Summary: "Set after the events of Deadlock, the crew of Voyager pushes the boundaries of Starfleet science to secure their survival in the Delta Quadrant. With B'Elanna Torres spearheading ground-breaking innovations, they face new opportunities and unforeseen challenges, navigating uncharted dangers while holding to Federation principles."
Chief Engineer Log: Lt. B’Elanna Torres
Stardate 49555.7
“It’s been a week since Voyager endured the worst of the spatial scission anomaly. Two versions of the ship, occupying the same space, straining every system to the breaking point and nearly draining our antimatter. And then the Vidiians attacked. We lost an entire duplicate crew—people who were us, down to the last molecule—and yet, it’s the strangest feeling. Harry Kim and Naomi Wildman survived, but they’re not quite the same Harry and Naomi we started with. Or maybe they are? I can’t help but feel the loss, even if logically, they’re still here. I’ve never been good at untangling emotions, and this... well, it’s a lot to process.
“Repairs have been overwhelming. The hull breach spanning Decks 14 and 15 was the worst—open to space, half the bulkheads buckling under stress. I can still see Harry helplessly being forced out into space when the breach widened. Maybe I can pay him a brief visit for reassurance. Carey and Vorik took charge of the structural integrity teams, and Nicoletti worked miracles with the power distribution systems and force field generators. The antimatter injectors needed manual attention; I spent hours crawling through Jeffries tubes just to stabilize them. It’s not perfect, but it’ll hold—for now.
“But holding isn’t enough. Our antimatter reserves are critically low—below twenty percent—and there’s no guarantee we’ll find more anytime soon. We’ve pushed the warp core efficiency to its limits, and it’s clear we can’t rely on conventional means much longer. During repairs, my mind kept wandering back to the Dreadnought and its Quantum Torpedoes. At first I couldn’t understand WHY, and then it hit me. Zero Point Energy. They use ZPE principles to enhance their explosive yield. What if I could tap into that somehow? The obstacles seem huge from a research point of view, but I think I found a way around that problem. To even begin testing it, I need access to Starfleet’s classified research on Zero Point Energy—materials and principles that could bridge the gap to make an actual energy source. I’ll have to take it to the Captain and see if she’s willing to trust me with this leap without revealing too much. Can’t get hers or the crew’s hopes up.”
Ready Room – Seeking Clearance
Captain Janeway leans back in her chair, savouring a rare moment of calm after the brutal fight to restore Voyager from the recent spatial scission anomaly. Her crew has endured exhausting repairs and tense moments, but Janeway feels an undercurrent of resilience that reassures her they’ll bounce back stronger than ever. The chime of the door interrupts her thoughts.
Janeway: “Come in.”
The doors slide open, and Lieutenant B’Elanna Torres enters, her expression focused and slightly reserved, with a spark of excitement she’s trying to keep in check.
Janeway: [gesturing to a seat] “B’Elanna. How are repairs coming along?”
Torres hands Janeway a PADD, nodding as she does.
Torres: “There are no more signs of microfractures on the hull, and we’ve fully sealed the breach along Decks 14 and 15, Captain.”
Janeway skims the PADD, nodding with satisfaction.
Janeway: “Good work. Those decks took quite a beating. Any concerns with structural integrity?”
Torres: “None, Captain. Reinforcement checks are showing all sections are back to optimal stability. The hull’s holding steady, and we can start letting people back onto those decks.”
Janeway nods approvingly, but then Torres continues, her tone shifting slightly.
Torres: “There’s another matter, though. With our antimatter reserves as low as they are, it’s becoming clear we’ll need alternative solutions if we’re going to sustain ourselves out here for the long haul.”
Janeway’s expression tightens, aware of the reality their low reserves imply.
Janeway: “A grim reality indeed. But I sense there’s something specific you’re getting at.” [she eyes Torres with a blend of curiosity and authority] “What’s on your mind?”
Torres hesitates, as if weighing how much to reveal.
Torres: “I have an idea… a theory. It’s early, and I wouldn’t want to raise expectations just yet. But to explore it, I need access to Starfleet’s classified data on quantum torpedoes. The developmental files, specifically.”
Janeway leans back, studying Torres carefully. Her tone turns slightly more probing.
Janeway: “B’Elanna, that’s high-level information—classified for a reason. Why would developmental data on quantum weapons have anything to do with our energy concerns?”
Torres’s eyes flicker with restrained determination.
Torres: “Captain, I’m already familiar with quantum torpedoes from my time in the Maquis, especially after working on the Dreadnought missile back in the Alpha Quadrant. I know their structure and general capabilities, but there are energy dynamics involved in their design that go beyond standard Starfleet propulsion or power systems. To test my idea, I need that knowledge.”
Janeway: [pressing gently] “If this is about alternative power sources, you should know that I need more than vague assurances to justify giving you access to classified files. We’re talking about a risk—to Voyager and to you. Can you give me something more specific?”
Torres takes a deep breath, visibly weighing her response.
Torres: “Captain, all I can say right now is that this might help us address our antimatter shortage more… sustainably. But I can’t guarantee results yet, and I’d rather not give the crew or you false hope. I just need to make sure it’s even feasible before I say more.”
