Author's note for future readers: This is not a chapter and has no bearing on the rest of the story.
So this won't be a conventional chapter. I feel deeply that Momo's creation quirk is top three in the verse.
The thing is I understand why I think it's top three but I have problems expressing that Opinion properly.
It's a shame that she is quite a boring character for someone with such an amazing quirk.
Still for the sake of her quirk alone she unfortunately qualifies as a love interest.
I prefer Toga as a character but she seems like someone who would cheat and won't feel she had done anything wrong.
Anyway this chapter will be exploring my thought process behind why I think her quirk is the strongest and the possible avenues I'll be exploring.
________________________________________
So first up I think everyone knows what condenium is but for the sake of today's chapter me and my humble assistant the Arch-Strategist of the ether-net (ChatGpt actually but she chose the alias and it's really cool.) will be giving a breakdown.
In My Hero Academia: Two Heroes, Melissa Shield creates the Full Gauntlet using a fictional metal called Condenium. While the movie doesn't provide an in-depth scientific breakdown, here's what we do know from the canon and supplemental materials:
Properties of Condenium:Extreme Durability:
Condenium is strong enough to withstand the immense force generated by 100% of One For All, even repeatedly. This implies resistance to shock, compression, and kinetic impact on a superhuman scale.
Lightweight:
Despite its strength, the gauntlet is light and flexible enough for combat, meaning Condenium likely has a high strength-to-weight ratio—ideal for wearable tech.
Heat and Pressure Resistance:
It doesn't warp, crack, or overheat under the friction and pressure of Deku's attacks, implying thermal and structural stability.
Rare and Expensive:
Melissa emphasizes the limited quantity and how difficult it was to obtain, suggesting Condenium is rare, possibly synthetic or mined from a rare source, and difficult to work with or refine.
High Tech Compatibility:
It can interface with Melissa's support gear tech, showing it's conductive or adaptable enough for integration with sensors and advanced systems.
Summary:
Condenium is a high-tech, fictional alloy with superhuman-level strength, shock absorption, heat resistance, and lightness—tailor-made for enhancing or reinforcing Quirk usage, especially for powerful characters like Deku.
So if you all might recall I mentioned in an earlier chapter that Rio was to get a piece of Condenium ore as a gift from his grandmother. At least that clears that up.
You said:
If the atomic makeup for a fictional material like let's say Vibranium, adamantium or Condenium is known can they be replicated in the real world
ChatGPT said:
Great question—and one that touches on the boundary between science fiction and real-world materials science.
Short Answer:
If the atomic or molecular structure of a fictional material like Vibranium, Adamantium, or Condenium were fully known and feasible within the laws of physics and chemistry, then yes—in theory, they could be replicated.
But in reality, most fictional materials violate or stretch real-world science, making exact replication currently impossible.
Breaking it Down:1. If Atomic Makeup is Known AND Feasible:
If a material had a realistic atomic structure, say:
A stable arrangement of known elements (or plausible isotopes),
Or a new but physically possible crystal lattice, alloy, or nanostructure...
Then advanced labs could attempt to synthesize it—just like we do with carbon nanotubes, graphene, or high-entropy alloys. This is how real materials like aerogel, metallic glass, or Kevlar were created from theoretical predictions.
2. If It Involves Imaginary Physics (Like Vibranium):
Most fictional materials (like Vibranium absorbing vibrations or Condenium withstanding 100% One For All) require properties that:
Violate conservation of energy or entropy,
Don't conform to any known atomic bonding rules,
Or involve fantasy particles or unknown elements.
These can't be replicated unless:
We discover new laws of physics,
Or invent ultra-advanced nanoengineering techniques way beyond current capabilities.
3. Materials Science is Getting There:
Real-world materials are catching up with sci-fi. For example:
Carbon Nanotubes have insane tensile strength.
Graphene is 200x stronger than steel, yet one atom thick.
Aerogels can support thousands of times their weight.
Quasicrystals once thought impossible, are now real.
Conclusion:
If we had a realistic blueprint for a fictional material and it didn't break physics, we could try to make it.
But for things like Condenium, Vibranium, or Adamantium, which often rely on fantasy physics, they remain aspirational until science catches up—or invents new paradigms.
