The archive's passive thermal systems have been independently validated by government engineers, practicing architects, and academic historians. The physics works. The buildings last. The economics pencil out in arid climates. Yet passive thermal systems remain a marginal practice — not a building industry standard. Why?
This page collects the explanations that appear across the wiki and identifies what remains unresolved.
In his AIA slideshow, Baer frames passive solar interest as recurring epidemics that fossil fuel industries work to suppress:
"Those who sell gas, electricity, propane and oil may regard these periods of self reliance and clever designs as epidemics which weaken the demand for their power and fuels which they must combat to re-establish healthy fossil fuel appetites."
This is the demand-destruction theory: passive systems reduce energy purchases, so the entities with market power have a structural incentive to discourage them. Baer sees the pattern repeat — 1940s, 1970s, 2000s — each wave cresting and receding.
The radiant cooling design brief identifies specific market barriers:
These are not objections to the physics — they are objections to change.
Bruce W. Davis makes the anti-Passivhaus argument: European passive-house standards push technological complexity (heat-recovery ventilators, airtight membranes, monitoring systems) that becomes obsolete within years. The simpler passive approach — thermal mass, water, orientation, sky view — has no certification industry, no product catalog, and no trade lobby. It is too simple to sell.
A Golden Thread: 2500 Years of Solar Architecture and Technology (Butti & Perlin, Cheshire Books, 1980) is the academic standard history of solar energy. Its 289 pages cover ancient Greek solar orientation, 19th century solar motors, the MIT solar house program (1939–1962), and the 1970s revival. Steve Baer, Harold Hay, Harry Thomason, and night-sky radiative cooling are absent.
Hay's Atascadero house (1973) and Baer's Drop City air loop (1967–68) were both within scope. Neither appears. The book was published the same year as Super Solar Houses (Shurcliff) — the counterculture passive solar movement was active but the academic history writers didn't include it. The only New Mexico passive solar reference is Bridgers & Paxton's 1956 Albuquerque office building — the conventional engineering tradition, not the Baer/Hay/Thomason creative activist tradition.
This is the historiographical gap: the mainstream narrative of solar energy history was written without the counterculture innovators, ensuring that later researchers looking to solar history for precedents would not find Baer's approach there either.
The US Air Force Passive Solar Handbook (Architectural Energy Corp., c.1985) is a 5-volume engineering guide for integrating passive solar into USAF facilities worldwide. Its passive cooling section covers exactly two strategies: Natural Ventilation (NVN) and Night Mechanical Ventilation (NMV) — both air-based. The handbook contains no mention of roof ponds, Skytherm, night-sky radiative cooling, or Zomeworks. Hay's Skytherm had existed for 12–18 years by the time this handbook was published; Baer's battery cabinet work was already generating revenue.
This is a concrete example of how the institutional definition of "passive cooling" was established without including the water-based night-sky approach. A USAF facility planner following this handbook would have no knowledge that a radically different passive cooling technology existed. The handbook reached engineers across hundreds of USAF bases worldwide.
The independent validation synthesis identifies the deepest structural problem: passive thermal systems eliminate ongoing energy purchases. A house that heats and cools itself does not generate utility bills, maintenance contracts, or equipment replacement cycles. The entities capable of deploying building technology at scale — utilities, HVAC manufacturers, large builders — have no business model for a system that works indefinitely with no consumables.
Sunmen argues that most people have never looked at a building with an infrared camera, never measured a surface temperature, never felt the difference between radiant and convective comfort. The thermal world is invisible to most decision-makers. You cannot demand what you have never experienced.
The archive's explanations are plausible but incomplete. Several questions remain open:
| Question | Why it matters |
|---|---|
| Is the cost competitive today? | The NSRC report (2006) showed 25–89% power savings, but did not model installed system costs against modern heat pumps. A 2026 cost comparison is missing. |
| Does the container prototype change the equation? | The Zomeworks container prototype suggests a modular, mass-producible platform. If passive thermal can be shipped as a product (not a custom build), the builder-familiarity barrier shrinks. |
| Could a demonstration neighborhood work? | Baer showed individual buildings. Chalom modeled individual homes. No one has demonstrated a neighborhood or campus where passive thermal is the default — creating the familiarity that the design brief says is missing. |
| Is the Solar Fools network a path to scale? | Davis, Baer, and their collaborators form a network of practitioners. Could this network produce a replicable design standard rather than one-off projects? |
| What would a passive thermal business model look like? | If recurring revenue from energy sales is the blocker, what alternative business model could fund deployment? Performance contracts? Thermal-as-a-service? Land development with integrated thermal? |
Open. The archive documents the problem thoroughly but does not resolve it. The container prototype (2026) is the most recent evidence that someone is still trying.