Janeway regards Torres with a blend of caution and respect. She knows her chief engineer wouldn’t ask without reason, but she also recognizes the potential risks.
Janeway: “You don’t ask for something like this lightly, do you?” [a beat, then a nod of resolution] “Alright, B’Elanna. I’ll grant you provisional access—but I expect regular updates. If this starts to veer into dangerous territory, I need you to be honest with me. Agreed?”
Torres: [relieved, with a slight smile] “Thank you, Captain. I’ll keep you posted.”
Torres steps out of the ready room after her meeting with Janeway, PADD and security clearance in hand. Her thoughts drift back to Harry Kim as she heads toward the turbolift, but spotting him near a console in the corridor gives her an excuse to pause.
Torres:
With a faint smile, walking up to him.
"Ensign Kim. Shouldn’t you be taking a break?"
Kim:
Turning, chuckling lightly.
"Look who’s talking. I’m just running some diagnostics on the repairs Nicoletti finished. Thought I’d make sure we don’t have any surprises."
Torres:
Crossing her arms, raising an eyebrow.
"After last week, I think we’ve met our quota for a lifetime.”
Kim: “Were you with the Captain just now?”
Torres: “Yeah. Delivered a finished report on the repaired hull breach and needed a clearance for something I’m looking into.”
Kim: “Clearance? From the Captain? For what?”
Torres: “Nothing worth mentioning. At least not yet. How are you holding up, Harry? Really."
Kim:
Pausing, studying her face.
"I’m fine, I think. But what about you? You look... I don’t know. Off. Is everything okay?"
Torres:
Her smirk fades, replaced by a rare vulnerability. She hesitates, then exhales.
"You know, it’s funny. I was just thinking about coming to check on you, but maybe I’m the one who needed it. Seeing you—seeing my friend—forced into the void of space like that... Harry, I thought we lost you. Hell, we actually did. And even though you’re standing here now, a part of me still..."
She trails off, struggling to find the words.
Kim:
Gentle, stepping closer, his voice soft.
"B’Elanna, I’m still me. I know what happened was... horrifying. And I won’t pretend it wasn’t. But whether it’s this Harry or that Harry, I’m still the same person you’ve known all along."
Torres:
Looks down briefly, trying to maintain her composure.
"I know that. But watching you go out like that... I don’t think I’ve ever felt so helpless. And after everything—the Vidiians, the anomaly—it feels like no matter how much I do, it’s never enough."
Kim:
Reaching out, placing a reassuring hand on her shoulder.
"You’re not helpless, B’Elanna. You saved this ship. You kept it together when we were falling apart—literally. You’ve done more than anyone could ever ask, and I’m standing here now because of you."
Torres:
Looking up at him, her expression softening
"I just... I don’t know how you’re so calm about all this. I’d be losing my mind."
Kim:
Smiling faintly, his tone steady.
"Maybe I did. For a while. I even talked to the Captain about it. She told me, ‘We’re Starfleet officers. Weird is part of the job.’ It helped put things in perspective, but the thing that stuck with me most is this: we’re still here. And no matter how strange or impossible it all seems, we’re still us. That’s what matters. And as long as that’s true, we’ll get through this. Together."
Torres:
Her lips quirk into a small, grateful smile. She lightly squeezes his arm.
"Thanks, Harry. For reminding me. Maybe I’ll even take a break."
Kim:
Chuckling, stepping back.
"Knowing you? I’ll believe it when I see it."
Torres shakes her head, smirking faintly as she turns toward the turbolift. As the doors close behind her, the moment lingers. Harry’s words, simple yet steady, stay with her—grounding her in a way she didn’t realize she needed.
Following her talk with Kim, Torres spent a couple of hours gathering ideas.
She made a priority reservation for Holodeck 2 to test her initial theories and verify if any of her ideas have merit. As B’Elanna walked towards her destination on deck 6, she tapped her comm-badge: “Torres to engineering.” - a familiar voice answered: “Carey here.”
Torres: “Joe, I am going to be busy conducting some research over the next few days with the Captain’s permission and I can’t afford any distractions. I need you to handle things in my absence.”
Carey: “Certainly. Mind if I ask what you’re working on? Perhaps I can offer assistance.”
Torres: “I appreciate the offer, but no. This is more of an exploratory analysis for now. But if I encounter problems, I will not hesitate to take you up on that offer. Torres out.”
Torres appreciated Carey’s enthusiasm and expertise, but she didn’t want to bring in anyone from engineering into this just yet. Not to mention the fact that they’ve done some extraordinary and difficult work over the past week with repairs, so they were well due for some routine work and downtime. But Torres was also tired, promising herself that after assembling a basic framework, she’ll take at least a short break before preparing her findings.
As she enters the holodeck, B’Elanna notices a minor flicker in the LCARS display on the arch and rolls her eyes.
Torres: [muttering] “Nothing like a quick relay fix to kick things off.”
With practised ease, she aligns the relay panels, restoring the display to normal function.
Torres: “Better. Computer, display all relevant data on quantum torpedoes and foundational Federation research on zero-point energy extraction. I need to identify any potential overlap.”
