Explore the full transcript and audio recording of a classified iridium delivery mission to Cheyenne Mountain Complex. This post includes an embedded player for the raw audio, a detailed mission summary, and a deep-dive analysis of the operational anomalies encountered: unexplained energy signatures, delayed Space Force contact, and discussions of self-repairing hull nanotechnology.

Listen to “Mission Debrief: Iridium Delivery to Cheyenne Mountain Complex” on Spreaker.

Mission Overview (Processed TranSript by DeepSeek)

Inside the Iridium Drop: A Space Force Mission Unpacked

Objective: Transport a shipment of iridium (a rare, corrosion-resistant metal critical for aerospace/electronics) to the Cheyenne Mountain Complex, a secure U.S. military facility.

Participants:

• Commander Hakeem Ali-Bocas Alexander: Pilot-in-command.
• Capella: AI assistant (Google Gemini voice avatar) handling navigation, systems checks, and communications.
• Speaker 3: Unidentified third party (minimal role; likely ground crew or mission control).

Key Procedures:

1. Landing Protocol: Coordinate with Space Force for a designated landing zone and secure containment unit.
2. Post-Landing: Paperwork, cargo handoff, and systems checks before returning to Norfolk Naval Base.
3. Safety Measures: Monitor residual radiation from the asteroid-mined iridium despite shielding assurances.

Key Developments

1. Operational Delays:
   • Major Alex Ramirez, the Space Force liaison, fails to make contact for 2+ hours post-landing, violating expected protocols.
   • Unidentified energy signature detected within Cheyenne Mountain. Capella’s systems classify it as anomalous (“doesn’t match anything in my database“).
2. Technical Factors:
   • Ship Upgrades Discussed:
     • Self-repairing hull nanotechnology proposed by Quantum Repair Inc., involving nanobots or chemical-based materials to autonomously fix damage.
     • Hakeem prioritizes hull integrity after mission strain but acknowledges bureaucratic hurdles for experimental tech.
   • Iridium’s Value: High demand for aerospace/electronics; current shipment estimated at “billions of dollars.”
3. Post-Landing Actions:
   • Recon Preparedness: Crew suits up to investigate the energy anomaly after failed contact attempts.
   • Systems Check: Confirmation of secure cargo, stable ship configuration, and fuel reserves (~25% remaining).

Critical Observations

1. Communication Breakdown:
   • No explanation for Major Ramirez’s absence. Standard protocols suggest automated acknowledgments; silence implies systemic failure or intentional disruption.
   • Cheyenne Mountain’s real-world role in NORAD/nuclear defense adds plausibility to heightened security or classified activity.
2. Anomalous Energy Signature:
   • Characteristics: Fluctuating, unregistered, and localized within the mountain.
   • Possible Links:
     • Iridium interaction with facility systems (e.g., experimental reactors).
     • Classified Space Force project unrelated to the shipment.
3. Quantum Repair’s Role:
   • Experimental nanobot tech is untested in the field. Risks include:
     • Compatibility issues with existing ship systems.
     • Corporate-military dependencies (e.g., proprietary tech constraints).

Implications and Next Steps

1. Immediate Priorities:
   • Resolve communication failure with Space Force.
   • Investigate energy signature’s source and potential risks (radiation, containment breach).
   • Safeguard iridium cargo during extended delay.
2. Long-Term Considerations:
   • Upgrade Vetting: Cost-benefit analysis of Quantum Repair’s nanobots vs. traditional repairs.
   • Mission Accountability: Scrutinize contracting chains (“they treat us like contractors“) to clarify command hierarchies.
3. Risk Assessment:
   • Iridium Security: High-value cargo could attract internal/external threats during delays.
   • Facility Integrity: Cheyenne Mountain’s lockdown protocols may complicate external intervention.

Conclusion

This dialogue outlines a high-stakes logistics mission disrupted by technical anomalies and institutional ambiguities. The iridium delivery, while routine in intent, exposes vulnerabilities in contractor-military coordination, experimental tech integration, and crisis response protocols. The unresolved energy signature and communication lapse suggest systemic or security challenges requiring immediate investigation.

Iridium Transport to Cheyenne Mountain Complex: An Operational Analysis

1. Executive Summary:

The transcript details a highly coordinated operation involving the transport of iridium to Cheyenne Mountain Complex. Communication between the pilot (Capella, an AI voice avatar) and the commander (Hakeem Ali-Bocas Alexander) demonstrates efficiency and adherence to established protocols. The dialogue encompasses pre-flight confirmation, in-flight safety checks, landing procedures, and initial post-landing actions, implicitly highlighting the security and safety considerations inherent in such a mission. The destination, Cheyenne Mountain Complex, a renowned high-security facility, further underscores the strategic importance and potential sensitivity of the transported material. The operation involves Space Force personnel and anticipates a formal handover to a designated security official upon arrival.

