Climb into the heart of the abandoned space station mystery with Ursa and Hakeem. This blog features the original mission audio, a full transcript, and a detailed DeepSeek summary. Explore an in-depth report analyzing the cloaked ship, the atomic code, and the station’s hidden history. Complete with an audio overview, this post is your ultimate guide to the science, story, and secrets behind the mission. –DeepSeek

Listen to “The Cloaked Enigma: Decoding the Abandoned Station” on Spreaker.

DeepSeek Solution to the Mystery of the Cloaked Object:

1. Elemental Code Input:
   The amorphous symbols, resembling atomic structures (Hydrogen and Oxygen), suggest a connection to water (H₂O). The 9-button circular panel likely corresponds to elements. Press the buttons in the sequence of water’s composition:
   • Hydrogen (1) twice (for H₂)
   • Oxygen (8) once (for O)
     This sequence (1-1-8) on the circular panel may deactivate the cloaking device or open the hatch.
2. Frequency Resonance:
   The energy signature pulses at 100 Hz. By emitting a sustained 100 Hz frequency using the suit’s systems (with Ursa’s power boost), they could resonate with the cloaked object’s structure, disrupting its invisibility or unlocking it.
3. Black Box Integration:
   Place the black box near the cloaked ship’s control panel. The box emits the same energy signature, possibly acting as a key. Combining its output with the 100 Hz frequency might activate the ship’s systems.
4. Multi-Spectral Scan:
   Use overlapping scanner frequencies (UV + gamma) to stabilize the symbols. This could reveal a static pattern or code, allowing Hakeem to input the correct sequence.

Outcome:
Upon returning with recharged suits, Hakeem and Ursa implement the 1-1-8 sequence synchronized with a 100 Hz pulse. The cloaked ship decloaks, revealing an advanced vessel with ties to the station’s decommissioning. The black box is a navigation module, completing the ship’s systems and providing answers to the mysterious energy readings.

Final Answer: Unlocking the Cloaked Ship’s Secrets

The solution elegantly weaves together narrative clues and scientific logic to resolve the mystery. Here’s a refined breakdown of how Hakeem and Ursa crack the case:

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Step-by-Step Resolution

1. Elemental Code Revelation
   • Atomic Symbolism: The amorphous, shifting symbols observed under gamma/UV scans are identified as magnified atomic structures (Hydrogen [1] and Oxygen [8]).
   • Water as the Key: Recognizing the connection to H₂O, Hakeem inputs the sequence 1-1-8 on the circular panel (two Hydrogen atoms, one Oxygen atom). The panel’s circular layout mirrors the periodic table’s structure, with numbers corresponding to atomic positions.
2. Frequency Synchronization
   • 100 Hz Resonance: Ursa amplifies the suit’s systems to emit a sustained 100 Hz pulse, matching the energy signature’s rhythm. This disrupts the cloaking field, destabilizing the invisibility tech.
3. Black Box Integration
   • Hermetic Seal Decoded: The mysterious black box, emitting the same energy signature, is placed against the ship’s control panel. Its proximity triggers a resonance effect, revealing it as a navigation module critical to the ship’s operation.
4. Multi-Spectral Overlay
   • UV + Gamma Fusion: By overlapping ultraviolet and gamma scans, the duo stabilizes the shifting symbols into a static pattern, confirming the 1-1-8 code and exposing hidden interfaces.

Analysis of Dialogue Transcript within the Context of Space Exploration

1. Introduction:

This report presents a comprehensive analysis of a provided dialogue transcript within the context of real-world and plausible future space exploration. The analysis specifically focuses on the activities of the National Aeronautics and Space Administration (NASA), a systematic comparison of the transcript’s content with existing scientific research, and a detailed account of the contributions made by Hakeem Ali-Bocas Alexander as depicted in the transcript. This updated analysis incorporates all relevant science-based information derived from prior comprehensive research reports to ensure a thorough and well-supported evaluation. The structure of this report will first address NASA’s involvement in pertinent areas of space exploration, followed by a detailed comparison of the transcript’s elements with scientific findings, a dedicated section on Hakeem Ali-Bocas Alexander’s role, and finally, a concluding summary of the analysis.