A/N: These are real world materials. These busted materials that seem Sci-fi are already feasible products. Now imagine the kind of stuff MHA has, set over a hundred years from our time.
So I also asked ChatGpt to create the metal for me using real world materials to craft something as close to the performance of Condenium in the anime.
ChatGPT said:
Excellent. Let's craft a realistic fictional version of Condenium—something that sounds plausible in-universe, feels scientifically grounded, and could feasibly exist in an advanced society like the one in My Hero Academia.
Material Profile: Condenium-X
(Advanced Combat Alloy for Quirk-Enhanced Wearables)
Origin:
Codenium-X is a composite nanolaminate alloy first developed by support engineers at Shiketsu Tech Institute in collaboration with American Hero Science Labs. It was created to withstand extreme kinetic energy discharges in Quirk-enhancement gear, particularly for users with high-output destructive quirks like One For All.
Composition:Base Matrix:
A nanoengineered titanium-boron-carbon carbide lattice (TiB₄-C₃N₄), chosen for its ultrahigh hardness and fracture resistance.
Nano-Reinforcements:
Embedded graphene nanotube bundles and amorphous metallic glass threads provide unmatched elasticity and thermal dispersion.
Reactive Layering:
Multi-phase piezoelectric polymers are woven into the structure. They dynamically redistribute force, reducing surface strain during impact—like adaptive shock absorbers.
Surface Coating:
Atom-thin layers of zirconium diboride (ZrB₂) for heat shielding and self-healing molecular patches for microfracture repair.
Properties:
Property
Performance
Tensile Strength
~4,500 MPa (comparable to advanced carbon composites)
Yield Strength
Exceptionally high due to amorphous reinforcement
Thermal Resistance
Stable up to 3,000°C (ideal for friction-based quirks)
Energy Absorption
Absorbs and disperses 98% of kinetic impact energy
Weight
~60% lighter than steel, ~30% lighter than titanium
Flexibility
High for a metal alloy due to polymeric components
Conductivity (for Tech Gear)
Tunable via embedded graphene matrices
Real-World Analogues:Graphene composites
Metallic glasses
Carbon-carbon fiber with ceramic armor layering
Self-healing polymers (still experimental)
A/N: So this is achievable through current technology but please it is highly unlikely anything of the sort would come out of a lab anytime soon.
You said:
If for instance there was a tool with atomic level precision. Could it create condenium-x
ChatGPT said:
Excellent follow-up—and yes, this is where science fiction edges into hard sci-fi territory. If you had a tool with atomic-level precision, then creating Condenium-X (or any advanced material) becomes theoretically possible. Here's how and why:
1. What Is Atomic-Level Precision?
Atomic-level precision refers to the ability to:
Place individual atoms or molecules exactly where you want them,
Control chemical bonds and lattice structure perfectly,
Create complex composites layer by layer, flaw-free.
This is the holy grail of molecular nanotechnology.
2. Could It Create Condenium-X?
Yes, and it would be the ideal tool for the job.
Condenium-X is described as a:
Nanolaminate alloy with a complex lattice,
Embedded with carbon nanotubes, metallic glass threads,
Laced with piezoelectric polymers and reactive surfaces.
A normal factory can't do that. But a molecular assembler—a tool that positions atoms like a 3D printer for molecules—could build it from scratch.
It would:
Align the graphene bundles perfectly,
Engineer void-free crystal phases,
Distribute nano-reinforcements exactly where needed,
Control the self-healing molecular patches at the surface.
3. Real-World Parallel:
Today, researchers already use scanning tunneling microscopes (STM) and atomic force microscopes to move single atoms, like arranging xenon atoms to spell IBM in 1989. That's the early ancestor of such tools.
4. Limitations Right Now:
Currently, we can:
Manipulate a few atoms,
Create simple nanostructures,
But not build complex macroscopic objects atom by atom—yet.
To create something like Condenium-X, you'd need:
High energy control,
Ultra-clean environments (no air molecules in the way),
Quantum-level material handling.
Conclusion:
If atomic precision tools exist in your universe, then yes—they could absolutely fabricate Condenium-X, and even more advanced materials. This opens the door to:
Ultra-rare hero gear,
Custom weapons forged on command,
Nanotech-enhanced prosthetics or implants.
You said:
If an atomic precision tool existed could it forge adamantium.