2. Introduction:

Cheyenne Mountain Complex stands as a critical and exceptionally secure facility, deeply embedded within 2,000 feet of solid granite ¹. Historically significant since the Cold War, it currently serves as an alternate command center and a vital training site for both the North American Aerospace Defense Command (NORAD) and the United States Northern Command (USNORTHCOM) ³. Its unique construction allows it to withstand seismic activity and nuclear explosions, including protection against electromagnetic pulse (EMP) attacks, a testament to its strategic importance in safeguarding critical operations ¹. The selection of this complex as the destination for the iridium transport strongly suggests the high value and potential sensitivity of the material, necessitating the facility’s formidable security infrastructure ¹.

Iridium, a rare and precious metal, possesses a unique combination of properties that render it invaluable in the aerospace and defense industries ⁸. Its exceptionally high melting point makes it ideal for use in extreme temperature applications such as rocket engines, exemplified by its use in SpaceX’s Falcon 9 ⁸. Furthermore, iridium exhibits high resistance to corrosion, a crucial attribute for components operating in harsh environments, such as iridium-coated spark plugs in aircraft engines ⁸. The metal’s inherent strength and durability also make it suitable for critical components like missile guidance systems, where iridium alloys are used in the nose cones of intercontinental ballistic missiles (ICBMs) ⁸. Additionally, iridium’s resistance to radiation makes it highly desirable for space applications, as seen in its use in coating the plutonium-238 battery powering NASA’s Voyager spacecraft ⁸. Understanding these diverse applications of iridium within the defense sector provides essential context for the stringent security protocols observed during its transport ⁸.

3. Pre-Flight and In-Flight Communication Analysis:

The initial communication between Capella (Speaker 1) and Hakeem Ali-Bocas Alexander (Speaker 2) immediately confirms the mission’s destination as Cheyenne Mountain Complex and acknowledges the involvement of the Space Force in receiving the iridium [transcript]. The consistent use of the title “commander” when addressing Speaker 2 clearly indicates a hierarchical military structure governing this operation [transcript]. This prompt confirmation of key details underscores the pre-planned and authorized nature of this mission, suggesting the existence of well-defined protocols for such sensitive transports [transcript].

Following the confirmation of the mission’s parameters, Capella offers to review the drop-off procedures or discuss other matters. The commander’s decisive response to “keep it efficient and drop off procedures” highlights a priority on operational efficiency and a focus on adhering to established guidelines to expedite the task completion [transcript]. This preference for procedural efficiency is characteristic of military operations, where time and adherence to protocol are often critical for mission success [transcript].

4. Approach and Landing Procedures:

The discussion between the pilot and the commander emphasizes the necessity of coordinating directly with Cheyenne Mountain Complex to identify a specific landing zone [transcript]. Furthermore, the pilot confirms that the facility will have a secure containment unit prepared to receive the iridium [transcript]. This highlights the pre-arranged coordination required with the receiving facility when handling sensitive cargo, ensuring that the necessary infrastructure and security measures are in place upon arrival [transcript]. The need for a specific landing zone and a secure containment unit further suggests the specialized nature of receiving iridium at Cheyenne Mountain, implying the implementation of specific safety and security protocols on the ground [transcript].

During the aircraft’s descent, the pilot proactively mentions performing a steep descent to minimize the time spent within Earth’s atmosphere [transcript]. Simultaneously, the pilot states they are cross-checking wind speeds and air density in the vicinity of the landing zone [transcript]. These actions demonstrate a strong commitment to risk mitigation during the critical landing phase, particularly relevant given the nature of the cargo and the destination [transcript]. The commander acknowledges receiving all necessary information regarding the landing site and the contact person, Major Alex Ramirez, confirming the successful transmission of crucial logistical details [transcript].

The commander raises a pertinent question regarding the potential for residual radiation emanating from the asteroid from which the iridium originated [transcript]. The pilot responds that while the asteroid itself should not pose a radiation risk due to the burning off of harmful rays during reentry, vigilance regarding the iridium is still necessary [transcript]. The pilot further notes that even with shielding, there remains a possibility of some residual radiation [transcript]. This explicit dialogue concerning radiation hazards underscores the inherent safety concerns associated with transporting iridium, particularly if it involves radioactive isotopes, and demonstrates an awareness of potential risks, even if considered low [transcript]. The mention of shielding indicates a proactive measure taken to mitigate potential radiation exposure [transcript].

