For the Atmospheric Conductivity analysis, it is essential to scrutinize the Earth's crust (A), the atmosphere (B), and induced atmospheric electricity (C) and their interplay within the system.
A. Structural Analysis: The Coexistence Triad is used to inspect how the Earth's crust (A1), the atmospheric layers (B1), and induced atmospheric electricity (C1) must coexist in equilibrium for the entire system to function aptly.
A1: Earth's crust: The conductive materials in Earth's crust, such as basalt and granite, are integral for the transmission of high-frequency, alternating electric currents injected into the crust. The crust's conductivity and overall composition significantly influence the efficiency of energy transmission.The terrestrial crust plays a fundamental role by housing the source and generator for initial AC currents. Any disruptive event, such as seismic activity or changes in Earth's magnetic field, can affect the initial generation of the current and subsequently impact the entire process of wireless electricity transmission.
B1: Atmospheric Layers: The atmosphere, particularly the ionized upper layer, acts as a medium for the propagation of electromagnetic waves. The ionosphere's conditions and ion-concentration affect the ease of transmission and degree of signal reflection or absorption therein. The atmosphere, specifically the ionosphere, becomes the pathway for the generated current. Changes in atmospheric/ionospheric conditions, such as solar radiation, space weather events or altering of ion-concentration can affect the ease of transmission and the degree of signal reliability.
C1: Induced Atmospheric Electricity: The induced electricity in the atmosphere becomes an essential facet for this system. Any unintentional variance in frequency or current strength could negatively impact the reception of power or even risk damaging the system. The interplay between the Earth's crust and the atmosphere establishes a resonating circuit crucial for Tesla's wireless energy transmission concept. Any deviations in the Earth's or atmosphere's conditions could disrupt this resonant network, adversely affecting the wireless power transmission mechanism.
B. Functional Analysis: The Stabilization Triad illuminates the processes of injecting currents into the Earth's crust (A2), the resulting changes in atmospheric/ionospheric properties (B2), and the extraction of this induced power at receivers (C2).
A2: Current Injection into the Earth: Tesla's system injects currents into the Earth's conductive crust. Any changes in the Earth's conductivity can affect the propagation of these waves and alter the overall signal strength. Varying the injected current intensity and frequency can alter the Earth's electric charge. Understanding the effects of these changes is crucial to maintaining the effective functioning of the system. Even though inserting high-frequency currents into the Earth's crust is crucial, it doesn't linearly correspond with the success of global wireless power transmission due to the other fluctuating variables.
B2: Atmospheric/Ionospheric Changes: The correlation between charge generation and the spread of EM waves is a vital determinant for the feasibility of global wireless power transmission. Disruptions in either component would hamper the overall efficiency of the system. The propagation of changing atmospheric currents can cause fluctuations in the Earth's magnetic and electric fields. Managing these changes is pivotal to ensure stable and consistent wireless power transmission.
C2: Current extraction at receivers: Ensuring the safety and reliability of the reception stations is vital for the system's success. Thus, controlling and managing alterations in the induced atmospheric electricity is imperative for preventing potential damage to the system or power outages.
C. Potential Analysis: The Nonlinear Triad suggests future challenges and scenarios where elements of the system may behave in a non-linear fashion. EM wave propagation in the Atmosphere (A3) doesn't necessarily correspond with successful Current Extraction at receivers (B3), and these processes together don't necessarily guarantee the Achievement of Global Wireless Power Transmission (C3).
A3: EM Wave Propagation in Atmosphere: High-frequency currents may propagate in the atmosphere. However, this doesn't guarantee successful power extraction at receivers due to possible disruption factors like atmospheric changes or receiver design flaws. The atmospheric layers, particularly the ionosphere, play a vital role in maintaining the survivability and strength of the electromagnetic waves. Variation in atmospheric conductivity could affect wave's travel and reflection.
B3: Current Extraction at receivers: Although a station might be equipped for successful power extraction, it does not guarantee a stable global wireless power transmission due to fluctuations in global atmospheric conditions.
C3: Achievement of Global Wireless Power Transmission: The desired outcome—global wireless power transmission—relies on a complex interaction of variables such as global atmospheric conditions, the Earth's crust conductivity, and the receiver's placement and design. Consequently, it is not a linear outcome of either wave propagation or successful power extraction.