ChatGPT said:
Yes, if an atomic precision tool existed—and assuming the blueprint (atomic structure and bonding behavior) of adamantium is known—it could theoretically forge it.
Let's break it down with logic rooted in both science and speculative fiction:
1. What Is Adamantium?
In Marvel lore:
Adamantium is a virtually indestructible alloy.
Once hardened, it cannot be reshaped or destroyed.
Its exact composition is a secret, even in-universe.
It's usually described as a metallic compound formed from multiple rare and reactive elements under extreme conditions, and once set, its molecular structure becomes completely stable.
2. Atomic Precision Tool: What It Does
A true atomic assembler would:
Place every atom of every element in the exact spot needed,
Replicate the lattice structure and inter-atomic bonding that gives adamantium its properties,
Build the alloy from the ground up, layer by layer, without relying on traditional casting, forging, or chemical mixing.
So if you had:
The complete atomic diagram of adamantium,
A perfectly controlled environment (e.g., vacuum, high energy shielding),
Access to the required elemental feedstock (even exotic ones),
Then yes—you could forge adamantium.
3. Real-World Limits vs Sci-Fi:
Real-world materials like:
Metallic glasses, which have no crystal structure and are very tough,
Tungsten carbide or graphene composites, which approach sci-fi-level durability in certain ways,
still don't reach adamantium's mythical properties because:
They have defects, voids, impurities,
We can't yet place atoms exactly where we want, across a whole large object.
Atomic precision tools eliminate these flaws.
4. Important Sci-Fi Consequences
If someone could forge adamantium:
Weaponization: Blades, armor, bullets—nothing could withstand or block it.
Containment: It could be used for prison cells, safes, or vaults.
Medical tech: Bones, prosthetics—like Wolverine's skeleton.
Defense infrastructure: Reinforced bunkers or spacecraft.
This also raises ethics questions:
Who gets to control the process?
Could it be destroyed or recycled?
What happens if a villain gets a molecular forge?
TL;DR:
YES—with a precise atomic blueprint and enough raw materials, an atomic-precision tool could forge adamantium, or any fictional material whose structure is fully understood.
It would mark the end of conventional metallurgy and the beginning of a molecular age, where any material, no matter how complex, could be forged—atom by atom.
A/N: So you may wonder why I was being long winded with this, after all while this information may be interesting it doesn't actually involve Momo after all, right?
You said:
What is Momo Yaoyozuru's quirk in MHA
ChatGPT said:
Momo Yaoyorozu's quirk in My Hero Academia is called Creation.
Here's how it works:Creation allows Momo to create any non-living object from her body, using the lipids (fats) in her cells as raw material.
She needs to understand the object's molecular structure in detail before she can create it.
The object emerges from her skin—usually through an opening in her costume—and she can shape it in real time.
Key Limitations: She needs a clear mental blueprint of what she's creating (like knowing the chemical composition or inner mechanics).
The more complex or large the object, the more stamina and lipids it consumes.
She can't create organic matter, living beings, or anything magical or quirk-powered.
Strengths: Extremely versatile in both combat and support.
High intelligence and tactical planning make her a natural leader.
Can mass-produce tools, weapons, electronics, or even antidotes if she knows the formula.
You said:
since she needs to know the molecular structure of the objects to create them it implies that her quirk has molecular levels of control. Does she qualify as having atomic level precision?
ChatGPT said:
Yes—Momo Yaoyorozu's quirk implies atomic or at least molecular-level precision, even if it's not stated explicitly in the series.
Here's why she likely qualifies:1. She Creates Complex, Functional Objects Momo can create things like:
Flashbangs
Insulated wires
Tracking devices
Antidotes
Even circuitry
These all require the accurate arrangement of atoms and molecules to function properly—especially electronic components and chemical compounds. You can't make a working flashbang or a metal alloy rod by just eyeballing the macro shape. The chemical makeup has to be spot-on.
2. She Understands Molecular Structures
Her quirk doesn't auto-generate materials based on thought. She must study and memorize the exact molecular structure and chemical composition of what she wants to create.
This suggests her power can:
Arrange atoms into specific molecular bonds
Differentiate between isomers or compound variants
Handle chemical complexity (e.g., making a flashbang vs. making a metal rod)
That kind of control would require sub-microscopic accuracy, well below the cellular level.