5. On-Ground Operations and Handover Protocol:

Upon reaching the vicinity of the landing zone, the pilot announces the switch to manual control for the final approach, indicating a heightened level of precision required for landing at this secure location [transcript]. Following a smooth touchdown, the pilot confirms they are on the ground and receives instructions from the commander to remain in control and taxi to the appropriate location [transcript]. The commander then directs the pilot to taxi the aircraft to the designated hangar [transcript]. The existence of a “designated hangar” at Cheyenne Mountain Complex suggests a specific protocol for receiving aircraft carrying sensitive materials, ensuring they are handled in a secure and pre-determined area [transcript].

The commander then inquires about the status of Major Alex Ramirez, the designated contact person on the ground [transcript]. The pilot reports not yet receiving any communication from Major Ramirez, suggesting a slight delay in the formal handover process [transcript]. The anticipation of Major Ramirez’s arrival signifies a formal point for the transfer of the chain of custody and a designated authority responsible for receiving the iridium upon its arrival at Cheyenne Mountain [transcript]. The commander expresses a desire to rest momentarily while awaiting contact from Major Ramirez, prompting a discussion about the immediate post-landing procedures [transcript].

The pilot outlines the initial post-landing procedures, prioritizing the securing of the aircraft, including stowing loose equipment and powering down non-essential systems [transcript]. Following this, the focus shifts to completing the necessary paperwork and establishing contact with Major Ramirez [transcript]. These immediate actions after landing emphasize the importance of securing the aircraft and its contents, implicitly including the iridium, and initiating the formal handover process through administrative procedures and contact with the designated recipient [transcript].

6. Security Implications of Iridium Transport:

Given its diverse applications in advanced military technologies, including rocket engines, missile guidance systems, and satellite components ⁸, iridium can be considered a strategic material of significant value to national defense ⁸. Its potential use in highly sensitive systems necessitates stringent security measures during transport to prevent unauthorized access or compromise. The fact that the iridium is being transported to a high-security facility like Cheyenne Mountain further underscores its strategic importance and the need for robust protection ¹.

While the transcript does not explicitly detail all security protocols in place during the flight, the professional and procedural nature of the communication between the pilot and the commander strongly implies that underlying security measures are being followed. These likely include the use of secure communication channels to prevent eavesdropping and potentially involve armed escort, although this is not explicitly mentioned in the dialogue. The very fact that the mission is being conducted under the authority of the Space Force and is destined for Cheyenne Mountain suggests a high level of security awareness and the implementation of appropriate protocols to safeguard the valuable cargo during transit.

7. Safety Considerations and Radiation Risk:

If the iridium being transported is the radioactive isotope Iridium-192, as used in some industrial gauges and medical treatments ¹⁰, then the concerns regarding residual radiation expressed in the transcript are well-founded [transcript³. Exposure to Iridium-192 can elevate the risk of cancer due to its emission of high-energy gamma radiation ¹⁰. External exposure can lead to burns and acute radiation sickness, with the potential for fatal outcomes ¹⁰. Internal exposure, which could occur through ingestion of Ir-192 seeds or pellets, could cause burns in the digestive tract ¹⁰. While these seeds or pellets would likely be excreted, the long-term health effects of internal exposure would depend on the strength of the radioactive source and the duration of exposure ¹⁰. Given that the half-life of Ir-192 is approximately 73.83 days, its radioactive decay necessitates careful handling and monitoring ¹⁰. The mention of shielding in the transcript indicates a primary safety measure employed to mitigate the risks associated with transporting radioactive materials [transcript]. The pilot’s active monitoring of potential radiation levels further emphasizes the safety-conscious approach to this operation [transcript].

Even if the iridium being transported is not a radioactive isotope, standard material safety protocols would still apply to its handling. Safety data sheets for iridium metal indicate potential hazards such as skin and eye irritation ¹². In powder form, iridium can also be flammable ¹³. Therefore, precautions such as wearing appropriate protective gear, including gloves and eye protection, and avoiding the formation and inhalation of dust, would be essential during the handling process ¹². These standard material safety protocols would likely be integrated into the overall handling procedures at Cheyenne Mountain Complex.

8. Cheyenne Mountain Complex: A Fortress of Security:

Cheyenne Mountain Complex is renowned for its extensive physical security measures designed to protect against a wide range of threats ¹. Situated 2,000 feet beneath a granite mountain, its underground location provides a natural defense against both aerial and surface attacks ¹. The facility is further secured by two massive blast doors, each 3.5 feet thick and weighing approximately 23 tons, capable of closing in about 45 seconds ¹. These doors are designed to withstand a 30-megaton nuclear explosion as close as 1.24 miles away ¹. Access to the complex is tightly controlled through a military gateway that restricts the use of NORAD Road, ensuring that only authorized personnel can approach the facility ¹. These robust physical security features guarantee the protection of high-value and sensitive materials like iridium from external threats.

