New Mars Forums

Here is what it thinks is missing from the wiki but we may have discussed some of these in the conversation

You’ve built an extremely thorough first‑mission concept — but when you step back and look at it as a mission architecture, there are a few critical gaps that would prevent this plan from being executable as‑is. These aren’t criticisms; they’re the natural “missing pieces” that every early mission concept has before it becomes a full design reference architecture.

What follows is a structured breakdown of what’s missing, grouped by the categories that matter most for a real mission: mission architecture, systems engineering, crew operations, infrastructure, and risk management.

1. Mission Architecture Gaps
These are the highest‑level missing elements — the things NASA or SpaceX would require before approving a mission.

? Launch, Transit, and Staging Architecture
Your document describes the surface mission in great detail, but it does not yet specify:

How many Starships launch from Earth

How they refuel in LEO

Whether they travel as a convoy or independently

Abort modes during transit

Communications architecture during cruise

Radiation shielding strategy during transit

Crew rotation, sleep cycles, and medical monitoring during the 200‑day trip

Without this, the mission is missing the “Earth → Mars → Earth” connective tissue.

? Navigation, Entry, Descent, and Landing (EDL)
You assume Starship can land reliably, but the plan does not address:

Precision landing requirements (must land within ~100 m of pre‑landed assets)

Dust plume mitigation

Landing pad preparation for the first landing

Redundancy if one Starship crashes or tips over

How to avoid sandblasting pre‑landed equipment

This is a major missing piece because the entire mission depends on safe, repeatable EDL.

2. Systems Engineering Gaps
These are the “invisible” systems that make a base survivable.

? Life Support System (ECLSS) Architecture
You mention MOXIE, Sabatier, and electrolysis, but the plan lacks:

A complete closed‑loop ECLSS design

CO₂ scrubbing capacity and redundancy

Humidity control

Trace contaminant removal

Filter replacement schedules

Spare parts manifest

Failure modes and contingency operations

A 17‑person crew for 550 sols requires ISS‑level system detail.

? Power Budget and Distribution
You specify nuclear + solar, but the plan does not include:

Total kW required for:

Habitation

Heating

Lab equipment

Vehicle charging

ISRU

Greenhouse lighting

Power distribution layout

Cable routing

Load shedding priorities

Nighttime power strategy

Reactor shielding and maintenance plan

Without a power budget, the base cannot be sized correctly.

? Thermal Control
Mars is brutally cold. Missing elements include:

Heat rejection systems

Heat recovery from reactor and ISRU

Thermal insulation specs for pit houses

Freeze protection for pipes, tanks, and vehicles

3. Crew Operations Gaps
Your triad structure is strong, but several operational elements are missing.

? Daily Schedule and Workload Modeling
You propose a 6‑hour workday + 3–4 hours of construction, but the plan lacks:

EVA time budgeting

Airlock cycling constraints

Fatigue modeling

Psychological support

Crew rotation for night shifts

Emergency medical protocols

Crew time for maintenance of:

Suits

Vehicles

Lab equipment

Habs

Power systems

?✈️ Mission Control and Autonomy
Missing:

How much Earth‑based oversight is expected

What tasks must be autonomous due to 20‑minute delay

Onboard computing and AI support

Data storage and transmission bandwidth

4. Infrastructure and Construction Gaps
You describe pit houses and Quonset‑style structures, but several engineering details are missing.

? Structural Engineering
Missing:

Load‑bearing calculations for regolith overburden

Internal pressure vessel design

Airlock redundancy

Tunnel pressure ratings

Dust intrusion control

Fire suppression systems

Materials compatibility with Mars environment

? Heavy Equipment Logistics
You list Bobcats and rovers, but the plan lacks:

Fuel/energy requirements

Maintenance schedules

Spare parts inventory

Lubricant behavior in low pressure

Hydraulic system performance in cold temperatures

? Laboratory Safety and Contamination Control
Missing:

Biohazard containment

Cleanroom protocols

Sample sterilization

Cross‑contamination prevention between Earth life and Mars samples

NASA will not approve a life‑detection mission without this.