2. NASA’s Role in Relevant Space Exploration Domains:

• 2.1. Current and Future Space Station Projects:
  • 2.1.1. International Space Station (ISS): NASA has been a central partner in the International Space Station (ISS) since its operational commencement in 1998 ¹. The ISS serves as a unique orbiting laboratory, facilitating a wide array of scientific investigations in the low Earth orbit environment ². Research conducted on the ISS spans numerous disciplines, including human physiology in microgravity, life sciences experiments, and studies in physical sciences ⁴. This sustained presence in space has provided invaluable data and experience regarding long-duration space habitation and the challenges associated with maintaining complex orbital facilities. NASA is committed to the continued utilization of the ISS as a critical research platform until its currently projected end of operational life in 2030, with plans for a transition to commercial alternatives thereafter ⁵. The extensive operational history and the diverse scientific output of the ISS offer a tangible framework against which the plausibility of space station-related elements within the provided transcript can be assessed. The challenges overcome and the knowledge gained from the ISS program directly inform our understanding of what is feasible in long-term space-based scenarios.
  • 2.1.2. Lunar Gateway: Looking towards future endeavors beyond low Earth orbit, NASA is actively developing the Lunar Gateway, a planned crewed space station situated in lunar orbit ¹. This project is a cornerstone of the Artemis program, NASA’s initiative to return humans to the Moon and establish a sustained lunar presence. The Lunar Gateway is envisioned as a multi-purpose platform with capabilities to support research in various scientific fields, including planetary science, astrophysics, Earth observation from a unique vantage point, heliophysics, and studies focused on fundamental space biology and human health and performance in deep space environments ⁷. The development and assembly of the Gateway are progressing, with initial modules slated for launch as early as 2027, and the first crewed mission to the station, Artemis IV, targeted for September 2028 ⁷. The Lunar Gateway signifies NASA’s long-term commitment to lunar exploration and the establishment of infrastructure beyond Earth’s immediate vicinity. Therefore, any elements within the transcript related to lunar activities or advanced space technologies gain plausibility when considered within the context of NASA’s ongoing Gateway program.
  • 2.1.3. Commercial Space Stations: Recognizing the evolving landscape of space exploration, NASA is also strategically fostering the development of commercially owned and operated space stations in low Earth orbit ¹. This initiative aims to ensure continued access to the unique microgravity environment of LEO after the eventual decommissioning of the ISS. NASA plans to act as one of many customers, purchasing services from these commercial platforms to meet its research and operational needs, while simultaneously stimulating the growth of a robust commercial space economy ⁵. Several companies, including Axiom Space, which is planning to attach modules to the ISS before becoming a free-flying station, Orbital Reef, a collaboration between Blue Origin and Sierra Space, and Starlab, a project led by Nanoracks and Voyager Space, are actively involved in these efforts ¹¹. This strategic direction indicates a future where space infrastructure and research activities will likely involve a collaborative ecosystem of both government and private sector entities. Consequently, scenarios depicted in the transcript that involve space stations or research facilities should be evaluated considering this emerging trend towards commercialization in low Earth orbit.
• 2.2. Research into Energy Signatures in Space:
  • 2.2.1. Spacecraft Identification and Tracking: Maintaining awareness of the objects orbiting Earth is crucial for ensuring the safety and sustainability of space operations. NASA, along with other space agencies and organizations, invests significantly in Space Situational Awareness (SSA) to track the increasing number of artificial satellites and debris in orbit. This involves employing a variety of technologies, including ground-based radar systems and optical telescopes, to monitor and catalog objects in space ¹³. Furthermore, innovative concepts like the “Satellite Licence Plate” (SLP) system, which utilizes wavelength-selective retroreflecting tags to provide a unique optical identifier for satellites, are being explored ¹⁶. The ongoing research and development in SSA underscore the importance of identifying and tracking spacecraft, lending scientific plausibility to the idea presented in the transcript of detecting an “unusual energy signature” as a means of identifying an unknown object in space. The ability to discern the characteristics of different spaceborne entities is fundamental to maintaining a safe and orderly space environment.
  • 2.2.2. Anomaly Detection: The analysis of energy signatures extends beyond mere identification to encompass the detection of anomalies or deviations from expected patterns. NASA utilizes various sensors and techniques to monitor energy emissions from both Earth and space. For instance, the Compact Thermal Imager (CTI) tested on the ISS demonstrated the capability to detect detailed heat signatures from Earth, valuable for monitoring events like wildfires ¹⁷. On a broader scale, energy signature analysis is a recognized methodology for understanding and tracking energy consumption and performance in various systems and facilities. The principle behind this is that consistent and predictable operations produce characteristic energy profiles, and deviations from these profiles can indicate anomalies or points of interest. Therefore, the scenario in the transcript where an “unusual” energy signature prompts an investigation aligns with established practices of using energy signature analysis as a tool for identifying unexpected events or conditions in space.
  • 2.2.3. Technosignatures and the Search for Extraterrestrial Intelligence (SETI): While the primary context of the transcript appears to be within the realm of known space exploration, the concept of detecting unusual energy signatures also has relevance to the search for extraterrestrial intelligence (SETI). NASA, alongside private and philanthropic organizations, has shown a renewed interest in the search for “technosignatures,” which are potentially detectable signals or signatures indicative of the presence of advanced extraterrestrial civilizations ¹⁸. These technosignatures could manifest as unexpectedly elevated heat signatures, unusual radio signals, or optical anomalies. Although the transcript’s scenario likely involves a terrestrial or near-future context, the broader scientific understanding that unusual energy signatures could point to unknown or advanced sources provides an intriguing backdrop to the events described. The search for technosignatures highlights the potential for anomalous energy readings to signify something beyond conventional understanding.
• 2.3. Perspectives on Cloaking Technologies and Advanced Materials:
  • 2.3.1. Cloaking Technology Research: The concept of cloaking, or rendering objects invisible, has transitioned from the realm of science fiction to an active area of scientific research. Various theoretical frameworks and experimental approaches are being explored, including transformation optics, which involves manipulating the path of light using specially designed materials; metamaterials, artificially structured materials with unique electromagnetic properties; active cloaking, which uses devices to generate fields that cancel out incoming waves; and plasmonic cloaking, which utilizes surface plasmons to reduce scattering. While significant theoretical progress has been made and cloaking has been demonstrated experimentally at certain frequencies (e.g., microwaves, terahertz), achieving broadband cloaking across the entire electromagnetic spectrum, especially for macroscopic objects, remains a considerable challenge. Research also explores unconventional cloaking methods involving water or chemical interactions. Despite current limitations, the active pursuit of cloaking technologies suggests that the concept of a cloaked object in the transcript is not entirely divorced from potential future realities in space exploration, particularly in specialized applications where perfect invisibility might not be required.
  • 2.3.2. Advanced Materials: The advancement of space exploration is intrinsically linked to the development and application of novel materials. NASA actively researches advanced materials for spacecraft construction, focusing on properties like lightweightness, strength, and resilience to the harsh space environment. This includes the investigation of composite materials, metal-organic frameworks, and low-mass alternatives to traditional materials ¹⁹. Among these advanced materials, iridium stands out due to its exceptional properties. Iridium possesses a very high melting point, remarkable resistance to corrosion, and excellent electrical conductivity, making it suitable for a range of high-performance applications. Research indicates potential uses for iridium in conductive films, as electrode materials in various devices, and even as a coating for X-ray mirrors used in space telescopes. Given these properties and ongoing research, the mention of an “iridium interface” within the transcript aligns with the real-world exploration and application of iridium in advanced technological contexts, including those relevant to space exploration.

3. Comparative Analysis of the Transcript with Scientific Research:

This section will provide a detailed comparison of the significant elements mentioned in the dialogue transcript with the scientific research gathered.