3. Creation Appears to Skip Assembly
Unlike characters who build gadgets by hand (like Mei Hatsume), Momo doesn't assemble parts manually. The objects emerge whole and functional, with all their microscopic or nanoscopic detail already complete.
That means her quirk must:
Know where each atom goes,
Ensure chemical reactions don't go wrong mid-formation,
Build structures that don't collapse or explode from instability.
Which heavily implies atomic-level fabrication or close to it.
Conclusion:
Yes, Momo's quirk does qualify as atomic-level precision, even if it's framed through a biological lens (using her body's lipids as raw material). She's essentially a biological molecular 3D printer with:
Vast scientific knowledge
Real-time material synthesis
Near-perfect matter arrangement
Momo Yaoyorozu – "Creation"
Core strength:Limitless potential. The only constraints are:
Her scientific knowledge,
Her lipid reserves,
And current mental stamina under stress.
If you gave Momo:
Access to a molecular database,
Advanced chemistry, physics, and engineering knowledge,
Strategic leadership support (which she already naturally has),
She could:
Forge power armor, drugs, explosives, weapons in the field,
Create antidotes, food, water, fuel, tools, or comms equipment mid-battle,
Even reproduce rare elements or materials (like hypothetical ones such as condenium or adamantium, if she knows their structures).
If she ever gained the ability to create living tissue or manipulate matter beyond inorganic material, she'd easily move into god-tier territory in the MHA universe.
A/N: ARE YOU SEEING THE VISION! CAN YOU UNDERSTAND WHAT SHE'S TECHNICALLY CAPABLE OF!
What Is the major challenge stoping humanity from achieving controllable nuclear fusion
ChatGPT said:
The major challenge stopping humanity from achieving controllable nuclear fusion lies in sustaining a net-positive energy output—that is, producing more energy than is consumed in starting and maintaining the fusion reaction. The key hurdles include:
1. Extreme Conditions Required
Fusion needs conditions similar to the core of the Sun:
Temperatures over 100 million°C to overcome the electrostatic repulsion between positively charged nuclei.
Very high pressure or density to increase collision chances.
Creating and maintaining these conditions on Earth is incredibly difficult and energy-intensive.
2. Plasma Containment
At such temperatures, matter exists as plasma, a hot, electrically charged gas that can't touch the reactor walls (or it would cool down and damage the reactor).
The current method: Magnetic confinement, using strong magnetic fields (like in tokamaks such as ITER).
Challenge: Plasma is unstable. It can twist, ripple, or escape the magnetic field—causing disruptions or even reactor shutdowns.
3. Energy Input vs Output
Most fusion reactors still require more energy to sustain the reaction than they produce. Getting a net energy gain (Q > 1) for long durations is the holy grail.
Recent advances (like at the U.S. National Ignition Facility) have briefly hit or exceeded Q = 1, but only in very short bursts and not in a continuous, practical way.
4. Material Limitations
Fusion reactions bombard reactor walls with neutrons that can weaken or degrade materials.
We need ultra-durable, heat- and radiation-resistant materials for inner reactor components.
These materials must also minimize radioactive waste.
5. Fuel Supply & Handling
Fusion uses isotopes like deuterium (abundant in seawater) and tritium (rare and radioactive).
Tritium is expensive and scarce.
Breeding and recycling it safely and economically remains a challenge.
6. Engineering & Economic Complexity
Building a fusion reactor is a technical and financial mega-project, requiring:
Massive precision infrastructure
International cooperation (like ITER)
Decades of research and funding before becoming commercially viable
Summary
We know fusion works. The challenge is making it safe, stable, continuous, and cost-effective. Advances in superconductor magnets, plasma physics, and material science are pushing us closer—but we're still likely decades away from practical fusion power on the grid.
Would you like a breakdown of promising technologies like tokamaks, stellarators, or laser fusion next?
4o
You said:If there were a material capable of meeting all the above mentioned conditions. Would nuclear fusion be feasible immediatelyChatGPT said:
Great question — and you're thinking in exactly the right direction.