Computer: “Access to Federation theoretical and developmental research on Zero Point Energy is classified. Specify identity and clearance level.”
Torres: “Liutenant B’Elanna Torres, clearance code Alpha-Delta-9.”
The holodeck pauses for a moment, and then the display fills with classified Starfleet data.
Computer: “Voice print recognized. Provisional clearance verified. Access granted.
Security precautions initiated. Sealing access to Holodeck 2. Authorization to lift the seal as needed granted to Liutenant B’Elanna Torres and Captain Janeway.”
Torres hears the holodeck doors seal, and the computer continues with its narration:
Computer: “Quantum torpedoes incorporate synthetic neutronium, dilithium, and quantum initiators. The neutronium provides containment stability under extreme forces, dilithium modulates energy for controlled high-energy output, and quantum initiators facilitate matter-antimatter energy transfer with precision, allowing for concentrated energy yields.”
The computer pauses, appearing to sift through additional files before continuing.
Computer: “Federation theoretical research into zero-point energy (ZPE) extraction includes primary components and principles.”
A holographic list and visual representation appear before Torres, detailing concepts for ZPE core construction. She crosses her arms, carefully analyzing each line as the computer elaborates.
• **Containment Fields**: ZPE systems rely on advanced containment matrices, similar to antimatter storage, enhanced to sustain vacuum energy. Key materials include tritanium composites and exotic field emitters.
• **Quantum Lattices**: Quantum lattices isolate and amplify vacuum fluctuations. Federation research indicates lattices with subspace-reinforced alloys, such as duranium mixed with metaphasic enhancements, could support zero-point scales.
• **Energy Extraction Nodes**: Quantum initiators regulate energy extraction by precisely modulating the Casimir effect. Synthetic neutronium provides containment stability, while dilithium facilitates controlled energy flow for scalable reactions.
• **Stabilization Cores**: Quantum stabilizers prevent decoherence, with materials like metamaterials that adapt to real-time fluctuations.
• **Subspace Dampening Arrays**: Damping subspace resonance interference through quantum phase discriminators improves energy stability during extraction.
Torres leans closer, examining each entry, her mind spinning with potential configurations.
Torres: “There’s quite a bit here. Computer! Would combining principles from quantum torpedo technology and Federation zero-point research provide a workable foundation for a Zero Point Energy core?”
Computer:
[Pausing longer than usual, as if reluctant]
“Warning! Suggested line of questioning leads into a highly speculative area. Zero Point Energy core construction has not been successfully developed in Federation research. Do you wish to proceed?”
Torres: [impatiently] “Yes! Proceed.”
Computer:
[After a lengthy pause]
“Working… Listed technologies form a theoretical basis for Zero Point Energy core construction. Challenges include: Amplification limits due to the inability to scale vacuum energy extraction beyond the capacities used in quantum torpedoes.
Material degradation under sustained high-energy demands.
Difficulty replicating or manufacturing required high-stability materials.
Conclusion: Initial evaluation indicates preliminary alignment with foundational ZPE principles. However, all practical applications to date have been limited to short-term enhancement of antimatter reactions in quantum torpedoes. Transition to sustained energy generation remains highly speculative.”
Torres:
[Frowning, muttering under her breath]
“Highly speculative, sure, but it’s better than nothing. Computer! What if we used replicable materials—things we can refine or synthesize on Voyager?”
Computer: ”Energy dynamics and stability associated with Zero Point Energy extraction involve exotic materials with complexities surpassing current material capabilities that can be replicated. Conclusion: replicable materials do not meet needed requirements.”
Torres: “And, of course it wouldn't be that easy. Which means, I’ll just have to expand on the possibilities. Computer! Cross-reference Federation database. Extend search of potentially suitable replicable materials to include historical files and try again.”
Computer: “Warning! Replicable materials do not…!
Torres: [Snapping] "I said *try anyway!*"
Computer. “Working.”
After a few moments that seemed like an hour, the computer finally chimed in:
Computer: “References to theoretical frameworks from early 21st-century Earth contain highly speculative data on Zero Point Energy. Warning! Insufficient data!”
Torres: “Damn... the data must have been damaged or lost in World War III.” – thinking further: “Well, we are fair bit more advanced than back then. Computer! Access my personal database. Use a high grade reconstructive algorithm listed as TRA-1 to try and piece together as much relevant data as you can. Also look for the kind of materials that were used or speculated back from that era that do exist in the archives to extrapolate the necessary information. Aim for most accurate results.”
Computer: “Working! Extrapolation complete. Superconductors such as YBCO, graphene, carbon nanotubes, synthetic diamonds, titanium, adaptive metamaterials, and dielectrics like barium titanate or hafnium oxide speculated to be theoretically viable.”
A spark of hope.
Torres: “Computer! Display a list of those materials for me and graphical composition of each.”
The computer beeped in acknowledgment. The holodeck was filled with overlapping graphical images of materials the computer mentioned.
Torres noticed the 2D structure of graphene and some of the extrapolations the computer was able to do. Including quantum capabilities it had and intriguing properties of adaptive metamaterials.