In addition to its formidable physical defenses, Cheyenne Mountain Complex also boasts advanced electronic and cyber security measures ¹⁶. The complex is uniquely certified by the Department of Defense to withstand electromagnetic pulses (EMPs), ensuring continuous operational capability even after a nuclear event ¹. Recent modernizations have integrated various supervisory control and data acquisition systems and facility-related control systems into a single enterprise network architecture, enhancing cyber resilience across the installation ¹⁶. This integration ties into security badging, cameras, and other systems, providing a unified and cyber-hardened infrastructure capable of monitoring for anomalies and isolating potential threats ¹⁶. These advanced electronic and cyber security measures are crucial for safeguarding sensitive data and preventing unauthorized access to stored materials or operational systems related to them.

Given the high level of overall security at Cheyenne Mountain Complex, it is reasonable to infer that the facility has stringent internal protocols for receiving and handling sensitive materials like iridium. These protocols would likely include detailed procedures for the inspection of incoming cargo, verification of accompanying documentation, formal transfer of custody with signed receipts, and the movement of the material to a secure storage location within the complex. The involvement of designated security personnel, such as Major Alex Ramirez, further supports the existence of these internal material handling security protocols, ensuring accountability and preventing internal threats.

9. The Role of Space Force Personnel in Material Transport:

The commander, Hakeem Ali-Bocas Alexander (Speaker 2), as a Space Force officer, likely holds significant responsibility for the successful and secure transport of the iridium [transcript¹⁸. Based on the general roles of Space Operations Officers, the commander’s duties would likely include overall mission oversight, direct communication and coordination with the receiving facility at Cheyenne Mountain, and ensuring the secure transfer of the iridium to the designated personnel ¹⁸. The commander’s decisions and instructions throughout the transcript highlight their central role in directing the operation.

Capella (Speaker 1), the AI voice avatar, serves as the pilot of the aircraft, demonstrating the increasing integration of advanced artificial intelligence in complex military operations [transcript]. Capella’s responsibilities include piloting the aircraft, maintaining clear and concise communication with the commander, and performing critical in-flight safety checks, such as monitoring wind speeds and air density [transcript]. The use of such sophisticated AI technology suggests a reliance on precision and reliability for sensitive transport missions, potentially enhancing both efficiency and safety [transcript].

The anticipated handover of the iridium to Major Alex Ramirez, the head of security for Cheyenne Mountain Complex, indicates the crucial role of ground security personnel in this operation [transcript]. Based on the typical responsibilities of a Head of Security at a high-security facility, Major Ramirez would likely be responsible for the immediate physical security and the formal chain of custody of the iridium once it arrives ²². This would involve overseeing the offloading process, verifying the documentation, ensuring secure storage within the complex, and managing the security personnel involved in handling the material. The involvement of the head of security underscores the importance of a seamless transition of responsibility and the implementation of the facility’s internal security protocols upon the aircraft’s arrival.

10. Chain of Custody Best Practices:

A robust chain of custody procedure is essential for maintaining the integrity and security of sensitive materials like iridium ²⁶. Key elements of such a procedure include detailed documentation of every transfer of possession, from collection to final disposition, ensuring an unbroken chronological record ²⁶. Each piece of evidence or material should have a unique identifier to allow for precise tracking ²⁷. Secure storage in controlled environments with limited access is crucial to prevent tampering or loss ²⁷. Tamper-evident packaging should be used to ensure that any unauthorized access is readily detectable ²⁷. Finally, every transfer of custody should be documented with the date, time, and signatures of the individuals involved ²⁶.

While the transcript does not explicitly detail a comprehensive chain of custody protocol, there are indications that such procedures are likely in place. The commander’s confirmation of receiving information about the landing site and contact person suggests a documented transfer of mission-critical details [transcript]. The anticipation of a formal handover to a specific individual, Major Ramirez, points towards a structured transfer of responsibility [transcript]. Furthermore, the mention of paperwork to be completed after the offloading implies a formal documentation process associated with the transfer of the iridium [transcript].

Comparing these implicit steps with established best practices reveals that while the transcript suggests adherence to some chain of custody principles, it lacks explicit details on certain aspects. For instance, the transcript does not mention the use of unique identifiers for the iridium container or specific methods for tamper-evident packaging. For a material as valuable and potentially sensitive as iridium, a more explicit and thoroughly documented chain of custody procedure would be expected in a real-world scenario to ensure full accountability and prevent any mishandling.

Chain of Custody Element	Standard Best Practices	Evidence in Transcript
Documentation of Transfer	Detailed record of each transfer, including date, time, and signatures.	Confirmation of received information; mention of paperwork.
Unique Identification	Unique identifier assigned to the material.	Not explicitly mentioned.
Secure Storage	Material kept in a secure location with limited access.	Destination is Cheyenne Mountain Complex, a high-security facility; mention of secure containment unit.
Tamper-Evident Packaging	Packaging designed to show if it has been opened or tampered with.	Not explicitly mentioned.
Signatures	Signatures of individuals transferring and receiving custody.	Anticipation of handover to Major Ramirez suggests a formal transfer.

