Mars Analogue Research Station Program


The Mars Analog Research Station Program is an international effort initiated and spearheaded by The Mars Society to establish a network of prototype research centers where scientists and engineers can live and work as if they were on Mars, to develop the protocols and procedures that will be required for human operations on Mars, and to test equipment that may be carried and used by human missions to the Red Planet.

Status

The first station, the Flashline Mars Arctic Research Station, began operation in 2000 on Devon Island in the Canadian Arctic. The second station, the Mars Desert Research Station, began operation in 2002 in southern Utah. Stations to be built in Europe and Australia have not progressed beyond the planning stages. EuroMARS was planned for deployment in Iceland. A structure for EuroMARS was built, but placed in storage for several years due to lack of funding to ship to the Society's UK headquarters, and from there on to Iceland. During storage and shipping the structure was damaged beyond repair, so now the European chapters of the Mars Society are seeking funding to build a new habitat. The fourth station, MARS-Oz, has been designed, but lacks funding for construction.
Each of the MARS research centers comprises a prototype of the Mars Habitat Unit of the kind advocated in the Mars Direct and NASA Mars Design Reference Mission for sending human crews to Mars.
These are multi-deck units, providing a combination of living and working space for crews of up to six people at a time. Each unit is approximately in diameter and stands in height, offering either two or three decks of interior living and working space.

Layout

The Flashline Mars Arctic Research Station and the Mars Desert Research Station are two-deck units, designed around a common layout.
The upper deck is divided into two halves: one is given over to six individual sleeping cabins that provide visiting crew members with a bed, personal storage space and privacy when they need it. The other half of the upper deck is devoted to a common work area / dining area / food preparation area. In the ceiling space above this is the unit's large water tank, containing all of the habitat's usable water.
The lower deck contains an open-plan work area where a variety of science and engineering tasks can be performed. It also contains the main hygiene area, and contains the main power distribution system for the habitat and the heating system. Heat and power are supplied by external generators, but on a real mission to Mars they would most likely be supplied using a combination of nuclear and possibly solar power. However, due to the extremes of dust contamination, solar panels will not supply sufficient energy to power a Habitat on Mars on their own.
Also on the lower deck of the FMARS and MDRS are the airlocks and the Extra-vehicular Activity preparation room. This is where crew members don and doff their simulated Mars spacesuits prior to leaving the Habitat Unit.
The European Mars Analog Research Station is slightly different from FMARS and MDRS in that it provides three decks:
The European unit has been deliberately designed for expansion - additional equipment and technology, such as water recycling systems, can be added to the unit as they become available.

Operational goals

The primary goal of the MARS programme is to research the operational environment of a base on Mars. As such, the programme is specifically geared towards answering a wide range of key questions about living and working on Mars, including:
In order to find answers to these and other questions, MARS teams will:
In order to achieve these goals, operations at the Habitat Units are performed under "Mars simulation" conditions. This means that once a crew is in a unit, barring a serious medical event or emergency, they live and work as astronauts would on Mars:
Each crew spends between 2 weeks and a month living in a habitat unit, performing the kind of work astronauts will be expected to carry out on Mars: collecting rock samples from the surface and examining them back in the habitat; conducting life science experiments; studying the local geology and geomorphology, and so on.

Design

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