If there were a hypothetical material that could meet all the physical and engineering challenges of nuclear fusion, then yes, fusion would become far more feasible — possibly even immediately or within a very short development cycle. Here's how such a material would change the game:
1. Surviving Extreme Heat & Radiation
A material that could:
Withstand temperatures above 100 million °C
Resist neutron bombardment and radiation damage
Not degrade or become brittle over time
…would allow engineers to build reactor walls and inner components that don't need frequent replacement, improving longevity, safety, and efficiency.
2. Perfect Plasma Containment
If this material could also help:
Create stronger and more stable magnetic fields
Or allow for direct containment of plasma without energy losses
…it could revolutionize magnetic confinement (like in tokamaks or stellarators), eliminating instabilities and energy leakage that currently plague reactor designs.
3. Energy Efficiency
Assuming the material reduces energy losses and enhances insulation:
More of the fusion energy output could be captured
Less input energy would be required to maintain conditions
That means achieving a net-positive energy output (Q > 1) consistently and economically.
4. Tritium Breeding & Fuel Handling
If this material:
Allowed efficient breeding and containment of tritium
Was chemically inert or self-healing
Could store or interact with fuel isotopes safely
…it would solve major hurdles around fuel scarcity, safety, and handling.
5. Reactor Miniaturization
Such a material might enable smaller, cheaper fusion reactors, eliminating the need for massive infrastructure like ITER. That would drastically speed up global adoption.
Conclusion
If a material like this existed, commercial nuclear fusion would likely become feasible very quickly. The major remaining barriers would be:
Scaling up the technology for energy grids
Regulatory approval
Mass-producing the material itself
In essence: materials science is the bottleneck. Fusion isn't impossible — it's just bound by the limits of what we can build and what can survive the conditions inside a star.
You said:If I had an atomic assembler. Could you design a material that could meet those requirements.
ChatGPT said:
If you had access to a true atomic assembler — a device capable of placing atoms with absolute precision to form any structure — then yes, we could design a theoretical material that meets or even exceeds the extreme requirements of nuclear fusion reactors.
Here's how we'd go about it and what kind of material might emerge:
1. What We'd Need the Material to Do
To support fusion reactors, the material must:
Withstand temperatures >100 million °C (theoretically on the inner walls of the reactor).
Be immune to neutron degradation (neutrons from fusion reactions damage atomic lattices).
Be magnetically and electrically optimized (for magnetic field generation or shielding).
Be thermally insulating but structurally sound.
Be chemically inert or self-healing under radiation bombardment.
2. What Could the Atomic Assembler Build?
With atomic precision, we're no longer limited by nature. You could design meta-structured materials—materials engineered down to their atomic lattice for specific properties.
Candidate: Hypercarbon-Tungsten Meta-Lattice (HTML)
A composite atomic structure combining:
Tungsten atoms (high melting point, neutron resistant)
Graphene-based carbon layers (extreme strength, flexibility, thermal conductivity)
Boron-carbide segments (radiation absorption, hardness)
Self-repairing molecular nodes (atoms or molecules that can re-bind when lattice damage occurs)
Embedded rare earth elements or superconductors for magnetic stabilization
With atomic-level control, you could arrange these in alternating 2D and 3D structures:
Outer shell: boron-carbide-carbon weave for radiation resistance
Core layers: diamond/graphene hybrid channels for heat dissipation
Structural mesh: tungsten and osmium frame for extreme stress and pressure
Add optional features:
Smart layers with embedded sensors or memory material
Fusion fuel traps or breeders within atomic gaps (like lithium-6 islands for tritium production)
3. What Makes It Possible
No grain boundaries = no weak points for neutron cracking
No chemical imperfections = higher resistance to corrosion or thermal stress
Custom bonding = exotic bonds (e.g. tetrahedral carbon-lattice with metallic inclusions) allow it to behave in unique ways
4. Could It Work in Practice?
If your assembler were:
Fully programmable
Able to build in 3D space at atomic scale
Able to handle large-scale assembly
Then yes — this material would, at least on paper, be perfect for use in fusion reactors. It could enable compact, efficient, and safe reactors far beyond today's capabilities.
You said:
So Yaoyozuru Momo could technically create this material?
ChatGPT said:
Yes — technically, Momo Yaoyorozu could create this material, if the following conditions are met:
1. She Knows the Full Atomic Structure
Her quirk, Creation, allows her to make any non-living material as long as she understands its molecular structure. If she had:
A complete atomic blueprint of the fusion-grade meta-material (like the one we discussed),
A deep understanding of atomic bonding, lattice orientation, and composite layering,
Then, in theory, her body could synthesize the material atom by atom.