Torres: “This might have some merit. Computer, analyse the possibility if we used these materials, could they stabilize a ZPE core?”
Computer: [Hesitant again]
"Warning! Speculative adjustments may—"
Torres: [Interrupting] "Override and proceed!"
Computer: “Acknowledged. Preliminary analysis indicates a composite of superconductors, graphene, carbon nanotubes, synthetic diamonds, titanium, and adaptive metamaterials could provide the required stability. The composite would approximate the stability of exotic materials and quantum lattices under specific configurations.”
Torres: [nodding thoughtfully] “Good. What if we precisely adjust the atomic arrangements in these materials? Could adaptive metamaterials and graphene replicate the functions of quantum lattices for energy extraction and containment?”
Computer: [processing with a slight delay] “Warning! Speculative…!
Torres: “Oh come on. Override!”
Computer: “Acknowledged! Atomic configuration adjustments within the composite, particularly leveraging adaptive metamaterials and graphene could hypothetically simulate lattice-like properties required for zero-point energy extraction. Extrapolative analysis indicates 10-15 percent uncertainty remains under prolonged extraction scenarios.”
Torres: [another spark of hope, but cautiously tempered] “I’ll need far better assurances than that. Extrapolate further. Could we reduce that uncertainty with simulations using Voyager’s computer core processor?”
Computer:
“Unable to comply! Extrapolation exceeds established data thresholds.”
Torres:
[Mutters under her breath as the computer halts another simulation] “THIS is where you draw the line? You’ve got to be kidding me.”
She rubs her temples, frustrated but not surprised. Starfleet computers were unparalleled when it came to precision, capable of reconstructing complex datasets from the smallest fragments of data. But this precision came with a price: built-in safeguards to ensure the integrity of their conclusions. Safeguards that, in moments like this, felt more like a noose.
Torres (internal monologue):
“They’re designed to prevent errors—no hallucinations, no wild guesses, just scientifically sound results. Great in theory. But when you’re working in the margins, those same safeguards keep you from going beyond the margins.”
She takes a deep breath, pacing. Then she stops, her eyes lighting up with an idea from her hypothetical games with Dreadnought.
Torres:
“Computer, let’s try this another way. Enter assumption that a theoretical framework exists for extrapolating beyond current data thresholds while preserving scientific accuracy. Extrapolate under this assumption.”
Computer:
[Processing, then replying cautiously] “Extrapolation results indicate potential viability for reducing uncertainty to approximate 3 to 5 percent under stated assumptions.”
Torres:
[Smiling faintly] “Thought so. And you didn’t even have to hallucinate to get there.”
She inputs additional parameters, watching as the computer begins to adapt its algorithms within the new framework. Slowly, the pieces of her ZPE core theory start falling into place.
Hours pass as Torres continues refining her ideas. The limitations of the current system, coupled with the sheer scale of the ZPE core project, push her to think beyond conventional engineering workflows. She leans back for a moment, staring at the holographic displays before her.
Torres:
[To herself] “This isn’t going to work piecemeal. I need something that can adapt, simulate, and refine… without hitting a wall every time it runs into the unknown.”
A new idea forms in her mind—an adaptive system, capable of learning and iterating on its own. Her experience with the Dreadnought’s AI and Starfleet’s precision modelling tools converges into a single concept.
Torres:
“Computer, set up an automated research and development framework. I’m calling it… AI Forge. Here’s the setup: dynamically integrate physics, engineering, and materials science models into a unified simulation system. Prioritize replicable materials for all designs, focusing on configurations that can be synthesized or refined on Voyager. Use machine learning to iterate designs, generate hypotheses, and simulate outcomes. All results must adhere to a strict ethical, verification and viability threshold—99.99% accuracy or higher.”
Computer:
“Analysing… AI Forge framework would incorporate specialized domain models, allowing granular simulations. Machine learning algorithms would enable adaptive refinement of properties, while hypothesis generation and testing would enhance accuracy. Focus on replicable materials acknowledged.”
Torres nods, feeling a glimmer of satisfaction as the computer processes her instructions. But then:
Computer:
Warning! Suggested framework is not recommended under standard protocols.”
Torres:
[Muttering] “Standard protocols aren’t exactly our biggest concern here, are they?
Computer, override similar warnings for this project only. Proceed with AI Forge creation.”
Computer:
[After a long pause] “Override accepted. Proceeding with framework creation.”
Over the next several hours, she refines the parameters, adding specific directives to guide the Forge’s development.
The holographic displays update, showing a more dynamic simulation environment. Torres inputs the initial parameters for a ZPE core design, emphasizing the need for replicable materials.
Torres:
“Computer, in matter of ZPE core, focus on materials that can be synthesized aboard Voyager. Exclude configurations relying on non-replicable exotic components unless alternatives are absolutely unattainable.”
Computer:
“Directive acknowledged. Initial projections for ZPE core design indicate reliance on replicable composites: superconductors, graphene, carbon nanotubes, synthetic diamonds, titanium, and adaptive metamaterials.”
Torres:
[Grinning slightly] “That’s more like it. Now, let’s see what you can do.”
