Myriad Heavens: Rise of the Rune God-Chapter 106: Verification

POV: DR. SOFIA MARTINEZ - MATERIALS LAB - 3:15 PM

Sofia stood in front of the molecular beam epitaxy chamber with her team of six materials scientists.

"We’re skipping the virtual simulation," she said. "The boss already ran this through that software. The theory is solid. We’re here to prove it works in real life."

She loaded the thermoelectric material procedures into their manufacturing system.

David pulled up the AI assistant. "Dr. Martinez, the procedures are incredibly detailed. Every step is specified down to exact atomic measurements."

"Good. That means less room for mistakes. Let’s follow it exactly."

The MBE chamber hummed to life. Source materials loaded into containers—bismuth, tellurium, antimony, cobalt, nickel. All precisely measured.

"Chamber at proper vacuum," David reported. "Temperature stable at 450°C."

"Beginning deposition," Sofia said.

She watched the monitors. Atomic flow rates. Layer thickness. Crystal alignment. The superlattice building atom by atom—layers just fifteen atoms thick, repeated over and over.

Three hours later, they had a sample. A small wafer, maybe five centimeters across, with the complex layered structure built into its crystal.

"Electrical testing," Sofia said.

They connected the sample to their measurement equipment. Applied temperature difference—one side heated to 2000°C, one side cooled to 50°C.

Voltage appeared immediately.

"Current flowing," David said. "Running calculations... conductivity is 10,300 S/m. Thermal conductivity 0.51 W/mK. Seebeck coefficient 468 microvolts per Kelvin."

Sofia did the math in her head. "Total conversion efficiency?"

"90.4%."

The lab went completely silent.

"The data was correct," Sofia whispered. "He actually did it. Room temperature thermoelectric material with 90% efficiency."

To put that in perspective, current thermoelectric materials barely hit 15% efficiency. This was six times better. If you put this material in a phone, the heat from the processor would convert directly to electricity. Your phone would never get hot. The battery would last weeks instead of days. Same for laptops, servers, any electronic device.

For power plants, it meant you could skip the entire steam turbine system. Just convert heat directly to electricity with almost no waste.

"But how?" one of the junior researchers asked. "How did he figure out this exact composition? This layering structure? There are millions of possible combinations."

"The simulation software," David said quietly. "He must be incredibly smart. The software provides the tools, but you still need to know what to test. What might work. He directed the AI to find this specific solution."

Sofia nodded. The software was powerful, but it needed direction. Orion had given it the right direction.

"Run the superconductor fabrication," Sofia said. "Let’s see if he’s right about that too."

POV: DR. JAMES KOWALSKI - LASER SYSTEMS LAB - 4:30 PM

James held the synthesized gain crystal carefully. It was beautiful—perfectly clear with subtle rainbow colors indicating the rare-earth layers inside.

"According to the specs, this crystal should amplify a kilowatt input laser to 200 megajoules output," James said to his assistant, Dr. Nina Patel.

"That’s 200,000 times amplification," Nina said. "If this works, it’ll change laser technology forever."

They set up the experiment. Standard kilowatt laser aimed at the crystal. The crystal had been pumped with electrical energy—ready to amplify.

"Firing in three... two... one..."

The laser pulsed. One kilowatt of input power hit the crystal.

Light cascaded through the crystal structure. Each photon triggering more photons. Energy multiplying as the light beam passed through.

The output was blindingly bright even through safety filters.

"Power output?" James asked, not daring to believe the instruments.

Nina checked three times. "198 megajoules. The amplification is real. A few kilowatts in, hundreds of megajoules out."

James sat down heavily. "This changes everything. Fusion ignition, industrial cutting, materials processing... this one crystal design opens up entire industries."

Think about it—current high-power lasers needed massive power supplies and cooling systems. They were room-sized machines. This crystal meant you could get the same power from a device the size of a briefcase. Handheld laser cutters that could slice through steel. Portable medical equipment. Compact fusion igniters.

"Who thinks of this?" Nina asked. "How does someone so young have this level of knowledge?"

"Genius," James said simply. "Pure genius plus incredible computational tools. The software let him test millions of crystal designs. His brain told him which ones to actually try."

POV: DR. AMARA OKAFOR - FUSION LAB - 5:45 PM

Amara watched the superconductor test with tears in her eyes.

The magnetic field strength was climbing. 50 Tesla. 100 Tesla. 150 Tesla.

"Still superconductive," her assistant announced. "No breakdown. Temperature holding at 22°C."

170 Tesla. 200 Tesla. 250 Tesla. 300 Tesla.

The field strength peaked at 300 Tesla.

The superconductor held. Room temperature. No cooling needed. Completely stable.

"It works," Amara whispered. "It actually works."

To understand how incredible this was—current superconductors needed to be cooled to -196°C with liquid nitrogen. That required massive, expensive cooling systems that used tons of energy. And even with all that cooling, they could only hit about 20-30 Tesla.

This material worked at room temperature and produced ten times stronger magnetic fields.

For fusion reactors, that meant you could squeeze the plasma way tighter. More fusion reactions. More energy output. Smaller reactor size.

For other applications? Magnetic levitation trains wouldn’t need cooling systems. MRI machines would be smaller and cheaper. Electric motors would be perfectly efficient. Power transmission lines would have zero energy loss.

Her team was assembled around her—fusion physicists, engineers, plasma specialists. They’d dedicated their careers to achieving practical fusion. They’d watched project after project fail. Watched budgets run out. Watched timelines extend from years to decades.