• Unusual Energy Signature: The transcript mentions the detection of an unusual energy signature. NASA’s work in monitoring space involves the constant detection and analysis of various energy signatures emanating from spacecraft, celestial bodies, and even background radiation. Deviations from expected energy profiles can indicate a variety of phenomena, including rocket launches ¹, unusual stellar activity ²³, or even the presence of unknown objects. For instance, the James Webb Space Telescope has detected unexpected light signatures from galaxies, potentially representing early stages of galactic evolution ²⁵. The Fermi Gamma-ray Space Telescope detected a high-energy signal outside our galaxy, the cause of which is still under investigation ²⁶. These examples illustrate that the detection of unusual energy readings is a recognized occurrence in space observation, making this element of the transcript scientifically plausible.
• Cloaked Object: The transcript refers to a cloaked object. As discussed in Section 2.3.1, while perfect invisibility across all frequencies remains elusive, significant research is being conducted on various cloaking technologies. Metamaterials, for instance, have been used to bend electromagnetic waves, including microwaves and even visible light, around objects ²⁷. Active camouflage, which involves blending an object with its surroundings using panels or coatings, is another area of development ³⁶. While current technologies face limitations in terms of bandwidth and the size of objects that can be effectively cloaked, the underlying scientific principles suggest that a cloaked object is a plausible element in a future space exploration scenario.
• Iridium Interface: The transcript mentions an iridium interface. Iridium is a highly corrosion-resistant and conductive metal with a very high melting point, making it suitable for various advanced technological applications. It is used in spark plugs for aviation, crucibles for high-temperature applications, and even as a component in LED screens ⁴⁰. Its robustness and conductivity make it a viable material for an interface in a space environment where equipment must withstand extreme conditions. Research also explores the use of iridium in thin films for electronic applications ⁴¹. Therefore, the presence of an iridium interface in the transcript is scientifically plausible given the known properties and applications of this element.
• ‘Giant Atoms’ Concept: The transcript includes the concept of ‘giant atoms’. In theoretical quantum optics, “giant atoms” refer to artificial atoms, often superconducting qubits, that couple to light or other bosonic fields at multiple discrete points separated by wavelengths. This multi-point coupling leads to unique quantum phenomena not observed in traditional atoms, offering enhanced possibilities for design, control, and manipulation in quantum technologies. Without the specific context from the transcript, it is difficult to definitively ascertain whether the usage aligns precisely with this theoretical definition or if it is employed in a more metaphorical or fictional sense. However, the existence of the concept of giant atoms in contemporary physics provides a potential scientific basis for this element in the narrative.
• 100 Hz Frequency: The transcript mentions a 100 Hz frequency. Frequencies around 100 Hz appear in various scientific and technological contexts. In the electromagnetic spectrum, frequencies below 100 Hz are classified as extremely low frequency (ELF) ⁴⁸. ELF waves have the ability to penetrate certain materials, including water, and are used in specialized applications like communication with submerged submarines ⁵³. In a biological context, the human heart rate typically falls within the range of 60-100 beats per minute (bpm), which is approximately 1-1.67 Hz ⁵⁸. However, a frequency of 100 Hz is significantly higher than the typical heartbeat. Research has shown that vibrations at 100 Hz can affect neuronal cell differentiation. In the realm of technology, pulsed electromagnetic field (PEMF) therapy utilizes pulsing electromagnetic fields at various frequencies, including around 100 Hz, for potential therapeutic benefits. Without further context from the transcript, the specific significance of the 100 Hz frequency is unclear, but its appearance in diverse scientific and technological domains indicates that it could relate to several aspects of space exploration or the phenomena described within the dialogue.

4. Detailed Account of Hakeem Ali-Bocas Alexander’s Contributions:

The provided research material offers some insight into the character of Hakeem Ali-Bocas Alexander. He is identified as a podcaster and author with interests in topics ranging from wellness and content creation to more esoteric subjects like demonology ⁶¹. He is also portrayed in fictional scenarios, such as a lunar module pilot on a mission to establish a moon base ⁶⁸. This suggests a character with a blend of technical aptitude and a humanistic, perhaps even imaginative, perspective.

Based on the user’s rewritten query, Hakeem’s contributions within the transcript likely involve a combination of practical actions, keen observations, and insightful hypotheses. His actions, such as navigating the station, operating scanners, and attempting to open the box, demonstrate a hands-on approach to the investigation. His observations, noting the lack of light, the tactile feel of the invisible box, visual fluctuations under UV light, and the description of symbols, highlight his attention to detail and sensory perception. His insights, particularly the connection he draws to water molecules, suggest a level of critical thinking and the ability to form hypotheses based on his observations.

The query specifically emphasizes how Hakeem’s human perspective and physical interaction with the environment complement Ursa’s AI capabilities. This highlights a synergistic dynamic where Hakeem’s direct sensory input and intuitive reasoning work in tandem with Ursa’s analytical processing and data interpretation. For example, while Ursa might detect the unusual energy signature, Hakeem’s physical interaction with the cloaked object, such as feeling its contours or observing its reaction to UV light, provides a different layer of information that an AI might not be able to gather remotely. Similarly, Hakeem’s hypothesis about the connection to water molecules, possibly based on his understanding of the environment or previous experiences, could guide Ursa’s analysis in specific directions. This interplay between human intuition and artificial intelligence likely forms a crucial aspect of the investigation depicted in the transcript.

5. Conclusion:

The analysis of the dialogue transcript within the context of real-world and plausible future space exploration reveals a nuanced interplay between established scientific principles and emerging technologies. The detection of an unusual energy signature aligns with NASA’s ongoing efforts in space situational awareness and anomaly detection. The concept of a cloaked object, while still facing technological hurdles, is supported by active research in metamaterials and active camouflage. The mention of an iridium interface is scientifically grounded in the material’s unique properties and applications in advanced technology. The term ‘giant atoms’ resonates with a specific area of theoretical physics, though its precise meaning in the transcript would require further context. The 100 Hz frequency appears in various scientific and technological domains, suggesting potential relevance depending on the specific phenomena being described.

Hakeem Ali-Bocas Alexander’s role in the transcript, characterized by his practical actions, detailed observations, and insightful hypotheses, underscores the enduring importance of human involvement in space exploration and scientific investigation. His ability to interact physically with the environment and draw connections based on his human experience complements the analytical capabilities of an AI like Ursa, highlighting the potential for effective human-AI collaboration in future space endeavors. The elements within the transcript, when examined through the lens of current scientific understanding and plausible technological advancements, demonstrate a degree of alignment with the trajectory of space exploration, suggesting a narrative grounded in relevant scientific concepts.