As the AI Forge processes the ZPE core configuration, it identifies potential bottlenecks, including material degradation under high-energy demands and containment field amplification limits. Torres begins addressing these one by one, using the Forge to iterate possible solutions.
Chief Engineer Log: Lt. B’Elanna Torres
Stardate 49555.7
“It’s been a week since Voyager endured the worst of the spatial scission anomaly. Two versions of the ship, occupying the same space, straining every system to the breaking point and nearly draining our antimatter. And then the Vidiians attacked. We lost an entire duplicate crew—people who were us, down to the last molecule—and yet, it’s the strangest feeling. Harry Kim and Naomi Wildman survived, but they’re not quite the same Harry and Naomi we started with. Or maybe they are? I can’t help but feel the loss, even if logically, they’re still here. I’ve never been good at untangling emotions, and this... well, it’s a lot to process.
“Repairs have been overwhelming. The hull breach spanning Decks 14 and 15 was the worst—open to space, half the bulkheads buckling under stress. I can still see Harry helplessly being forced out into space when the breach widened. Maybe I can pay him a brief visit for reassurance. Carey and Vorik took charge of the structural integrity teams, and Nicoletti worked miracles with the power distribution systems and force field generators. The antimatter injectors needed manual attention; I spent hours crawling through Jeffries tubes just to stabilize them. It’s not perfect, but it’ll hold—for now.
“But holding isn’t enough. Our antimatter reserves are critically low—below twenty percent—and there’s no guarantee we’ll find more anytime soon. We’ve pushed the warp core efficiency to its limits, and it’s clear we can’t rely on conventional means much longer. During repairs, my mind kept wandering back to the Dreadnought and its Quantum Torpedoes. At first I couldn’t understand WHY, and then it hit me. Zero Point Energy. They use ZPE principles to enhance their explosive yield. What if I could tap into that somehow? The obstacles seem huge from a research point of view, but I think I found a way around that problem. To even begin testing it, I need access to Starfleet’s classified research on Zero Point Energy—materials and principles that could bridge the gap to make an actual energy source. I’ll have to take it to the Captain and see if she’s willing to trust me with this leap without revealing too much. Can’t get hers or the crew’s hopes up.”
Ready Room – Seeking Clearance
Captain Janeway leans back in her chair, savouring a rare moment of calm after the brutal fight to restore Voyager from the recent spatial scission anomaly. Her crew has endured exhausting repairs and tense moments, but Janeway feels an undercurrent of resilience that reassures her they’ll bounce back stronger than ever. The chime of the door interrupts her thoughts.
Janeway: “Come in.”
The doors slide open, and Lieutenant B’Elanna Torres enters, her expression focused and slightly reserved, with a spark of excitement she’s trying to keep in check.
Janeway: [gesturing to a seat] “B’Elanna. How are repairs coming along?”
Torres hands Janeway a PADD, nodding as she does.
Torres: “There are no more signs of microfractures on the hull, and we’ve fully sealed the breach along Decks 14 and 15, Captain.”
Janeway skims the PADD, nodding with satisfaction.
Janeway: “Good work. Those decks took quite a beating. Any concerns with structural integrity?”
Torres: “None, Captain. Reinforcement checks are showing all sections are back to optimal stability. The hull’s holding steady, and we can start letting people back onto those decks.”
Janeway nods approvingly, but then Torres continues, her tone shifting slightly.
Torres: “There’s another matter, though. With our antimatter reserves as low as they are, it’s becoming clear we’ll need alternative solutions if we’re going to sustain ourselves out here for the long haul.”
Janeway’s expression tightens, aware of the reality their low reserves imply.
Janeway: “A grim reality indeed. But I sense there’s something specific you’re getting at.” [she eyes Torres with a blend of curiosity and authority] “What’s on your mind?”
Torres hesitates, as if weighing how much to reveal.
Torres: “I have an idea… a theory. It’s early, and I wouldn’t want to raise expectations just yet. But to explore it, I need access to Starfleet’s classified data on quantum torpedoes. The developmental files, specifically.”
Janeway leans back, studying Torres carefully. Her tone turns slightly more probing.
Janeway: “B’Elanna, that’s high-level information—classified for a reason. Why would developmental data on quantum weapons have anything to do with our energy concerns?”
Torres’s eyes flicker with restrained determination.
Torres: “Captain, I’m already familiar with quantum torpedoes from my time in the Maquis, especially after working on the Dreadnought missile back in the Alpha Quadrant. I know their structure and general capabilities, but there are energy dynamics involved in their design that go beyond standard Starfleet propulsion or power systems. To test my idea, I need that knowledge.”
Janeway: [pressing gently] “If this is about alternative power sources, you should know that I need more than vague assurances to justify giving you access to classified files. We’re talking about a risk—to Voyager and to you. Can you give me something more specific?”
Torres takes a deep breath, visibly weighing her response.
Torres: “Captain, all I can say right now is that this might help us address our antimatter shortage more… sustainably. But I can’t guarantee results yet, and I’d rather not give the crew or you false hope. I just need to make sure it’s even feasible before I say more.”
Janeway regards Torres with a blend of caution and respect. She knows her chief engineer wouldn’t ask without reason, but she also recognizes the potential risks.