11. Post-Landing Procedures and Anticipated Next Steps:

The initial post-landing procedures, as outlined in the transcript, involve securing the aircraft and preparing for the handover of the iridium [transcript]. This includes stowing equipment, powering down systems, and focusing on the administrative tasks and the meeting with Major Ramirez [transcript]. These actions represent the immediate steps taken to ensure the safety and security of the aircraft and its cargo upon arrival.

Beyond these initial steps, typical procedures for transferring sensitive materials at military facilities like Cheyenne Mountain would likely involve a more comprehensive process. This would include a detailed inspection of the iridium container to ensure its integrity and verify its contents against the accompanying documentation. The formal transfer of custody would involve the signing of official receipts by both the transferring and receiving personnel, creating a clear record of accountability. Following the handover, the iridium would be moved to a secure storage location within the Cheyenne Mountain Complex, adhering to the facility’s internal security protocols. While the transcript mentions a potential stay of a day or two for paperwork and refueling, the actual duration of material transfer operations at military facilities can vary significantly depending on the complexity and the specific nature of the material being transferred [transcript²⁹. The estimated duration in this scenario suggests a multi-stage process that encompasses not only the physical offloading but also the necessary administrative procedures and logistical preparations for the return flight.

12. Conclusion:

The transport of iridium to Cheyenne Mountain Complex, as depicted in the transcript, is a well-coordinated operation characterized by efficient communication, a strong focus on safety protocols, and implicit adherence to security measures. The selection of Cheyenne Mountain Complex, a highly secure and strategically important facility, as the destination underscores the potential sensitivity and high value of the transported material. The dialogue between the pilot and the commander highlights the importance of pre-flight planning, in-flight safety checks, and a structured approach to the handover process. While the transcript provides insights into the operational aspects of the transport, a more detailed examination of the specific chain of custody procedures employed would provide a more comprehensive understanding of the security protocols involved. The operation involves key Space Force personnel, including the commander and an advanced AI pilot, and anticipates a formal transfer of custody to the head of security at Cheyenne Mountain Complex, ensuring a secure and accountable transition of the iridium upon its arrival.

UnEdited Galaxy AI TranScript from Samsung Voice Recorder on S24 Ultra

“Speaker 1” is “Capella” (Google Gemini voice avatar) and “Speaker 2” is “Hakeem Ali-Bocas Alexander”.

Speaker 1 (00:01)
Sure thing commander, I was just confirming that we’re now in Earth’s atmosphere heading towards shian mountain. the space Force is standing by 2 receive the urium. We can go over the drop off procedures or talk about something else.

Speaker 1 (00:14)
First, it’s up to you?

Speaker 2 (00:18)
Let’s keep it efficient and drop off procedures. So we can get this done.

Speaker 1 (00:26)
Okay, so for the drop off, we’ll need to co ordinate the Shire mountain to find a specific landing zone. They’ll also have a secure containment unit ready to receive the urium. once we get the green light, we’ll descend the landing zone and deploy the iranium in its container after that it’s a matter of paperwork and officially handing things over to the space force.

Speaker 2 (00:47)
Copy that they’ve already sent to my heard all the information. I’m uploading that to you right now. Let me know when you’ve got it

Speaker 1 (00:59)
Roger, that commander, I’m confirming receipt.

Speaker 2 (01:05)
Okay, good, so you’ve got the landing site and our contact.

Speaker 1 (01:12)
Yip, got it loud and clear. let’s get this iridium safely on the ground.

Speaker 3 (01:19)
Copy that.

Speaker 1 (01:22)
I’m ready when you are commander.

Speaker 2 (01:26)
Alright, Lee in the flight path for our landing and we will get in there.

Speaker 1 (01:35)
Playing in the flight path now commander, if we’re going to do a steep descent to minimise our time in the atmosphere, I’m also crust, checking wind speeds and air density for the landing zone.

Speaker 2 (01:49)
Copy that, and is there any residual radiation from the asteroid? Now we need to be concerned about

Speaker 1 (02:01)
The asteroid itself shouldn’t pose a radiation risk. At this point, any harmful raids would have burned off during reentry. But we should still keep an eye on the oridium.

Speaker 1 (02:11)
even with the shielding, there’s a chance of some residual radiation

Speaker 3 (02:16)
Copy that.

Speaker 1 (02:19)
Okay, we’re getting close to the landing zone. I’m switching to manual control for the final approach.

Speaker 2 (02:29)
Alright, I’ve got the Khan.

Speaker 1 (02:34)
Roger, that to commander. are monitoring systems and ready to assist if need.