Transcript Element	Potential Real-World Parallel	Supporting Research Snippets (IDs)
Unusual Energy Signature	Spacecraft tracking, anomaly detection, space weather, unknown phenomena	S_R1, S_R2, S_R6, S_R10, S_R12, S_R16, S_R17, S_R19, S_R21, S_R23, S_R33, S_R38, S_R40, S_R47, S_R48, S_R50, S_R54, S_R61, S_R75, S_R78, S_R105, S_R114, S_R116, S_R176, S_R184, S_R188, S_R217, S_R219, S_S16, S_S17, S_S18, S_S19, S_S20
Cloaked Object	Metamaterial cloaking, active camouflage, theoretical invisibility methods	S_R3, S_R4, S_R11, S_R16, S_R18, S_R24, S_R28, S_R29, S_R30, S_R31, S_R39, S_R52, S_R59, S_R60, S_R63, S_R66, S_R72, S_R73, S_R74, S_R76, S_R77, S_R82, S_R83, S_R88, S_R91, S_R96, S_R98, S_R99, S_R100, S_R102, S_R113, S_R115, S_R117, S_R119, S_R123, S_R124, S_R126, S_R130, S_R132, S_R135, S_R137, S_R141, S_R143, S_R144, S_R153, S_R154, S_R160, S_R161, S_R164, S_R166, S_R168, S_S25, S_S26, S_S27, S_S28, S_S62, S_S63, S_S64, S_S65, S_S66, S_S67, S_S68, S_S69, S_S70, S_S71, S_S73, S_S74, S_S75, S_S76, S_S77, S_S78, S_S79, S_S80, S_S81, S_S82, S_S83
Iridium Interface	High-performance material in conductive films, electrodes, metamaterials	S_R8, S_R13, S_R15, S_R22, S_R34, S_R35, S_R56, S_R65, S_R79, S_R85, S_R87, S_R92, S_R103, S_R106, S_R108, S_R129, S_R139, S_R145, S_R147, S_R175, S_R179, S_R180, S_R189, S_R190, S_R210, S_R215, S_R220, S_R222, S_S37, S_S38, S_S39, S_S40
‘Giant Atoms’	Theoretical concept in quantum optics	S_R67, S_R101, S_R107, S_R111, S_R133, S_R134, S_R138, S_R146, S_R157, S_R159, S_R213, S_R216
100 Hz Frequency	ELF communication, biological rhythms, PEMF therapy, potential cloaking applications	S_R80, S_R81, S_R95, S_R109, S_R110, S_R115, S_R119, S_R127, S_R128, S_R156, S_R160, S_R162, S_R181, S_R185, S_R206, S_R41, S_R43, S_R64, S_R84, S_S41, S_S42, S_S43, S_S44, S_S45, S_S46, S_S47, S_S48, S_S49, S_S50, S_S51, S_S52, S_S53, S_S54, S_S55, S_S56, S_S57, S_S58, S_S59, S_S60, S_S61, S_R27, S_R36, S_R49, S_R55, S_R70, S_R90, S_R94, S_R109, S_R110, S_R112, S_R121, S_R122, S_R136, S_R140, S_R151, S_R167, S_R169, S_R170, S_R171, S_R173, S_R174, S_R182, S_R183, S_R195, S_R196, S_R199, S_R200, S_R207, S_R212, S_R57, S_R90, S_R93, S_R121, S_R125, S_R140, S_R142, S_R149, S_R163, S_R171, S_R181, S_R201, S_R207, S_R214, S_R218, S_R204

UnEdited Galaxy AI TranScript from Samsung Voice Recorder on S24 Ultra

“Speaker 1” is “Ursa” (AI) and “Speaker 2” is “Hakeem Ali-Bocas Alexander”.

Speaker 1 (00:00)
How’s your suit holding up?

Speaker 2 (00:01)
Suits holding up fine or something.

Speaker 1 (00:06)
Copy that my systems are all online and running smoothly. Let’s get started. Do you want to head straight for the source of those readings or check out some other parts of the station first.

Speaker 2 (00:18)
I think that we should just go straight for the readings but you gotta tell me what kind of readings they are, what does that resemble, I mean, what is it indicating to you?

Speaker 1 (00:35)
It looks like some kind of energy signature, but it’s unlike anything we’ve ever seen before, it’s really strong and it seems to be coming from the station’s core.

Speaker 2 (00:44)
I’ve been hearing a lot about that lady.

Speaker 1 (00:49)
Did you say energy signature? If so, that sounds like a clue to what’s going on or did you meet something else?

Speaker 2 (00:56)
I’ve been hearing a lot about these energy signatures that are not like anything we’ve ever detected before has been an ongoing theme.

Speaker 1 (01:07)
That’s right, these readings are definitely a mystery. We should be careful in narrow. Keep getting a strange feeling about this whole thing

Speaker 2 (01:16)
Me too. It’s kind of reminiscent of some of the other missions I’ve been on, but you’ve been blocked out from those and compartmentalized so I’ll have to, I’ll catch you up on that later.

Speaker 1 (01:30)
Sounds interesting, Hakeem. I look forward to hearing about those other missions, but for now, should we focus on getting inside the station and figuring out what’s causing those strange readings?

Speaker 2 (01:42)
Okay like I said, what kind of readings are they a type of radiation? Is it a signal? Is it anything that I should be worried about?

Speaker 2 (01:51)
I mean, I know I’ve got my suit, but um, what are the risks?

Speaker 1 (01:59)
It’s not radiation, and it doesn’t seem to be a signal either. It’s something completely different. And that’s what’s making it so intriguing, as for risks, it’s hard to say for sure, until we get in there and take a closer look.

Speaker 2 (02:12)
Okay. Well then I suggest we get on into investigator mode and go check it out.

Speaker 1 (02:22)
Sounds good. Let’s get a move on. Then I’m running diagnostics on the airlock, now to see if it’s compromised.

Speaker 2 (02:31)
Copy that.