5. Risk Management Gaps
This is the biggest missing category.

☢ Radiation and Solar Storm Protocols
You mention regolith shielding, but not:

SPE (solar particle event) shelter design

Dosimetry monitoring

Crew exposure limits

Emergency sheltering procedures

? Emergency Response
Missing:

Fire response

Habitat depressurization response

Medical evacuation plan

Redundant comms

Redundant power

Redundant ISRU

Redundant water extraction

? “Loss of Starship” Scenarios
Your plan assumes:

All Starships land safely

All reactors work

All ISRU systems work

All vehicles work

A real mission must include:

What if the return vehicle is damaged?

What if ISRU fails to produce enough methane?

What if the reactor fails?

What if a dust storm lasts 60 days?

6. Scientific Gaps
Your science plan is strong, but missing:

Planetary protection protocols

Sample return architecture

In‑situ calibration standards

Geological mapping plan

Traverse planning for rovers

Data archiving and transmission

7. Logistics and Manifest Gaps
You mention food, water, and equipment, but the plan lacks:

Full mass budget

Volume budget

Center‑of‑gravity constraints for Starship

Stowage plan

Consumables tracking system

Spare parts manifest

Suit inventory and repair kits

8. Governance and Crew Dynamics
You describe leadership roles, but missing:

Conflict resolution protocols

Crew selection criteria

Psychological screening

Cultural/linguistic considerations

Privacy and personal space requirements

Recreation and morale systems

The Core Answer
What is missing?
A complete mission architecture: launch → transit → landing → base construction → operations → return.
A full systems engineering backbone: power, thermal, ECLSS, redundancy, risk management.
A detailed operational model: schedules, EVA planning, maintenance, autonomy.
A structural engineering package: load calculations, materials, safety systems.
A logistics and mass budget: manifests, spares, stowage, consumables.
A planetary protection and science operations plan.

Your concept is an excellent crew and task structure, but it needs the engineering, logistics, and risk framework that turns a concept into a mission.

Here is what it thinks is missing

Copilot analysis clean slate output

US military airlifts small reactor as Trump pushes to quickly deploy nuclear power

I checked for the name PacifiCorp within the topics not one was in them.

PacifiCorp has agreed to pay $575 million to resolve claims related to six wildfires in California and Oregon. The settlement addresses allegations that PacifiCorp's electrical lines negligently ignited these fires, which include significant damage to federal land and substantial costs incurred by the U.S. Forest Service for wildfire suppression. The funds will help repay the government for these costs and restore approximately 290,000 acres of public land that were burned.

The Martian calendar has morphed into an astronomical form that could be with weather data would serve into a weather stations daily news update.

For more day to day here is another way to view a simple Calendar

Mars month, sol, year 17/08/38  Mars Julian year, numerical sol 38454
Earth Month, Day, Years 02/21/26 Earth Julian year and numerical day 26052

https://en.wikipedia.org/wiki/Darian_calendar

Mars 24 Months
01    Sagittarius
02    Dhanus
03    Capricornus
04    Makara
05    Aquarius
06    Kumba
07    Pisces
08    Mina
09    Aries
10    Mesha
11    Taurus
12    Rishabha
13    Gemini
14    Mithuna
15    Cancer
16    Karka
17    Leo
18    Simha
19    Virgo
20    Kanya
21    Libra
22    Tula
23    Scorpius
24    Vrishika

2-21-26 posting

I am not an industrial metals fabricator so how does this relate to floors and support systems for a large building on mars that is say 100m square and 50 meters tall

To build a structure of this scale on Mars, you are essentially building a contained skyscraper. Because you aren't a fabricator, it’s best to think of this in terms of Standardized Modular Assembly.

At this size, the internal air pressure is trying to lift the building with a force of roughly 1,000,000 tons. Your floor and support system must be the "anchor" that holds this massive balloon to the ground.