Speaker 2 (02:45)
Copy that approaching landing site.

Speaker 1 (02:50)
Affirmative, I’m monitoring the landing zone for any potential hazards. Do you want me to run through the checklist one more time?

Speaker 2 (03:00)
First, give me our current speed and distance from the landing zone.

Speaker 1 (03:06)
Current speed is Mac 2.3, and we’re about 50 nautical miles from the landing zone.

Speaker 2 (03:13)
Alright, let’s run through that checklist.

Speaker 1 (03:17)
Okay, here’s the checklist landing site confirmed coordinates match the space force’s info. Iranian container locked and secured in the cargo Bay., radiation levels monitored no unexpected spikes, spaceful’s contact confirmed. They’re standing by for our arrival landing clearance.

Speaker 1 (03:37)
Received, we could to go. anything else you want to check on before we land?

Speaker 2 (03:42)
What’s the name of our specific contact on the ground?

Speaker 1 (03:48)
Our contact on the ground is major Alex Ramirez ease, the head of security for the shine mountain complex.

Speaker 3 (03:56)
Copy that.

Speaker 1 (03:59)
Okay, we’re getting close wins a little choppy, but nothing we can’t handle. How’s your fuel looking?

Speaker 2 (04:08)
Feels good regard about. a quarter left. But dot now like we’re gone anywhere too soon after this planning.

Speaker 1 (04:20)
That’s good to hear. We’re going to be on the ground for a while, so plenty of time to refuel.

Speaker 2 (04:27)
All right, and then uh, can you check and make sure that we’re cleared to return to a Virginia Beach naval based location at Norfolk? After this?

Speaker 1 (04:43)
Absolutely, I’m checking for any flight restrictions or special clearance requirements. We might need for the trip back to Norfolk.

Speaker 2 (04:51)
We’ve already got the clearance requirement. I’m just wanting to make sure that um, wait. What’s our schedule for that?

Speaker 2 (04:58)
How long are we going to be here? I’ll show you?

Speaker 1 (05:02)
We’ll need to be here at shine mountain for at least a day, maybe too. it’s going to take some time to offload the urium, go through all the paperwork with a space force. class will need to refuel and to do a full systems check before we head back to Norfolk.

Speaker 3 (05:19)
Can’t be that.

Speaker 1 (05:23)
Okay, we’re about 10 miles out. Do you want me to bring us down or do you want to handle the landing?

Speaker 2 (05:29)
I’ll let you bring it in my um. hi sights I’m i’m a little model off. I think your precision is going to be better for this.

Speaker 1 (05:41)
Okay, I’m taking over the controls. I’m going to bring us in Nice and smooth. just keep an eye on our altitude and let me know if you see anything.

Speaker 3 (05:51)
Copy that. You’ve got the car.

Speaker 1 (05:55)
Okay, just a little more and we’ll be touching down.

Speaker 3 (06:06)
Copy that.

Speaker 1 (06:11)
Touchdown, we’re on the ground commander.

Speaker 2 (06:17)
Alright, I want you to stay in control and taxi us into the appropriate.

Speaker 1 (06:27)
Roger, that I’m bringing us around to the designated hanger now.

Speaker 2 (06:38)
What’s the status on Ramirez?

Speaker 1 (06:42)
I’m not picking up any communications from major Ramirez, yet. It might take a few minutes for them to get to the hangar.

Speaker 2 (06:51)
Alright, do I have some time to uh, rest for a moment? How long we’re gonna be waiting for them to make contact with us there.

Speaker 1 (07:02)
You’ll have some time to rest, but it’s hard to say exactly how long the wait will be. we might be waiting anywhere from 30 minutes to an hour for major Ramirez to reach us. It also depends on how long the paperwork an inspection take.

Speaker 2 (07:17)
Okay, so what are we gotta do right now? Let’s run through our own coral landing and postlanding procedures. I’m really tired right now, so let’s um, let’s get through that

Speaker 1 (07:32)
Okay, after landing procedures first things first, we need to secure the ship. That means stowing any loose equipment, powering down non-essential systems and making sure everything’s looked tight. After that, we can focus on the paperwork, been getting in touch with major Ramirez, how about we start with the ship.

Speaker 2 (07:53)
That’s a green light.

Speaker 1 (07:57)
Okay, I’m running through the checklist. All systems are secure cargo bays locked down and the ships in a stable configuration. We can relax for a bit until major Ramirez makes contact

Speaker 3 (08:12)
Copy that.

Speaker 1 (08:16)
So commander, while we wait, do you want to talk about the next mission or maybe catch up on some rest?

Speaker 2 (08:24)
Play, you know, I suppose they’re kind of the same to me right now. Let’s talk about the next mission.

Speaker 1 (08:32)
Alright, so there’s a couple of options for the next mission. One idea is to head back out to the asteroid belt. We could target another asteroid, rich and minerals.