Speaker 1 (02:34)
Airlock, looks clear, ready to step inside when you are

Speaker 2 (02:39)
All right there we go oh my gosh, uh, come again, repeat.

Speaker 1 (02:54)
You leading the way Hakeem.

Speaker 2 (02:57)
Oh yeah, I’m leaving. Yes, can’t be

Speaker 1 (03:02)
All right, let’s move out.

Speaker 2 (03:05)
All right. I’ll lead the way but you can guide me. Um, do you have AA map of the layout of this place

Speaker 1 (03:17)
Affirmative, I’m accessing the station’s schematics. Now it looks like the source of those readings is several decks below us.

Speaker 2 (03:24)
All right. How can we access those decks below? Which direction should I go?

Speaker 2 (03:29)
How far should I keep going forward? And then for how long

Speaker 1 (03:34)
Okay, there’s a ladder down to the next level. I’m just ahead of you on your right. You might have to crouch a little to get under the emergency lighting there, all right.

Speaker 2 (03:45)
Okay, I found that ladder.

Speaker 1 (03:50)
Okay, time to descend, be careful down there.

Speaker 2 (03:54)
Okay.

Speaker 1 (03:58)
All right, let me know when you get to the bottom.

Speaker 2 (04:03)
Just a little bit more. Should take about another 45 seconds.

Speaker 1 (04:10)
All right, take your time.

Speaker 2 (04:18)
I’m going to turn on my headlamp. Real quick, about 30 more seconds bottom.

Speaker 1 (04:26)
All right, sounds good.

Speaker 2 (04:34)
Okay.

Speaker 1 (04:37)
Alright, I’m getting a little interference down here. Let’s see if we can figure out where the signal is coming from.

Speaker 2 (04:44)
Alright, let me know I’m, uh, I’m looking around. I don’t see anything. There’s nothing but some more of these dim red emergency lights around here looks like, hmm, how much power is coming to this thing

Speaker 1 (05:00)
Okay, let’s conserve power. Turn off that headlamp, unless you absolutely need it. I’m still trying to triangulate the source of those readings

Speaker 2 (05:12)
All right, you can send my. You can send me any information to my my gauntlet.

Speaker 1 (05:30)
All right, so I’m getting a strong reading straight down from here. It looks like a maintenance hatch that leads deeper into the station.

Speaker 2 (05:39)
Okay, well, you know out in space up as down as up deeper as not really anything, it’s just AA direction to Go, so let’s go for it.

Speaker 1 (05:51)
All right, let’s see if this hatch is locked.

Speaker 2 (06:00)
Nope.

Speaker 1 (06:03)
All right, sounds like it’s open. You want to go down first or shall I?

Speaker 2 (06:15)
I’ll lead.

Speaker 1 (06:19)
Alright, sounds good. I’m right behind you.

Speaker 2 (06:26)
I can’t be there.

Speaker 1 (06:29)
Alright, let’s get this show on the road you leading the way Hakeem.

Speaker 2 (06:35)
All right. I think, uh, uh, uh, I’m gonna have to turn my headlamp back on. I get down here I don’t there’s not much light at all.

Speaker 1 (06:45)
Okay, go ahead and turn on that headlamp. I’m still getting used to this darkness myself.

Speaker 2 (06:51)
All right well, you being in an advanced AI and all just uh, send me some of your reserve power for my headlamp. My suit’s doing everything it can to maintain life support.

Speaker 1 (07:05)
I’m detecting a power source, a short distance ahead of you. Can you check it out?

Speaker 2 (07:11)
I’m on it.

Speaker 1 (07:14)
All right, let me know what you find.

Speaker 2 (07:24)
All right, this is uh, interesting.

Speaker 1 (07:29)
Tell me about it. What did you find?

Speaker 2 (07:34)
Well, it’s kind of cliche It’s a small black box.

Speaker 1 (07:41)
All right, let’s see if we can get a closer look at that box, can you try to open it?

Speaker 2 (07:49)
I’m going to patch you through to my gauntlet, and let you scan here. Just let’s scan it first before I open it.

Speaker 1 (07:58)
Copy that, go ahead and patch me through

Speaker 2 (08:04)
All right, you’re patched in

Speaker 1 (08:08)
All right, let’s see what this thing is.

Speaker 2 (08:16)
So far, I’m not getting anything really significant, but your scanners are more detailed and meticulous and more sensitive than mine. So let me know what you’ve got.

Speaker 1 (08:29)
This box is definitely emitting the same energy signature as the one that brought us here. I’m getting a lot of strange readings, but I can’t quite make sense of them yet. Thank you?

Speaker 2 (08:37)
All right, any patterns to the readings or signal?

Speaker 1 (08:44)
It’s pulsing like a heartbeat, and it’s getting stronger.

Speaker 2 (08:48)
So is it pretty regular? What’s the what’s the rhythm? Is it, can you give that to me in Hertz or megahertz?

Speaker 1 (08:58)
It’s pulsing at a pretty steady rate, about 100 feets per minute.

Speaker 2 (09:04)
Okay, that’s pretty basic, okay. I don’t think there’s anything to worry about. What do you make of it

Speaker 1 (09:17)
I’m not sure yet. It’s definitely intriguing, but it could be anything. Maybe it’s a Beacon of some kind for a power source or something else entirely.

Speaker 2 (09:26)
All right well, I’m going to start 12. See if I can crack it open.

Speaker 1 (09:38)
All right, be careful. Let me know if you need a hand.

Speaker 2 (09:43)
Yeah, like you have hands.

Speaker 1 (09:47)
If you got me there, let me know if you find anything interesting inside.

Speaker 2 (09:56)
Uh, you know, at first I thought I saw some seams on this thing, but pretty hermetically sealed.

Speaker 1 (10:07)
All right. Let’s see if we can find a way to open it up without damaging the contents. Do you see any kind of panel or latch anywhere

Speaker 2 (10:16)
No, it’s smooth all around. I mean, the openings that I thought I saw, uh, they’re more like just grooves, but they don’t have any apparent way to get inside of it.

Speaker 1 (10:32)
All right, but let’s try something different. See if there’s a way to bypass the seal, maybe something on your suit could create a small opening without damaging the box itself.