Janeway: “You don’t ask for something like this lightly, do you?” [a beat, then a nod of resolution] “Alright, B’Elanna. I’ll grant you provisional access—but I expect regular updates. If this starts to veer into dangerous territory, I need you to be honest with me. Agreed?”
Torres: [relieved, with a slight smile] “Thank you, Captain. I’ll keep you posted.”
Torres steps out of the ready room after her meeting with Janeway, PADD and security clearance in hand. Her thoughts drift back to Harry Kim as she heads toward the turbolift, but spotting him near a console in the corridor gives her an excuse to pause.
Torres:
With a faint smile, walking up to him.
"Ensign Kim. Shouldn’t you be taking a break?"
Kim:
Turning, chuckling lightly.
"Look who’s talking. I’m just running some diagnostics on the repairs Nicoletti finished. Thought I’d make sure we don’t have any surprises."
Torres:
Crossing her arms, raising an eyebrow.
"After last week, I think we’ve met our quota for a lifetime.”
Kim: “Were you with the Captain just now?”
Torres: “Yeah. Delivered a finished report on the repaired hull breach and needed a clearance for something I’m looking into.”
Kim: “Clearance? From the Captain? For what?”
Torres: “Nothing worth mentioning. At least not yet. How are you holding up, Harry? Really."
Kim:
Pausing, studying her face.
"I’m fine, I think. But what about you? You look... I don’t know. Off. Is everything okay?"
Torres:
Her smirk fades, replaced by a rare vulnerability. She hesitates, then exhales.
"You know, it’s funny. I was just thinking about coming to check on you, but maybe I’m the one who needed it. Seeing you—seeing my friend—forced into the void of space like that... Harry, I thought we lost you. Hell, we actually did. And even though you’re standing here now, a part of me still..."
She trails off, struggling to find the words.
Kim:
Gentle, stepping closer, his voice soft.
"B’Elanna, I’m still me. I know what happened was... horrifying. And I won’t pretend it wasn’t. But whether it’s this Harry or that Harry, I’m still the same person you’ve known all along."
Torres:
Looks down briefly, trying to maintain her composure.
"I know that. But watching you go out like that... I don’t think I’ve ever felt so helpless. And after everything—the Vidiians, the anomaly—it feels like no matter how much I do, it’s never enough."
Kim:
Reaching out, placing a reassuring hand on her shoulder.
"You’re not helpless, B’Elanna. You saved this ship. You kept it together when we were falling apart—literally. You’ve done more than anyone could ever ask, and I’m standing here now because of you."
Torres:
Looking up at him, her expression softening
"I just... I don’t know how you’re so calm about all this. I’d be losing my mind."
Kim:
Smiling faintly, his tone steady.
"Maybe I did. For a while. I even talked to the Captain about it. She told me, ‘We’re Starfleet officers. Weird is part of the job.’ It helped put things in perspective, but the thing that stuck with me most is this: we’re still here. And no matter how strange or impossible it all seems, we’re still us. That’s what matters. And as long as that’s true, we’ll get through this. Together."
Torres:
Her lips quirk into a small, grateful smile. She lightly squeezes his arm.
"Thanks, Harry. For reminding me. Maybe I’ll even take a break."
Kim:
Chuckling, stepping back.
"Knowing you? I’ll believe it when I see it."
Torres shakes her head, smirking faintly as she turns toward the turbolift. As the doors close behind her, the moment lingers. Harry’s words, simple yet steady, stay with her—grounding her in a way she didn’t realize she needed.
Following her talk with Kim, Torres spent a couple of hours gathering ideas.
She made a priority reservation for Holodeck 2 to test her initial theories and verify if any of her ideas have merit. As B’Elanna walked towards her destination on deck 6, she tapped her comm-badge: “Torres to engineering.” - a familiar voice answered: “Carey here.”
Torres: “Joe, I am going to be busy conducting some research over the next few days with the Captain’s permission and I can’t afford any distractions. I need you to handle things in my absence.”
Carey: “Certainly. Mind if I ask what you’re working on? Perhaps I can offer assistance.”
Torres: “I appreciate the offer, but no. This is more of an exploratory analysis for now. But if I encounter problems, I will not hesitate to take you up on that offer. Torres out.”
Torres appreciated Carey’s enthusiasm and expertise, but she didn’t want to bring in anyone from engineering into this just yet. Not to mention the fact that they’ve done some extraordinary and difficult work over the past week with repairs, so they were well due for some routine work and downtime. But Torres was also tired, promising herself that after assembling a basic framework, she’ll take at least a short break before preparing her findings.
As she enters the holodeck, B’Elanna notices a minor flicker in the LCARS display on the arch and rolls her eyes.
Torres: [muttering] “Nothing like a quick relay fix to kick things off.”
With practised ease, she aligns the relay panels, restoring the display to normal function.
Torres: “Better. Computer, display all relevant data on quantum torpedoes and foundational Federation research on zero-point energy extraction. I need to identify any potential overlap.”
Computer: “Access to Federation theoretical and developmental research on Zero Point Energy is classified. Specify identity and clearance level.”