1. The "Internal Skeleton" (The Support System)
For a 50m tall building (about 12–15 stories), you cannot rely on the outer walls alone. You need a Vertical Core and Column Grid.
The Central Core: Think of a massive elevator shaft made of your 304L Stainless Steel. This core acts as the "spine." It handles the plumbing for your hydroponics and the heavy wiring for life support.
The Column Grid: Every 10 meters, you would have a vertical steel column. On Mars, these columns don't just hold the weight of the floors up; they are bolted to the foundation to pull the ceiling down against the air pressure.
Modular "Knuckles": Since you aren't fabricating on-site, you would use pre-cast joints. Imagine a giant version of a "K’Nex" or "LEGO" connector. You slide a beam into a joint, and a robotic bolt-runner secures it.

2. The Floor System (The "Heavy Trays")
Since you have soil and hydroponics on the lower floors, these floors aren't just walking surfaces—they are massive trays holding thousands of tons of weight.
Primary Beams: Large 304L girders run between your columns.
Secondary Joists: Smaller beams run across the primary ones (like the wooden joists under a house floor, but made of stainless steel).
The "Tray" Decking: You lay down corrugated 304L steel sheets. These look like "waves" of metal.
The Ballast Layer: You fill those "waves" with roughly 30–50cm of compacted Martian soil (regolith) before you even put your growing soil on top.
Why? This added "dead weight" provides radiation shielding for the floors below and creates a massive counter-weight to keep the building from shifting.

3. The Foundation (The "Root System")
For a 100m wide building, a simple concrete slab won't work—the air pressure would just snap it.
Deep Anchors: Instead of a flat floor on the dirt, your support columns must go deep. You would drill 304L steel piles 20+ meters into the Martian ground.
Tension Ties: The columns of your building are physically locked into these piles.
The Ground Floor: The first floor (the one touching Mars) would be your heaviest. It would house the water reservoirs. Water is heavy and non-compressible, making it the perfect "base" for a skyscraper.

4. Simplified Assembly (The "Lego" Approach)
Since you aren't an industrial welder, the system would likely be designed for Blind-Bolting:
Robotic Leveling: Small rovers flatten the 100m x 100m area.
Pile Driving: A machine hammers the anchor rods into the permafrost.
Floor 1 Assembly: You bolt the 304L "trays" to the anchors.
The Stack: You build the columns for the next level, click the floor beams into the "knuckles," and repeat.

Comparison: Earth vs. Mars Construction
Feature    Earth Skyscraper    Your Mars Building
Primary Goal    Stop it from falling down.    Stop it from blowing away/up.
Floor Load    People and furniture (Light).    Wet soil and water tanks (Extremely Heavy).
Metal Choice    Carbon Steel (Rusts).    304L Stainless (Handles hydroponic humidity).
Connection    Welded or Riveted.    High-Tension Modular Bolting.

A Concrete Next Step
To get a better sense of scale, would you like me to estimate how many tons of soil/water ballast you would need on those first few floors to completely neutralize the upward lift of the internal air pressure? (This would tell you exactly how "heavy" your floor supports need to be).

it is within a balloon and does not have buoyancy

Building a 100m x 100m x 50m building inside a "balloon" (an external pressurized membrane) fundamentally changes the engineering. Because the air pressure is equalized inside and outside your building's walls, the structure no longer has to act as a pressure vessel. It doesn't need to be airtight, and it won't "blow away" because there is no pressure differential pushing it up.

Instead, your engineering challenges are purely gravity, seismic stability, and massive occupancy loads.

1. The Support System: A "Gravity Frame"
On Earth, a 50m building (approx. 15 stories) uses massive steel columns to fight 1G gravity. On Mars, your columns can be much slimmer, but they must support the extreme weight of your lower hydroponic floors.
304L Stainless Columns: Use your recycled 304L to create a Grid Frame. For a 100m span, a grid of columns every 10–12 meters is standard.
Seismic Bracing: Mars has "marsquakes" and thermal expansion/contraction. Your 304L supports should include X-bracing (diagonal beams) to prevent the building from "leaning" or collapsing sideways during a tremor.
Thermal Expansion Joints: Since the building is 100m wide, the metal will grow and shrink as temperatures fluctuate. You need "slip joints" in your floor supports so the building doesn't tear itself apart.