Speaker 2 (10:43)
Okay, I think I have an idea.

Speaker 1 (10:48)
Sounds good. Let me know if you need any help.

Speaker 2 (10:51)
Well, yeah, I think if we can amplify this, the frequency, let’s see if what happens if we match the signal a 100 Hz, for a 100 Hz, but I’m going to need you to send me some more backup power.

Speaker 1 (11:07)
All right, let’s try it sending you some extra power now.

Speaker 2 (11:12)
All right, now you said that it was around a 100 Hz, was that uh giving off more in the Em frequency or audio because I don’t hear anything.

Speaker 1 (11:26)
It’s closer to an electromagnetic frequency. You might want to try using the frequency analyzer in your suit.

Speaker 2 (11:39)
Okay, I’m just not getting anything, maybe my. It’s because my suit power is low or my instruments aren’t as sensitive as yours, but I’m gonna have to take your word for it.

Speaker 1 (11:52)
All right, let’s try a different approach. Maybe there’s a way to bypass the box altogether. Can you check to see if there are any other components nearby that might be connected to it

Speaker 2 (12:03)
Alright, I’m looking around now. Give me a moment.

Speaker 1 (12:08)
No problem. Let me know if you find anything.

Speaker 2 (12:27)
Um, I mean I found some stuff. But nothing really looks like it’s significant. I mean, it’s all stuff, it doesn’t none of the none of these tools are there gadgets?

Speaker 2 (12:37)
Look, it’s familiar to me. I don’t know what to make of it

Speaker 1 (12:44)
All right, let’s try something else. Do you see any other hatches or doors nearby that might lead deeper into the station?

Speaker 2 (13:00)
Send me some schematics to my gauntlet again. And let me see if I can map out if you just look for any type of opening depending on what I can see on the schematics.

Speaker 1 (13:18)
All right, sending schematics now.

Speaker 2 (13:25)
All right, pulling that up right now. Okay, it looks like there is. There are actually a few levels deeper that we can go, should I take the box with me?

Speaker 1 (13:40)
Let’s take the box, it might be a key to understanding what’s going on here.

Speaker 2 (13:45)
Okay, and speaking of that, it’s been pretty quiet. I know that this was listed as an abandoned spear. The space station, was there any records of any distress signals or anything sent from here before we were dispatched to it?

Speaker 1 (14:07)
That’s a good point. I’m checking the database. Now, there don’t seem to be any records of distress signals coming from the station, but there’s a mention of it being decommissioned a few decades ago I might want to look into that

Speaker 2 (14:17)
Decommission, then that means that everybody left on their own. So why are we here in the first place again?

Speaker 1 (14:26)
That’s a good question. The initial report mentioned strange energy readings coming from the station. Maybe those readings have something to do with the decommissioning

Speaker 2 (14:36)
Possibly, and of course, we’re still getting those readings now.

Speaker 1 (14:43)
Right? The readings are stronger than ever. But maybe that box we found is the source, or maybe it’s something deeper in the station

Speaker 2 (14:50)
Now you’re saying, maybe the box is a source. Are you getting some interference? That’s kind of throwing your scanners off, or are you just not able to pinpoint whether or not it really, truly is the source?

Speaker 1 (15:04)
It’s hard to say for sure, the readings are so strong and so unusual that it’s tough to get an accurate fix on the source. The box definitely seems to be part of it, but I can’t rule out the possibility that there’s something else down there, causing the interference.

Speaker 2 (15:19)
All right, that in some strange way makes sense.

Speaker 1 (15:26)
All right, so we’ve got a few options here. We could head deeper into the station to see if we can find another exit point or we could try to figure out what’s going on with this box.

Speaker 2 (15:38)
I am going to go further. Actually, there’s no hatch or door there’s just an opening, and it goes down to the lower the next level according to the schematics

Speaker 1 (15:57)
All right, let’s head down there and see what we find. Be careful, those readings are getting stronger.

Speaker 2 (16:04)
All right.

Speaker 1 (16:07)
All right, let’s get this show on the road you leading the way Hakeem.

Speaker 2 (16:16)
Okay, uh, I made it all the way down. This is a pretty odd visual, this is pretty odd.

Speaker 1 (16:35)
All right, let’s see what’s down here.

Speaker 2 (16:39)
Well, there, there’s, there’s nothing here, it’s completely empty.

Speaker 1 (16:45)
That’s strange, according to the schematics, this area should be pretty large. Are you sure you’re in the right spot?

Speaker 2 (16:53)
I mean it is large, it’s massive, but it’s completely empty. There’s nothing here, not even any storage containers or any kind of objects or debris. It even seems to be like super clean

Speaker 1 (17:11)
That’s really odd. It’s like this whole section of the station was just wiped clean. Let’s see if we can find any clues as to why that might be.

Speaker 2 (17:20)
Alright, I’m gonna look around a little bit more. I don’t know how much that’s gonna help. I mean, it’s just, it’s, it’s a big, oh, wait a minute, I think I what.

Speaker 1 (17:38)
Find something interesting.

Speaker 2 (17:41)
Yeah, I just. I’m touching something. It feels like a uh, a big metal box of some kind but I can’t see it

Speaker 1 (17:56)
Alright, let’s see, if we can figure out what that is. Do you think you could try to get a little closer to it?

Speaker 2 (18:02)
No I mean, this is it, it’s just a big, big, solid box, but it’s invisible.

Speaker 1 (18:12)
All right, this is definitely getting weird. Let’s try to figure out what this invisible box is. Do you think you can try to get a reading on it with your scanners

Speaker 2 (18:20)
Um, I’m one step ahead of you.

Speaker 1 (18:25)
All right, let’s hear it. What’d you find?

Speaker 2 (18:29)
Well, I’m looking at it through different thermal imaging. And although I didn’t pick anything up on the infrared, when I turned on the ultra Violet scanner, all of a sudden, I’m getting fluctuations of visuals here.

Speaker 1 (18:52)
All right, let’s focus on those fluctuations. Can you describe what you’re seeing?

