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In Korolev's defence of the N1 draft project in July 1962 he stated that he first sketched out the N1 design in 1956-1957. The requirement at that time was to support a large manned expedition to Mars. This first serious examination in the Soviet Union of manned flight to Mars was initiated by M Tikhonravov's section of Korolev's OKB-1. The study group first considered a complete manned expedition to Mars. This followed the classic scenario worked out by Von Braun's group in their Mars Project of 1948. A spacecraft, the Martian Piloted Complex (MPK), would be assembled in low earth orbit. Using conventional liquid propellants, it would fly a Hohmann trajectory, enter Martian orbit, and a landing craft would descend to the surface. After just over a year of surface exploration, the crew would return to earth. It was calculated that the initial mass of the MPK would be 1,630 tonnes, and a re-entry vehicle of only 15 tonnes could be returned to earth at the end of the 30 month mission. At the planned N1 payload mass of 75 to 85 tonnes, it would take 20 to 25 N1 launches to assemble the MPK.

In 1959 a group of enthusiasts in OKB-1 Section 3 under the management of G U Maksimov started engineering design of this first fantastic project for manned interplanetary travel. The requirements for executing this project would shape the specifications for the N1 launch vehicle. The 75 tonne TMK-1 spacecraft would take a crew of three on a Mars flyby mission. After a 10.5 month flight the crew would race past Mars, dropping remote controlled landers, and then be flung into an earth-return trajectory. The first flight to Mars of the TMK-1 was planned to begin on June 8, 1971, with the crew returning to the earth on July 10, 1974, after a voyage of three years, one month, and two days.

Feoktistov felt that the TMK-1 manned Mars flyby design was too limited. They proposed in 1960 a complete Mars landing expedition, to be assembled in earth orbit using two or more N1 launches. The spacecraft would be powered by nuclear electric engines, with the reactor moved away from the crew quarters on long telescoping booms. Five landers would deliver a nuclear-powered 'Mars Train' on the surface for a one-year survey of the terrain. The design would be heavily modified as the 1960's progressed, as research showed the Martian atmosphere to be much thinner and the nuclear electric engines to be less efficient than assumed.

Surface transports were part of all Soviet Mars expeditions. The earliest concepts had multiple articulated tracks. The elaborate Mars Train used wheeled vehicles equipped with manipulator arms so that extended surface operations could be undertaken in shirtsleeve comfort. Later Marsokhods were more austere, providing limited mobility around the landing site on short 30-day or 7-day sojourns on the surface.

A variation of the TMK-1 scenario by Maksimov's unit would still use a single N1 launch. However a flyby of Venus would be undertaken on the return voyage from Mars. This would reduce both flight time and the earth-return velocity. The project was given the code name "Mavr" ('Moor' or MArs - VeneRa).

Work on the TMK project continued, including trajectory trade-off studies and refinement of the design. In its final iteration, in May 1966, before Korolev�s OKB was overwhelmed by N1-L3 development work, the design was known as the KK - Space Complex for Delivering a Piloted Expedition to Mars. Nuclear-electric propulsion was retained, but various mission designs were studied in an attempt to reduce the overall vehicle mass.

By the end of 1969 Mishin and Yangel dropped out of the competition. This left Chelomei as the only chief designer working on Project Aelita.

A government expert commission reviewed the preliminary draft project for the UR-700M launch vehicle and MK-700 spacecraft in 1972. Based on the decades worth of development and tens of billions or roubles required, the state commission recommended that further work on manned Mars expeditions be deferred indefinitely.

NPO Energia resumed study of a Mars project once development began of the new Energia booster in place of the cancelled N1. The 1978-1986 study used some of the ideas and technical results of the 1969 study, but modified according to technical developments of the period. The 15 MW nuclear power requirement was retained, but actual development of the 11B97 rocket stage beginning in 1971 had shown earlier specific impulse projections to be hopelessly unrealistic. This lead to the mass of the spacecraft more than doubling, with the propellant fraction increasing from 17% to 45% of the spacecraft total. Other differences included the use of two reactors in the place of one; reduction of the crew size from six to four; and the use of tested systems developed on the Salyut and Mir orbital stations in placed of the untried TMK hardware. This use of tested hardware guaranteed an increased level of crew safety compared to previous concepts. The original use of a completely separate second reactor and propulsion unit ensured the safe return of the crew even in the event of complete failure of one reactor or engine cluster.

The ship designed to perform this mission would have a mass of 355 tonnes.

By the 1980's test of the experimental RD-0410 nuclear thermal rocket engine had led to a definitive flight design. The design included bimodal use of the nuclear reactor to provide electrical power during dormant or cruise flight phases by means of a Brayton cycle turbine using xenon-helium coolant. The NPO Luch powerplant produced 20,000 kgf, with a thermal power of 1200 MW, operating time of 5 hours, and a specific impulse of between 815 and 927 seconds. During cruise operations the turbine would provide 50-200 kW of electric power, requiring 600 square meters of radiators. Two designs emerged using this a cluster of three to four of these engines with a total powerplant mass of 50 to 70 tonnes. The 1989 layout of the Kurchatov Institute surrounded the crew quarters with liquid hydrogen propellant tanks to shield the crew from radiation from the reactors and cosmic rays. The radiators were positioned at the nose of the spacecraft. A more detailed 1994 design from the Keldysh Institute / NII-TP placed the radiators forward of the engines, followed by communications antennae, the living quarters (again surrounded by propellant tanks), followed by two large landing craft (one for Mars, one for Earth) docked laterally at the nose. The crew of five would complete the trip to Mars and back in 460 days. Total time of thrusting engine operation for the 800 tonne, 84 m long craft was 6 hours.

The Marpost (Mars Piloted Orbital Station) spacecraft would have a total mass of 400 tonnes and be assembled in low earth orbit from components assembled in four launches of a revived Energia launch vehicle. As in the 1989 Energia Mars design, it would be powered to and from Mars by matrices of hundreds of solar-powered ion thrusters using xenon as propellant. Unlike the earlier expedition, the crew module would be an enormous 6-m diameter, 28 m long spacecraft housing a crew of six. This module seemed to be a throwback to the TMK-derived modules of the 1960's. Over a total expedition duration of two years the spacecraft would fly to Mars, spend a month or more in Mars orbit, obtain samples from the surface by operation of automated probes, and return to earth. Evidently the large station would be braked into earth orbit on return by the ion engines and was not equipped with a re-entry vehicle.