论文信息 - Stoichiometric constraints and complete closure of long-term life support systems.

Stoichiometric constraints and complete closure of long-term life support systems.

High closure of matter recycling is an obvious requirement for long-term life support systems (LSS). Biological species are obligate components of the LSS since physical/chemical components are not able yet to provide food for crew. However including biological species into LSS is difficult due to specific stoichiometric configuration of their inputs and outputs. Formally the problem is to estimate the ability for given set of species to provide complete closure of LSS. Two possible models of metabolism organization can be considered: rigid and flexible ones. Stoichiometric analyses showed that the rigid metabolism case is not typical and takes place with very specific requirements. The flexible metabolic model can be applied to describing wide range of systems. Some formal indications of ability to provide complete closure and stationarity of LSS state are considered in the paper. These indications establish some constraints on the form of mathematical models intended to describe artificial and natural ecological systems.

S I Bartsev | S. Bartsev

[1] S I Bartsev,et al. Evaluation of optimal configuration of hybrid Life Support System for Space. , 2000, Advances in space research : the official journal of the Committee on Space Research.

[2] N. M. Sisakyan,et al. PROBLEMS OF SPACE BIOLOGY , 1963 .

[3] Alan Drysdale. The Effect of Resource Cost on Selection of Life Support Technologies , 1995 .

[4] J I Gitelson,et al. Perspectives of different type biological life support systems (BLSS) usage in space missions. , 1996, Acta astronautica.

[5] Gary W. Stutte,et al. A More Completely Defined CELSS , 1994 .

[6] Reinhart Heinrich,et al. Evolutionary optimization of metabolic pathways. Theoretical reconstruction of the stoichiometry of ATP and NADH producing systems , 2001, Bulletin of mathematical biology.

[7] E. Odum. Fundamentals of ecology , 1972 .

[8] David M. Karl,et al. Aquatic ecology: Phosphorus, the staff of life , 2000, Nature.

[9] Granino A. Korn,et al. Mathematical handbook for scientists and engineers , 1961 .

[10] James P Grover,et al. Stoichiometry, herbivory and competition for nutrients: simple models based on planktonic ecosystems. , 2002, Journal of theoretical biology.

[11] S. I. Bartsev,et al. Life Support System (Lss) Designing: Principle of Optimal Reliability , 1996 .