2. She Has Enough Biomass
Creating exotic materials from scratch would require a huge amount of energy and raw material, which her body metabolizes from food:
The denser or more exotic the material, the more calories she'd need.
A single high-performance fusion panel might take tens of thousands of kilocalories.
This limits how much she could make at once without serious preparation or assistance (like support equipment or metabolite boosters).
3. Her Mental Processing Can Handle Atomic Precision
While her quirk gives her molecular-level control, atomic-level control is a step higher:
To precisely arrange atoms into a programmable metamaterial like the one described, she'd need either:
A genius-level understanding of atomic physics and material science (plausible with time, tutoring, and study), or
A quantum-AI assistant or specialized support gear that helps her visualize and structure the compound atom-by-atom in real time.
Conclusion:
Yes, she absolutely could—with enough knowledge, calories, and training.
In fanfic terms, this makes her insanely broken. She's basically a walking atomic assembler once properly trained. Give her a year at a lab under someone like Mei Hatsume, Power Loader, or David Shield, and she could be building next-generation reactors or planetary defense weapons solo.
You said:What kind of structure do you think adamantium would have to make it indestructible?
ChatGPT said:
To make adamantium truly indestructible in a scientifically plausible way, it would need a structure that pushes the limits of material science, quantum mechanics, and atomic bonding. Here's a breakdown of what its structure might look like from a real-world physics perspective:
🔬 1. Perfect Atomic Lattice (No Defects)
Most real materials fail due to microscopic flaws: cracks, grain boundaries, or dislocations in the atomic lattice. Adamantium would have:
A perfectly ordered atomic structure, possibly single-crystal across any scale.
No grain boundaries, meaning it's uniform at the atomic level—no weak points.
This alone would already make it stronger than any steel or ceramic on Earth.
💠 2. Covalent Hyperbonding
The atoms in adamantium would likely be bonded by extremely strong covalent bonds:
Similar to diamond, which uses tetrahedral carbon-carbon bonds, but far denser and more multidimensional.
These bonds could form a 3D polymeric lattice with overlapping electrons — a structure that resists shearing, compression, and tension.
It could even use delocalized pi bonding (like graphene) to enhance flexibility and electron sharing across the structure.
🧬 3. Self-Reinforcing Nanostructures
Adamantium might consist of:
Interwoven carbon nanotubes or boron-nitride nanotube frameworks, which have massive tensile strength.
These tubes could be embedded in a meta-stable matrix that shifts atomic positions under stress, dissipating force without cracking.
Think of it as having flexibility at the nanoscale, but rigidity macroscopically.
🧊 4. Exotic Quantum-Level Stabilization
To be truly indestructible, you'd need to stabilize the structure against:
Heat, pressure, and nuclear radiation.
This might involve:
Zero-point energy fields locking atoms in place.
Exotic matter interactions, like topological phases that resist energy input.
Or even quantum entanglement to distribute force instantaneously across the material, preventing localized stress failure.
🔐 5. Non-Newtonian Phase Adaptability
Adamantium might be:
Liquid or moldable at a specific temperature or frequency, and
Perfectly solid and immutable afterward (like it is in Marvel canon: cast once, then immutable).
This implies it may exist in a meta-stable phase — not its lowest energy form, but locked there by an immense activation barrier. You'd need phenomenal energy to even alter it once it's solid.
🧠 Summary
For adamantium to be indestructible:
Feature Real-world Analogue Perfect
Perfect lattice Single-crystal diamond
Covalent hyperbonding Diamond, graphene
Nanotube reinforcement Carbon/boron nanotubes
Quantum stabilization Topological insulators, exotic matter
Indestructible phase Metastable alloys, memory materials
Final Author's note: My main gripe was that I researched this in like an hour max, with a glorified chatbot like ChatGpt. Imagine what she could achieve with the resources, money and connections she has. Mainly this was a rant that shouldn't in anyway qualify as a chapter but I'm still writing the outline for volume two and I don't want to skip posting today so here's this instead of the chapter. We'll get a normal chapter on tuesday though.