherein the borehole sensor comprises: a second capacitive electric-field sensor comprising: a second plurality of plates configured to receive fluctuating electric signals from within the borehole, and second electrical circuitry connected to the second plurality of plates, wherein the fluctuating electric signals induce a second displacement current in the second electrical circuitry. 10. The system of claim 9 , wherein the electromagnetic changes to the electromagnetic signals generated within the borehole and to the passive, naturally-occurring electromagnetic signals over the period of time are determined based on the first displacement current and the second displacement current. 11. The system of claim 8 , wherein the borehole sensor comprises a tri-axial electromagnetic sensor configured to measure magnetic signals and electric signals within the borehole. 12. The system of claim 8 , wherein determining electromagnetic changes to the electromagnetic signals generated within the borehole and to the passive, naturally-occurring electromagnetic signals over the period of time comprises: determining ratios of the electromagnetic signals generated within the borehole and the passive, naturally-occurring electromagnetic signals over the period of time; and determining an impedance of the hydrocarbon-bearing formation in which the borehole is formed based on the determined ratios. 13. The system of claim 8 , wherein the period of time over which the electromagnetic signals are measured is in an order of weeks or more. 14. The system of claim 8 , wherein each of the electromagnetic sensor and the borehole sensor is configured to measure electromagnetic signals over a range of frequencies over the period of time. 15. The system of claim 14 , wherein determining the electromagnetic changes to the electromagnetic signals over the period of time comprises: determining, from among the range of frequencies, a sub-range of frequencies at which a majority of the electromagnetic changes over the period of time were measured and a magnitude of the electromagnetic changes at the sub-range of frequencies; numerically determining a skin depth of changes to the passive, naturally-occurring electromagnetic signals over the period of time based on the sub-range of frequencies and based on a resistivity of the hydrocarbon-bearing formation; and determining an intensity of electric and magnetic field variations resulting from the naturally-occurring electromagnetic