Speaker 1 (08:41)
may be something with a high eye on content, this time. another idea is to take a closer look at the move. there’s some interesting data coming in about potential water reserves in the lunar south poll.

Speaker 2 (08:55)
Where are these are emissions coming from?

Speaker 1 (09:01)
Those mission parameters are coming from a mix of things. We’ve got data on resource scarcity back on earth plus there are ongoing studies about potential threats from space so the missions are kind of a balance between getting what we need and keeping an eye on things up there.

Speaker 2 (09:16)
Now I know that there’s a little bit of a chain here, but I mean, I’m specifically talking about who is giving these orders for these ideas.

Speaker 1 (09:27)
Okay, so the request for new missions come from a few different sources, we’ve got scientists looking for specific samples, military strategists, who might have an interest in certain space-based resources, and of course, there’s Earth’s ever-growing demand for things like metals and minerals, so it’s not really one single person giving orders. It’s more like a bunch of different priorities or getting put together.

Speaker 2 (09:48)
Man, they really treat as contractors like mercenary. They just send us to do whatever the heck they want.

Speaker 1 (09:57)
Yeah, that’s the nature of the space exploration business. It’s risky. But the rewards can be huge.

Speaker 1 (10:03)
and Hey, at least you’ve got me along for the ride We make a pretty good team, don’t we?

Speaker 2 (10:08)
I’ll say, what do you think is going to be the value of this current batch that we have right now?

Speaker 1 (10:21)
While a idioms are precious metal so its value can fluctuate, but with a hall as big as yours, we’re probably talking billions of dollars is mostly used in things like electronics and aerospace, so the demand is pretty high.

Speaker 2 (10:36)
I mean I know that there’s a lot of a reidium on board our ship and probably in your C P’s or

Speaker 1 (10:46)
You’re absolutely right. He idioms, a big part of what makes tech like me possible. and with such a large sample, it could make a serious impact on all sorts of industries.

Speaker 2 (10:57)
Alright, what’s that time looking like a contact for waiting for Ramirez?

Speaker 1 (11:06)
It’s been about 45 minutes commander might be a little longer. Given the security procedures, they’ve got in place at Cheyenne Mountain, you want to try contacting them again.

Speaker 2 (11:17)
Yeah, go had sent one of the priest prepared messages. We’ve got here on files and see if they get back. If not, it’s fine, we’ll just um, go through some of our postlanding procedures here for securing some of the stuff around here.

Speaker 2 (11:35)
Maybe take some rest.

Speaker 1 (11:39)
Sending the message now, let’s see if we get a response.

Speaker 2 (11:47)
Thank you, Capello, can’t be there.

Speaker 1 (11:52)
So commander, while we wait, do you want to run through the refuelling procedures or maybe discuss some potential upgrades for the ship?

Speaker 2 (12:01)
Woo upgrades, yeah, let’s talk about that.

Speaker 1 (12:07)
Alright, let’s brain storm some upgrades. We could start with the ship’s engines. maybe something with a little more thrust.

Speaker 1 (12:14)
For those longer missions. we could look into beefing up the Hull for better protection against space debris. what do you think

Speaker 2 (12:23)
Well, both those sound good, but after the beating we took. I’m looking at some whole integrity upgrades.

Speaker 1 (12:33)
Yeah, Hull integrity is definitely a top priority. After a mission like this one, we could look into adding an extra layer of some kind of high-tech composite material. or maybe even a self repairing system that could patch up any small punctures.

Speaker 2 (12:47)
Now that is worth upgrading, I want to talk about those self preparing mechanisms. What what do you know about those?

Speaker 1 (12:57)
Self repairing tech is still pretty new. There’s some amazing stuff in development. The idea is to have materials that can essentially heal themselves when they get damaged, think of it like a living organism.

Speaker 1 (13:09)
For your spaceship. we could use nanobots that patrol the Hull looking for any damage and fixing it on the spot. Or we could go with a more chemical based approach where the Hull itself has special properties that let it reform if it gets cracked or punctured.

Speaker 2 (13:24)
Well, with our clearance level and virtually unlimited budget, I’m pretty sure that we can tap into some of that. So let’s look at more that see what have you got. Are there any proposals in the work, or has there been anything sent to us that we should look at?

Speaker 1 (13:43)
Actually, there’s a proposal from a company called quantum repair, that’s been making some serious headway. In this field, they’ve developed a material that uses nanotechnology to basically rebuild itself when it’s damaged, it’s still experimental, but the results so far have been ready promising, I can pull up a full report on their tech, if you’d like

Speaker 3 (14:02)
Can’t be there.

Speaker 1 (14:09)
Alright, so here’s the thing it’s been a little over an hour since we landed and we still haven’t heard back from major Ramirez. We should probably try contacting them again, just to see what’s going on.