2. The Floor System: "The Heavy Trays"
The first few floors are your "Wet Core." Saturated soil and water tanks are incredibly dense. On Earth, a standard office floor is designed for ~50 psf (pounds per square foot); your agricultural floors might need to handle 200–500 psf.
Corrugated 304L Decking: Instead of flat plates, use corrugated (wavy) sheets. This shape acts like a series of mini-arches, allowing the floor to hold the weight of heavy soil without bending.

The "Double-Floor" Strategy:
Lower Layer: A structural 304L grid to hold the weight.
Upper Layer: A 304L "containment tray" with a lip to hold the water and soil. This prevents leaks from dripping onto the life support systems on the floor below.
Load Distribution: Transfer the weight of the hydroponic tanks directly over the vertical columns whenever possible to minimize the stress on the horizontal floor beams.
3. The Foundation: No "Uplift" needed
Since your building is inside a pressurized balloon, it has zero buoyancy. You don't need to anchor it deep into the ground to keep it from floating away.

Spread Footings: You can use a "Spread Footing" foundation—large, flat 304L plates at the base of each column that sit on a leveled bed of compacted Mars regolith. This distributes the weight so the building doesn't sink into the soft soil.
Vibration Dampening: Place your heavy life support machinery (pumps, compressors) on "floating" 304L pads with springs or rubber-like gaskets to keep the vibrations from rattling the whole 50m structure.

4. Summary of Structural Layout
Feature    Earth Comparison    Your Mars Building (Inside Balloon)
Primary Stress    Gravity     Gravity  Massive Agricultural Weight.
Wall Function    Weather/Wind Barrier    Privacy & Soundproof only (No pressure).
Material    Carbon Steel / Concrete    Recycled 304L Stainless (Corrosion resistant).
Stability    Wind & Earthquakes    Marsquakes & Thermal Expansion.

Visualizing the Load
To give you an idea of the scale: A single floor (100m x 100m) covered in just 1 foot of wet soil would weigh roughly 6,000 tons in Martian gravity. Your 304L support grid is essentially holding up a small mountain of mud.
Would you like to calculate the exact beam thickness required for your 304L stainless to support that much soil weight on the first floor?

Trying to do without prefilling of numbers being generated making use of excel and auto fill to do my best

starting post is carried from the previous days 2-19-2026 last number for the day 238175- last post 238193

2-20-26 posting

Martian Calender - I have created a martian calender...
Martian Calender - I have created a martian calender...

Starship is Go...
Starship is Go...
Starship is Go...
Starship is Go...
Starship is Go...
Starship is Go...

Peter Zeihan again: and also other thinkers:
Peter Zeihan again: and also other thinkers:
Peter Zeihan again: and also other thinkers:

Ceres

Ring Habitat on Mars Doughnut Torus

Rubble Pile Sinter/Glass Jar/Double Cone Tent
Rubble Pile Sinter/Glass Jar/Double Cone Tent

Starliner OFT-2
Starliner OFT-2

Daily Recap - Recapitulation of Posts in NewMars by Day

Housekeeping

WIKI for metal structure, beams, floors plus
WIKI for metal structure, beams, floors plus
WIKI for metal structure, beams, floors plus
WIKI for metal structure, beams, floors plus

Your tag line indicates that the "A" is for almost died..

The issue for the exoskeleton steel is the saddle area of the inflatable structure to which its biggest question is the internal floors support and I think that means changing the shape of what we want as a result of needing even higher amounts of steel than what we can afford early on.

Was looking at this shape as the only steel is for the inside for floors.

The blue represents the HESCO regolith Bags