I was discussing cement technologies with AI and I discovered a cement which was underutilized by the industry. I uncovered the potential of this cement by developing new processes for construction that change everything. Just combine 25% Magnesium Oxide (MgO) and 75% Monopotassium Phosphate (KH₂PO₄) with enough water to turn the powder into a thick fluid paste. You get the revolutionary cement in your hands: Magnesium Potassium Phosphate Cement (MKPC).
The superior characteristics of this cement allow it to be an all-in-one solution for construction. This also allows most of the construction materials to be manufactured on-site. MKPC is at least three times stronger than Portland cement and cures very fast, even in cold weather. I highlight these features in my architecture. In order to increase the strength of the cement matrix even further, I propose the use of fine glass dust as the primary cement aggregate.
When MKPC and glass dust are mixed with water to form a paste, it can be poured into molds. For the insulation blocks, sodium carbonate is added before the mix solidifies. The carbonate reacts with the acid component inside the mix to generate carbon dioxide gas bubbles, which are trapped inside the thick paste. The fine glass dust acts as a micro-structural stabilizer to keep the closed-cell bubbles confined and uniform. The result is an ultra-lightweight aerated concrete manufactured on-site in minutes, without the need for high-pressure steam autoclaves. These carbonated foam bricks are significantly stronger than traditional Portland-cement-based Autoclaved Aerated Concrete (AAC). As a result, they can be made thinner while maintaining high structural form and crushing resistance. These foam bricks will have multiple roles in the construction of the building.
The structural concrete columns require molds. I am planning to manufacture these molds as permanent, interlocking closed ring forms made of these very same carbonated foam bricks. Because these stay-in-place molds are made of the same base phosphate material as the dense concrete core poured inside them, the fresh acid matrix slightly etches the inner walls and allows the crystals to grow directly into each other. They chemically weld to form a single, solid monolithic block. The molding process is radically sped up, and the temporary mold removal phase is totally eliminated.
As a rebar alternative for the concrete, I propose continuous glass fibers strengthened by a glass-dust-infused MKPC slurry. The ultra-fine glass dust acts as a micro-wedge, packing tightly into the geometric gaps between the internal fiber filaments to eliminate structural voids and increase the modulus of elasticity. The rebars are co-extruded as a dense paste from a containerized extruder and immediately formed into structural shapes by automated bender mechanisms. The fast exothermic setting of the cement allows the preformed rebar shapes to be handled in minutes on-site. These preformed shapes are then combined and bonded using the cement itself. These rebars are vastly more durable than traditional carbon steel, which requires constant protection against humidity and alkalinity. My composite rebar, on the other hand, is entirely immune to corrosion. As a result, the concrete cover layer outside the rebar can be made much thinner, drastically reducing the overall size of the columns and the dead weight of the floor slabs.
The inner and outer walls of the building will be made of these carbonated foam bricks, cast directly on-site. The molds will be prepared before casting to include built-in channels for wiring and piping. As a result, after they are dry-stacked, there will be minimal secondary trenching work needed on them. These bricks will be cast with one side facing a smooth PTFE (Teflon) mold surface, turning that specific face into a perfectly glossy finish. Depending on the room layout, these PTFE surfaces can be coated with specialized mineral paint pigments prior to casting. The pigments fuse directly into the setting phosphate-glass matrix, giving it a permanent, ceramic-like glossy glaze. The high loading of internal glass dust enhances this vitrified aesthetic. This allows the brick walls of the bathroom and the kitchen to have native, tile-like surfaces, completely negating the need for secondary wall tiling. Furthermore, the entire floor of the building can be covered with these pigmented foam bricks to double as the finished flooring. These blocks possess excellent thermal and acoustic insulation; additionally, they are waterproof and do not allow mold to propagate. The exterior envelope of the building will also be covered with these glossy, weather-resistant foam bricks.
The bricks, the structural cores, and the walls are all derived from the same base cement chemistry, meaning they are glued to each other with the very same phosphate binder. This guarantees a perfect thermal expansion match and allows zero water leakage between separate architectural sections. Unlike traditional construction where tile glues degrade and fail over time, this design is engineered to last centuries. The hard and durable cement creates micro-fine joints between the precisely cast bricks, allowing minimal gaps. These gaps are later filled and grouted with the same liquid cement they are made of, resulting in perfectly smooth, continuous surfaces unseen with traditional ceramic grouts. The walls of the building achieve a perfect 90-degree alignment through interlocking geometry, without requiring expert bricklayers.
Finally, I plan to manufacture the internal plumbing and piping of the building on-site as well. A continuous glass fiber closed mesh sleeve, thoroughly saturated by the fluid MKPC matrix, will be extruded to form high-pressure pipes. Due to the glossy, non-porous crystalline finish formed inside the piping walls, there will be no organic bio-films or mineral scaling building up inside. More importantly, the toxic microplastics commonly associated with traditional PVC piping are completely eliminated from the water supply.