And now, a twenty-one-year-old had handed them the missing pieces.

"The thermoelectric material is verified," Amara said, reading the reports from Sofia’s team. "90% efficiency. The superconductors work—300 Tesla at room temperature. The laser ignition system produces the necessary energy with minimal input."

She pulled up the preliminary fusion reactor design Orion had mentioned.

Eight meters across. Compact. Efficient. Actually buildable.

"We’re going to do it," she said to her team. "We’re actually going to achieve commercial fusion. In our lifetimes. In our lab."

One of the engineers, Marcus Webb, was crying openly. "I’ve worked on fusion for thirty years. Thirty years of ’ten more years and we’ll have it.’ And now..."

"Now we have it," Amara finished. "Because someone gave us the right tools and the right knowledge."

CONFERENCE ROOM A - 6:30 PM

Orion sat at the conference table while team leads presented their results.

Dr. Sofia Martinez went first. "Thermoelectric material verified. 90.4% efficiency, exactly as predicted. Room-temperature superconductor also verified—300 Tesla field strength, stable at 22°C. Both materials can be manufactured with our existing equipment."

Dr. James Kowalski next. "Laser gain crystal verified. 200,000 times amplification. Input of 3.2 kilowatts produces 198 megajoule output. System is ready for fusion ignition."

Dr. Michael Torres from battery research. "Solid-state batteries verified. 2,430 watt-hours per kilogram, 100,000+ charge cycles with almost no degradation. Non-flammable, thermally stable. Ready for production."

For context—current phone batteries were about 250 watt-hours per kilogram and lasted maybe 500-1000 charge cycles. These new batteries had ten times the energy density and lasted 100 times longer. A phone with this battery could run for a month on a single charge and last twenty years before needing replacement.

Dr. Amara Okafor, barely containing her excitement. "All fusion components verified. Magnetic containment achievable with the new superconductors. Plasma heating achievable with the laser system. Power conversion achievable with the thermoelectric materials. Mr. Starr... we can build this reactor. We can achieve commercial fusion."

Her voice broke on the last word.

Orion smiled. "Then let’s build it."

He stood and connected his tablet to the main display. Again, nobody saw him do anything—the connection just happened. More puzzled glances around the room.

"I’m sending the complete reactor design to your tablets now. Modular construction blueprints, assembly procedures, manufacturing specs, safety protocols, testing procedures—everything you need."

Files began appearing on everyone’s tablets.

The design was comprehensive. Six modular sections that could be built separately and assembled on-site. Detailed 3D models showing every component. Manufacturing procedures optimized for their existing equipment. Assembly sequences with exact measurements. Quality control checkpoints. Safety systems. Monitoring equipment.

"The reactor sections are divided by specialty," Orion continued. "Materials team handles the thermoelectric blanket and superconductor components. Laser team builds the ignition systems. Battery team constructs the energy storage. Fusion team manages the plasma chamber and magnetic containment. Manufacturing team coordinates production and assembly."

He pulled up a timeline.

"We start production immediately. Component manufacturing happens parallel across all teams. Assembly begins in four months. Testing and fine-tuning in month five. Full power operation in month six."

"Six months?" Amara said. "We can have a working fusion reactor in six months?"

"Yes. We have the technology. We have the expertise. We have the facility. We have unlimited funding. No more waiting. No more delays. We build it now."

The room was silent for a moment.

Then Amara started clapping.

Others joined. Soon the entire room was applauding.

Orion waited for it to die down. "One more thing. This reactor will produce 3,000 megawatts continuous. Enough to power two major cities. Fuel requirement is 50 grams of deuterium per day. One kilogram lasts twenty days."

To put that in perspective, a typical coal plant needed thousands of tons of coal per day. This needed 50 grams of deuterium—a amount that would fit in a shot glass.

"For smaller reactors, we can scale down to pot-sized units requiring less than a gram per year," Orion continued.

"Pot-sized?" Sofia said. "You mean—"

"I mean distributed fusion power. Every neighborhood gets its own reactor. Remote locations don’t need power grids. Developing regions skip traditional infrastructure entirely. Clean, unlimited energy everywhere."

A pot-sized reactor that could power 1000 homes from less than a gram of fuel per year. That would fit in your kitchen. No power lines needed. No utility bills. No pollution. Just clean energy forever.

He looked around the room.

"This is the beginning. In six months, we prove it works. In a year, we’re manufacturing commercial units. In five years, fossil fuels are obsolete. Coal plants shut down. Oil becomes worthless. Gas becomes unnecessary. You’re all part of the team that changes everything."

Orion disconnected his tablet. "Review the designs tonight. Coordinate with your teams. We start manufacturing tomorrow morning. Welcome to Innovatia Advanced Research Division. Let’s build the future."

He walked out, leaving the researchers staring at blueprints for technology that would reshape civilization.

Sofia looked at David. "We’re really doing this."

"We’re really doing this," he confirmed.

Amara was already on her phone, calling team members who weren’t at the meeting. "Get back to the lab. Now. We’re building a fusion reactor. A real one. Yes, I’m serious. No, I haven’t lost my mind. Just get here."

Across the room, researchers were examining different sections of the design. Running preliminary calculations. Planning manufacturing workflows.

Marcus Webb was still crying. "Thirty years. Thirty years of waiting. And it’s finally happening."

"Not just happening," another fusion engineer said. "It’s happening in six months. Six months and we change the world."

The future had arrived.

And it was being built in their lab.