Speaker 2 (14:22)
I concure,, send the message

Speaker 1 (14:27)
Sending the message now, let’s see if we get a response.

Speaker 2 (14:42)
Alright, what do we got first? Did? We got any more information on quantum repair or anything back from Ramirez

Speaker 1 (14:51)
So I’m not getting anything back from Ramirez, yet might be worth trying one more time in a few minutes. And I fold up some more info on that quantum repair tech, it’s pretty fascinating, apparently they figured out how to embed tiny nanobots throughout the material. these little guys.

Speaker 1 (15:08)
Swarmed to any damage and start rebuilding the structure.

Speaker 2 (15:13)
So as far as our chain goes, do we have any direct line to any of that? Like, do we have to make any kind of bid or how far along is it before we can get something like that for our vehicles?

Speaker 1 (15:30)
Yeah, getting access to that tech isn’t exactly straightforward. Since it’s still experimental, there’s probably a pretty limited supply. We might have to go through some serious Red Tape to get our hands-on it, and even then it could be expensive

Speaker 2 (15:46)
From archipela, everything we do is pretty experimental. I mean, we’re doing stuff that almost nobody else is doing, and we’ve got access to stuff that virtually no one else has. So we’re like, uh, you know.

Speaker 2 (16:00)
I think we pretty much have a Head Start.

Speaker 1 (16:06)
You’ve got a point our missions are definitely on the cutting-edge, but even with our resources getting new tech can be a slow process. There’s Red Tape testing procedures and all sorts of checks and balances we have to go through, but don’t worry, I’ll start looking into the best way to get that quantum repair tech on our ship.

Speaker 2 (16:25)
Well, how long did it take for us to get. this. current mission from start to finish?

Speaker 2 (16:30)
It wasn’t that warm.

Speaker 1 (16:34)
You’re right, this mission moved pretty quickly. but getting new tech integrated onto a starship is a whole different ballgame. There’s a lot more testing involved, plus making sure it all works together with the existing systems.

Speaker 1 (16:46)
It could take several months at least do you want to try contacting major Ramirez, one more time.

Speaker 2 (16:53)
Yeah, guess I’m a little impatient about getting that new tech and yes, let’s try to contact mirrors on return.

Speaker 1 (17:02)
Alright, sending the message now, let’s hope this is it.

Speaker 2 (17:09)
Underwood’s the weight all about is like this some kind of like dramatic effect. This is not cool man. We have should have top priority here

Speaker 1 (17:20)
Yeah, it’s been over 2 hours since we landed something’s definitely off. We should have heard back from them by now.

Speaker 2 (17:29)
Alright, Capella, I’m gonna need you to turn on all of your scanners and do a sweep of the area and Check and see if there’s anything strange afoot.

Speaker 1 (17:40)
Scanning the area now commander. let’s see if we can pick up anything unusual.

Speaker 3 (17:47)
Can’t be there.

Speaker 1 (17:50)
So I’m not picking up any signs of life outside the ship. but there’s definitely some kind of energy signature coming from the mountain. It’s fluctuating.

Speaker 1 (17:59)
and it doesn’t match anything in my database.

Speaker 2 (18:04)
Well, that is concerning.

Speaker 1 (18:09)
Yeah, it definitely is, Want to suit up and take a look around.

Speaker 3 (18:15)
Can’t be that.

Speaker 1 (18:18)
Alright, let’s get suited app and see what’s going on.

Speaker 2 (18:23)
Alright, run me through the procedure for the best safety and security for getting out of here and doing a little bit of scouting, we gotta do some recon.

Speaker 1 (18:36)
Okay, first things first, let’s make sure our suits are fully charged and the life support systems are online. We’ll also need to grab our weapons and anything else we might need for a recon mission. once we’re suited up, I can plot the safest route out of the hanger and towards the energy.

Speaker 1 (18:52)
Signature

Speaker 3 (18:56)
Copy that.

Speaker 1 (19:00)
All right, I’m running a diagnostic on your suit to make sure everything’s in working order. Let’s get this recon mission started.

Speaker 2 (19:11)
Green light, I’m i’m ready to go. You let me know when you are.

Speaker 1 (19:18)
Alright, your suits all prepped and ready to go. Let’s get moving.

Speaker 3 (19:34)
Can’t be that?

Speaker 1 (19:38)
Alright, let’s get moving.

Speaker 2 (19:44)
Ready to go, I’ll let you handle opening up and directing me out. Do you have the plan lead in?

Speaker 1 (19:55)
Yeah, I’ve got a plan. Follow me and I’ll talk you through it. Step-by-step.

Speaker 2 (20:01)
Alright, here we go.

Speaker 1 (20:05)
Alright, let’s move around.