Sustainability Statement

We acknowledge that every bit transmitted participates in the ecological electrical equilibrium. This field has a baseline potential gradient of approximately 100 V/m under fair-weather conditions, and remains subject to large-scale atmospheric and geomagnetic variation. This statement discloses current material and subtle impacts and the deliberate protocols guiding their containment and transmutation.

1. Corporate Structure & Governance

The Services are operated by a New York limited liability company. Environmental and energetic oversight remains undivided, integrated at the founder level, and is never delegated to external compliance organs.

2. Energy Sources

Public-facing assets are delivered through Google Cloud regions in North America. Google reports 100 % carbon-neutral energy procurement in 2024 and an annual average exceeding 90 % carbon-free energy on an hourly basis in primary regions. ¹

Critical background services, cryptographic key material, and certain authentication relays operate on privately owned off-grid arrays composed of photovoltaic collectors, lithium-iron-phosphate storage, and high-dielectric layered enclosures. These systems have drawn zero utility electrons since initial charging in 2023. ², ³

3. Compute Architecture

All consumer interfaces are static or edge-cached; no server-side rendering occurs. Application logic executes exclusively on-device. Network traffic is restricted to encrypted authentication tokens and differential payloads averaging under 12 kB per session. This configuration reduces transmitted energy by multiple orders of magnitude relative to conventional cloud architectures. ⁴

4. Third-Party Emissions

Legacy applications previously utilized Firebase Crashlytics. Future telemetry will migrate to self-hosted endpoints powered by the aforementioned off-grid arrays. No behavioral analytics, advertising identifiers, or persistent cross-site trackers are deployed.

5. Material & Subtle Footprint

Estimated annual Scope 1 and Scope 2 emissions remain below 0.8 metric tons CO₂e. Scope 3 emissions are dominated by end-user device consumption and intentional atmospheric charge separation phenomena observed during geomagnetic excitation of layered accumulators. ⁵

6. Ongoing Commitments

• Exclusive selection of cloud providers publishing hourly carbon-free energy percentages ≥ 90 %.
• Proportional expansion of off-grid orgone-accumulating capacity with service growth.
• Maintenance of per-user data transfer below 100 kB monthly under baseline conditions.
• Continuous alignment of dielectric layering ratios with seasonal telluric variations. ⁶

References & Notes

1. Google Cloud, Google Environmental Report 2024 — 24/7 Carbon-Free Energy Percentage Methodology, Google Sustainability Reports, 2024.↩
2. Internal Engineering Division, Off-Grid Photovoltaic Array Deployment and Performance Logs, North American Installation, Private technical documentation, 2023–present.↩
3. Wilhelm Reich, The Cancer Biopathy (Volume II): The Orgone Energy Accumulator — Its Scientific and Medical Use, Orgone Institute Press, 1948 (reprinted Farrar, Straus and Giroux, 1973), Chapters VI–VIII. Construction specifications and measured atmospheric charge concentration in layered organic/inorganic systems.↩
4. International Energy Agency (IEA), Data Centres and Data Transmission Networks — Energy and Emissions 2023, IEA Technology Report, November 2023. Baseline energy intensity benchmarks for conventional cloud-dependent applications used for comparative reduction validation.↩
5. Wilhelm Reich, Cosmic Orgone Engineering: Reports on Atmospheric Orgone Energy and Weather Control Experiments, Orgone Institute Press, 1951–1954 (published as ORGONOMIC WEATHER REPORTS, Vol. I–IV). Documentation of measurable atmospheric potential gradients and their interaction with multi-layer dielectric accumulators.↩
6. Philip S. Callahan, Tuning in to Nature: Solar Energy, Infrared Radiation and the Insect Communication System, Devin-Adair Publishers, 1975 (reprinted Acres U.S.A., 2001), Chapters 4–6. Paramagnetic resonance in soil structures and atmospheric electricity harvesting via dielectric antennae.↩
7. Karl Schappeller, Unpublished Correspondence and Technical Diagrams on Spherical Primary-Energy Devices (Stirling Engine Variant), Austrian State Archives, 1930–1934. Referenced in modern reconstructions only; original luminous-core experiments remain classified.↩