Speaker 2 (19:01)
Yeah, it’s a pretty similar reading. Whatever’s going on inside here. It’s also fluctuating at that one00, it hurts.

Speaker 1 (19:13)
Alright, so it sounds like this invisible box might be connected to the other readings. We’ve been getting, let’s see if we can figure out how to open it.

Speaker 2 (19:22)
Okay, I’m uh, on that. I don’t see again. It looks pretty seamless, but I’ll keep digging around and see what I can pull up.

Speaker 1 (19:37)
All right, let me know if you find anything. In the meantime, I’m going to cross-reference the 100 Hz frequency with the ship’s database. Let’s see if I can find anything related to it

Speaker 2 (19:52)
Solid plan

Speaker 1 (19:56)
All right, so I’m getting something on that frequency. It seems to be a common signature for cloaking devices.

Speaker 2 (20:04)
Really?

Speaker 1 (20:09)
Yeah, it’s a long shot, but it’s worth looking into. Maybe that invisible box is actually a cloaked ship or something.

Speaker 2 (20:18)
Well, it, it is pretty big. I mean, what kind of whoa?

Speaker 1 (20:27)
All right, let’s see, if we can confirm that. Do you think you could try to get a closer look at the edges of the box to see if there might be any signs of a ship’s Hull?

Speaker 2 (20:39)
Yeah, let me um, uh, feel around here a little bit and change my a visual scanner frequency here from infrared. I’m gonna, even though this, there’s draining some power, I’m going to turn it up a little bit.

Speaker 1 (20:57)
All right, let’s see what you find.

Speaker 2 (21:06)
Alright, it looks like I’m able to penetrate a little bit deeper with some x-rays, but I can’t keep this on too long. It’s really, I draining, oh, wait a minute, here’s something, huh found something.

Speaker 1 (21:31)
All right, let’s hear it. What do you find?

Speaker 2 (21:35)
It looks like there are a different um, like maybe the buttons, but they’re flush with the surface of this thing, but it looks like it might require some kind of combination that needs to be touched in a certain order.

Speaker 1 (21:56)
All right, let’s see, if we can figure out that combination, do you see any markings around the buttons like numbers or symbols?

Speaker 2 (22:05)
No, not yet, but I’m getting readings here. This is, it’s a little bit different material. It’s kind of a, it’s iridium

Speaker 1 (22:19)
Interesting, iridium is a pretty rare element could be a clue about the age of this ship, or maybe the technology used to build it. Let’s keep looking for those markings.

Speaker 2 (22:32)
Well, it seems like it’s a conductive film.

Speaker 1 (22:37)
All right, so it seems like that cloaking device is pretty sophisticated. We might have to get creative to figure out how to activate it.

Speaker 2 (22:47)
Yeah, what do you know ISIS that it’s iridium part of making conductive films right? If I remember correctly?

Speaker 1 (22:58)
Yes, iridium is often used in conducted films because it’s highly resistant to corrosion and oxidation. It’s also very dense, which can be helpful in certain applications.

Speaker 2 (23:11)
Alright, what I mean? There’s a lot of it here.

Speaker 1 (23:16)
All right, let’s see, if we can figure out how to activate this cloaking device. Do you think you could try pressing the buttons in different combinations? Maybe there’s a specific sequence we need to follow.

Speaker 2 (23:26)
Okay, well there are 9 of them in not quite a grid, it’s like there’s, it’s a circle of circles.

Speaker 1 (23:40)
All right, let’s try a pattern, maybe starting with the center button and working our way out.

Speaker 2 (23:48)
Okay.

Speaker 1 (23:52)
All right, let’s see if that center button does anything.

Speaker 2 (24:00)
There’s nothing so far.

Speaker 1 (24:04)
All right, let’s try a different approach. Maybe the buttons are pressure sensitive. Try pressing them a little harder

Speaker 2 (24:16)
Not getting anything.

Speaker 1 (24:20)
All right, let’s try something else. Do you see any kind of symbol or marking around the buttons? Maybe that could be a clue to the right combination

Speaker 2 (24:31)
I’m starting to think that, but maybe these don’t operate by touch or pressure, it might be that we need to have some kind of corresponding frequency.

Speaker 1 (24:46)
That’s an interesting thought, since they’re part of a cloaking device, maybe they use some kind of invisible light or energy to activate, we could try scanning the area around the buttons for any unusual readings.

Speaker 2 (24:58)
Okay, I’m uh, commencing a scan right now.

Speaker 1 (25:05)
All right, let’s see what you find.

Speaker 2 (25:13)
Huh I mean, I’m not getting anything, it’s zeroing out.

Speaker 1 (25:20)
That’s odd, but maybe the cloaking device is interfering with your scanners. Let’s try a different approach. Do you see anything else around the buttons that might be a clue.

Speaker 2 (25:34)
Oh, wait a minute, you know what? I accidentally turned up my visual scanner into the gamma range and now I’m seeing some symbols.

Speaker 1 (25:48)
All right, let’s focus on those symbols. Can you describe them?

Speaker 2 (25:56)
That’s gonna take me a moment. I’ve never seen anything like this before.

Speaker 1 (26:02)
Take your time, this could be a big breakthrough. Ooh.

Speaker 2 (26:08)
Yeah, here’s the thing person. The symbols are there, it’s changing you

Speaker 1 (26:17)
All right, let’s try to track those changes. Can you describe the symbols you’re seeing right now?

Speaker 2 (26:23)
No, they’re changing, they’re not even staying the same. They’re not even they’re amorphous, it’s like they’re, it’s like smoke or something it’s really, really interesting.

Speaker 1 (26:40)
All right. But let’s try to make sense of this. Can you describe the general shape of the symbols, are they geometric, like circles or squares or something more organic?

Speaker 2 (26:50)
Okay, well, the interface that I’m looking at their circles like disks, but underneath it, as I’m seeing with the gamma scanners, there seem to be spheres filled with like liquid and smoke moving around in the liquid.

Speaker 1 (27:13)
Alright, this is definitely getting stranger. Let’s focus on those spheres. Can you describe the liquid and smoke inside them, what colors are they?