Torres: “Liutenant B’Elanna Torres, clearance code Alpha-Delta-9.”
The holodeck pauses for a moment, and then the display fills with classified Starfleet data.
Computer: “Voice print recognized. Provisional clearance verified. Access granted.
Security precautions initiated. Sealing access to Holodeck 2. Authorization to lift the seal as needed granted to Liutenant B’Elanna Torres and Captain Janeway.”
Torres hears the holodeck doors seal, and the computer continues with its narration:
Computer: “Quantum torpedoes incorporate synthetic neutronium, dilithium, and quantum initiators. The neutronium provides containment stability under extreme forces, dilithium modulates energy for controlled high-energy output, and quantum initiators facilitate matter-antimatter energy transfer with precision, allowing for concentrated energy yields.”
The computer pauses, appearing to sift through additional files before continuing.
Computer: “Federation theoretical research into zero-point energy (ZPE) extraction includes primary components and principles.”
A holographic list and visual representation appear before Torres, detailing concepts for ZPE core construction. She crosses her arms, carefully analyzing each line as the computer elaborates.
• **Containment Fields**: ZPE systems rely on advanced containment matrices, similar to antimatter storage, enhanced to sustain vacuum energy. Key materials include tritanium composites and exotic field emitters.
• **Quantum Lattices**: Quantum lattices isolate and amplify vacuum fluctuations. Federation research indicates lattices with subspace-reinforced alloys, such as duranium mixed with metaphasic enhancements, could support zero-point scales.
• **Energy Extraction Nodes**: Quantum initiators regulate energy extraction by precisely modulating the Casimir effect. Synthetic neutronium provides containment stability, while dilithium facilitates controlled energy flow for scalable reactions.
• **Stabilization Cores**: Quantum stabilizers prevent decoherence, with materials like metamaterials that adapt to real-time fluctuations.
• **Subspace Dampening Arrays**: Damping subspace resonance interference through quantum phase discriminators improves energy stability during extraction.
Torres leans closer, examining each entry, her mind spinning with potential configurations.
Torres: “There’s quite a bit here. Computer! Would combining principles from quantum torpedo technology and Federation zero-point research provide a workable foundation for a Zero Point Energy core?”
Computer:
[Pausing longer than usual, as if reluctant]
“Warning! Suggested line of questioning leads into a highly speculative area. Zero Point Energy core construction has not been successfully developed in Federation research. Do you wish to proceed?”
Torres: [impatiently] “Yes! Proceed.”
Computer:
[After a lengthy pause]
“Working… Listed technologies form a theoretical basis for Zero Point Energy core construction. Challenges include: Amplification limits due to the inability to scale vacuum energy extraction beyond the capacities used in quantum torpedoes.
Material degradation under sustained high-energy demands.
Difficulty replicating or manufacturing required high-stability materials.
Conclusion: Initial evaluation indicates preliminary alignment with foundational ZPE principles. However, all practical applications to date have been limited to short-term enhancement of antimatter reactions in quantum torpedoes. Transition to sustained energy generation remains highly speculative.”
Torres:
[Frowning, muttering under her breath]
“Highly speculative, sure, but it’s better than nothing. Computer! What if we used replicable materials—things we can refine or synthesize on Voyager?”
Computer: ”Energy dynamics and stability associated with Zero Point Energy extraction involve exotic materials with complexities surpassing current material capabilities that can be replicated. Conclusion: replicable materials do not meet needed requirements.”
Torres: “And, of course it wouldn't be that easy. Which means, I’ll just have to expand on the possibilities. Computer! Cross-reference Federation database. Extend search of potentially suitable replicable materials to include historical files and try again.”
Computer: “Warning! Replicable materials do not…!
Torres: [Snapping] "I said *try anyway!*"
Computer. “Working.”
After a few moments that seemed like an hour, the computer finally chimed in:
Computer: “References to theoretical frameworks from early 21st-century Earth contain highly speculative data on Zero Point Energy. Warning! Insufficient data!”
Torres: “Damn... the data must have been damaged or lost in World War III.” – thinking further: “Well, we are fair bit more advanced than back then. Computer! Access my personal database. Use a high grade reconstructive algorithm listed as TRA-1 to try and piece together as much relevant data as you can. Also look for the kind of materials that were used or speculated back from that era that do exist in the archives to extrapolate the necessary information. Aim for most accurate results.”
Computer: “Working! Extrapolation complete. Superconductors such as YBCO, graphene, carbon nanotubes, synthetic diamonds, titanium, adaptive metamaterials, and dielectrics like barium titanate or hafnium oxide speculated to be theoretically viable.”
A spark of hope.
Torres: “Computer! Display a list of those materials for me and graphical composition of each.”
The computer beeped in acknowledgment. The holodeck was filled with overlapping graphical images of materials the computer mentioned.
Torres noticed the 2D structure of graphene and some of the extrapolations the computer was able to do. Including quantum capabilities it had and intriguing properties of adaptive metamaterials.
Torres: “This might have some merit. Computer, analyse the possibility if we used these materials, could they stabilize a ZPE core?”
Computer: [Hesitant again]
"Warning! Speculative adjustments may—"
Torres: [Interrupting] "Override and proceed!"