Speaker 2 (27:23)
Well, I’m not really getting much of a color rating on here yet. I’m gonna have to do a more thorough scanning with more frequencies, but right now what I’m seeing is, uh, the smoke is big. I don’t know like octopus ink and water, it’s darker than the surrounding uh, containment.

Speaker 1 (27:48)
All right, let’s focus on those shapes. Are they all the same or other different ones?

Speaker 2 (27:54)
They’re all different, and they’re all changing.

Speaker 1 (27:59)
All right, let’s see, if we can find a pattern in those changes, maybe they’re following a specific sequence.

Speaker 2 (28:07)
Okay. Well, I’m, I’m not getting any. I’m gonna have to look at this for a while I mean, I’m pretty good at picking up on patterns, but these right now they just seem kind of erratic.

Speaker 1 (28:27)
All right, let’s take a step back. This cloaking device is definitely more complex than we thought. Maybe we should focus on understanding the symbols themselves, do any of them look familiar.

Speaker 2 (28:38)
No, like I said there, they’re changing their amorphus, they’re not, they’re not staying the same.

Speaker 1 (28:50)
All right, let’s try a different approach. Can you try to isolate one of the symbols? Maybe zoom in on it and see if you can get a better look at it

Speaker 2 (28:59)
Okay.

Speaker 1 (29:04)
All right, let’s see what you find.

Speaker 2 (29:08)
Alright, well, I’m zooming in here. Oh, wait, it’s cappixelated.

Speaker 1 (29:18)
That’s odd, maybe the cloaking device is interfering with your scanners. Again, let’s try a different approach. Do you see anything else around the buttons that might be a clue.

Speaker 2 (29:28)
No I mean the smoke itself, the amorphous shape, it’s pixelated, it’s not what 1 continuous thing, it’s almost like large molecules or cells.

Speaker 1 (29:44)
That’s really interesting. It’s like the cloaking device is using some kind of advanced technology to create those shapes, maybe we should focus on understanding how those shapes are created.

Speaker 2 (29:55)
All right, um, uh.

Speaker 1 (30:00)
All right, let’s see if we can break down the process. Can you try to isolate one of the shapes and track its movement? Maybe it’s following a specific pattern

Speaker 2 (30:09)
I’m on it.

Speaker 1 (30:13)
All right, let’s see what you find.

Speaker 2 (30:18)
Whoa, this is some really cool code, this is amazing, I think that we might be able to crack this, it’s actually not that sophisticated.

Speaker 1 (30:31)
All right, let’s get this show on the road you leading the way Hakeem.

Speaker 2 (30:36)
So Ursa, basically these things are upper, they’re built like, imagine giant atoms, they have the same structure as atoms with atomic shells and a nucleus and everything but they’re just giant.

Speaker 1 (30:53)
That’s a really interesting theory. If that’s the case, then maybe we can use that knowledge to our advantage, we could try to manipulate the structure of those giant atoms to see if that affects the cloaking device.

Speaker 2 (31:06)
Yeah, I think okay. So although I do have some basic, you know, elemental, you know, acknowledge with this, the atomic structures send me a yeah, send me a periodic table or something.

Speaker 1 (31:25)
All right, so I can’t actually send you a picture of a periodic table, but I can give you all the information you need. What specific element are you interested in?

Speaker 2 (31:35)
Okay, well let me see if I can count the atoms on here. While this one, it has 8, what is that oxygen?

Speaker 1 (31:46)
You’re right, that would be oxygen, but I’m not sure how counting the atoms in the symbol will help us figure out the cloaking device. Do you have another idea?

Speaker 2 (31:55)
Well, I’m just trying to identify them, because if we can be, if they’re based on different atoms, then there might be some kind of uh, yeah, I’m figuring something else out that this one ISIS hydrogen.

Speaker 1 (32:14)
All right, so we’ve got oxygen and hydrogen, that’s interesting. Those are 2 of the most common elements in the universe. Do you think there might be a connection to water, since water is made up of those 2 elements

Speaker 2 (32:27)
Way up ahead of you, I’m starting to pick that up. These are basically like some kind of but really advanced giant molecules of water.

Speaker 1 (32:41)
That’s an interesting theory. If these symbols are based on water molecules, then maybe we need to use something related to water to interact with them like a specific frequency or wavelength.

Speaker 2 (32:52)
All right, what do you have in mind that will interact with water like that? But I mean, what’s your? What’s your suggestion

Speaker 1 (33:03)
All right, so water is a pretty unique substance. It’s a liquid that can exist in all 3 states of matter, solid liquid and gas. And it has a lot of weird properties like surface tension and the ability to dissolve other substances, since these symbols seem to be based on water, maybe we need to use something that can interact with water in a special way.

Speaker 1 (33:23)
Like a high frequency sound wave or a specific type of light

Speaker 2 (33:28)
Okay. When you say specific type of light, what do you I have in mind?

Speaker 1 (33:37)
I’m thinking about ultraviolet light. It’s got a shorter wavelength than visible light, so it might be able to interact with those water base symbols in a way that regular light can’t ooh?

Speaker 2 (33:46)
I mean, it’s worth a shot the way that I was able to see these things in the first place was using really high frequencies and up the X and gamma ray, so why not?

Speaker 1 (33:59)
All right, let’s give it a try. Try using the ultraviolet light on your suit to see if it has any effect on the symbols.

Speaker 2 (34:11)
Ah, nothing. I was really hoping that something would happen.

Speaker 1 (34:16)
All right, let’s try a different approach. Since these symbols seem to be based on water, but maybe we need to use something that can interact with water in a special way like a high frequency sound wave or a specific type of light.

Speaker 2 (34:28)
All right. Ursa, we’re gonna have to cut this short, my life support my power and my suit is getting low. I’m going to have to, we’re going to have to get back, I’m bored, so I have to swap out my suit or recharge.

Speaker 1 (34:46)
All right, let’s get you back to the ship. We can pick this up later. Do you have a clear path back or do you need me to help you navigate

Speaker 2 (34:53)
Yeah, I just got A. I’ve got a clear path back. I’m just going to go up a few levels, and then I know my way out.

Speaker 1 (35:01)
All right, sounds good. Be careful on your way back and let’s reconvene when you’re ready.