Computer: “Acknowledged. Preliminary analysis indicates a composite of superconductors, graphene, carbon nanotubes, synthetic diamonds, titanium, and adaptive metamaterials could provide the required stability. The composite would approximate the stability of exotic materials and quantum lattices under specific configurations.”
Torres: [nodding thoughtfully] “Good. What if we precisely adjust the atomic arrangements in these materials? Could adaptive metamaterials and graphene replicate the functions of quantum lattices for energy extraction and containment?”
Computer: [processing with a slight delay] “Warning! Speculative…!
Torres: “Oh come on. Override!”
Computer: “Acknowledged! Atomic configuration adjustments within the composite, particularly leveraging adaptive metamaterials and graphene could hypothetically simulate lattice-like properties required for zero-point energy extraction. Extrapolative analysis indicates 10-15 percent uncertainty remains under prolonged extraction scenarios.”
Torres: [another spark of hope, but cautiously tempered] “I’ll need far better assurances than that. Extrapolate further. Could we reduce that uncertainty with simulations using Voyager’s computer core processor?”
Computer:
“Unable to comply! Extrapolation exceeds established data thresholds.”
Torres:
[Mutters under her breath as the computer halts another simulation] “THIS is where you draw the line? You’ve got to be kidding me.”
She rubs her temples, frustrated but not surprised. Starfleet computers were unparalleled when it came to precision, capable of reconstructing complex datasets from the smallest fragments of data. But this precision came with a price: built-in safeguards to ensure the integrity of their conclusions. Safeguards that, in moments like this, felt more like a noose.
Torres (internal monologue):
“They’re designed to prevent errors—no hallucinations, no wild guesses, just scientifically sound results. Great in theory. But when you’re working in the margins, those same safeguards keep you from going beyond the margins.”
She takes a deep breath, pacing. Then she stops, her eyes lighting up with an idea from her hypothetical games with Dreadnought.
Torres:
“Computer, let’s try this another way. Enter assumption that a theoretical framework exists for extrapolating beyond current data thresholds while preserving scientific accuracy. Extrapolate under this assumption.”
Computer:
[Processing, then replying cautiously] “Extrapolation results indicate potential viability for reducing uncertainty to approximate 3 to 5 percent under stated assumptions.”
Torres:
[Smiling faintly] “Thought so. And you didn’t even have to hallucinate to get there.”
She inputs additional parameters, watching as the computer begins to adapt its algorithms within the new framework. Slowly, the pieces of her ZPE core theory start falling into place.
Hours pass as Torres continues refining her ideas. The limitations of the current system, coupled with the sheer scale of the ZPE core project, push her to think beyond conventional engineering workflows. She leans back for a moment, staring at the holographic displays before her.
Torres:
[To herself] “This isn’t going to work piecemeal. I need something that can adapt, simulate, and refine… without hitting a wall every time it runs into the unknown.”
A new idea forms in her mind—an adaptive system, capable of learning and iterating on its own. Her experience with the Dreadnought’s AI and Starfleet’s precision modelling tools converges into a single concept.
Torres:
“Computer, set up an automated research and development framework. I’m calling it… AI Forge. Here’s the setup: dynamically integrate physics, engineering, and materials science models into a unified simulation system. Prioritize replicable materials for all designs, focusing on configurations that can be synthesized or refined on Voyager. Use machine learning to iterate designs, generate hypotheses, and simulate outcomes. All results must adhere to a strict ethical, verification and viability threshold—99.99% accuracy or higher.”
Computer:
“Analysing… AI Forge framework would incorporate specialized domain models, allowing granular simulations. Machine learning algorithms would enable adaptive refinement of properties, while hypothesis generation and testing would enhance accuracy. Focus on replicable materials acknowledged.”
Torres nods, feeling a glimmer of satisfaction as the computer processes her instructions. But then:
Computer:
Warning! Suggested framework is not recommended under standard protocols.”
Torres:
[Muttering] “Standard protocols aren’t exactly our biggest concern here, are they?
Computer, override similar warnings for this project only. Proceed with AI Forge creation.”
Computer:
[After a long pause] “Override accepted. Proceeding with framework creation.”
Over the next several hours, she refines the parameters, adding specific directives to guide the Forge’s development.
The holographic displays update, showing a more dynamic simulation environment. Torres inputs the initial parameters for a ZPE core design, emphasizing the need for replicable materials.
Torres:
“Computer, in matter of ZPE core, focus on materials that can be synthesized aboard Voyager. Exclude configurations relying on non-replicable exotic components unless alternatives are absolutely unattainable.”
Computer:
“Directive acknowledged. Initial projections for ZPE core design indicate reliance on replicable composites: superconductors, graphene, carbon nanotubes, synthetic diamonds, titanium, and adaptive metamaterials.”
Torres:
[Grinning slightly] “That’s more like it. Now, let’s see what you can do.”
As the AI Forge processes the ZPE core configuration, it identifies potential bottlenecks, including material degradation under high-energy demands and containment field amplification limits. Torres begins addressing these one by one, using the Forge to iterate possible solutions.
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