Terraforming Mars - Edited by Martin Beech, Joseph Seckbach, and Richard Gordon

Terraforming Mars 

Edited by Martin Beech

Joseph Seckbach

and Richard Gordon

Wiley-Scrivener

ISBN 9781119761969

eISBN 9781119761860

ASIN B09M9CBYSW

First this is one of the most memorable Science Text I have read in years. It ranks up there with reading In Search of Schrodinger's Cat: Quantum Physics and Reality by John Gribbin and more recent favourites How To Think Like A Neandertal by Thomas Wynn and Frederick L. Coolidge and Caffeinated: How Our Daily Habit Hooks, Helps and Hurts Us by Murray Carpenter. But this one was by far the most technical piece I have read. Second I am grateful for digital lending libraries, this volume would have been way out of my price point for a leisure read. And third I stumbled across this while writing a review for the novelization of the Terraforming Mars game, a novel; In the Shadow of Deimos by Jane Killick Terraforming Mars Book 1. 

This volume was a stretch for me. Both in content and theory. But I took my time and worked my way through it. Some of the scientific notations are well beyond my grasp, but the theories for the most part were easily accessible. The volume is edited by Martin Beech, Joseph Seckbach and Richard Gordon. The chapters sections and subsections of the book are:

Preface 

Part 1: Introduction 

1 Terraforming and Colonizing Mars 

Giancarlo Genta

1.1 Introduction 

1.2 Earth: A Terraformed Planet 

1.3 Planetary Environments 

1.4 Terraforming Mars 

1.5 The Role of Solar Wind 

1.6 Ethical Aspects 

1.7 Venus, Moon, Titan… 

References 

Part 2: Engineering Mars 

2 Terraforming Worlds: Humans Playing Games of Gods 

Nilo Serpa and Richard Cathcart

Early Mars 

Oceans Here and There 

The Mars We are Creating Here 

Mars: An Arena of Delusions? 

References 

3 Mars, A Stepping-Stone World, Macro-Engineered 

Richard B. Cathcart

3.1 Introduction 

3.2 Mars-Crust as Kinetic Architecture 

3.3 A Crust-Infrastructure Mixture 

3.4 Infrastructure and Life-Styles 

3.5 Atmosphere Enhancements for Mars 

3.6 Between Then and Now 

Acknowledgments 

References 

4 Efficient Martian Settlement with the Mars Terraformer Transfer (MATT)

and the Omaha Trail 

Gary Stewart

4.1 Introduction 

4.2 Construction Efficiencies of MATT’s Small-Scale Terraformation 

4.2.1 Impact Terraformation for Settlement 

4.2.2 Impactor Redirection with DE-STARLITE 

4.2.3 Subaqueous Hab Network at Omaha Crater 

4.3 Provisioning Efficiencies of the Omaha Trail 

4.3.1 Deimos Dock 

4.3.2 Mars Lift 

4.3.3 Arestation 

4.3.4 Deimos Rail Launcher (DRL) 

4.4 Cosmic Ray Protection: From Omaha Trail to Omaha Shield 

4.5 Conclusion 

References 

5 Mars Colonization: Beyond Getting There 

Igor Levchenko, Shuyan Xu, Stéphane Mazouffre, Michael Keidar

and Kateryna Bazaka

5.1 Mars Colonization – Do We Need it? 

5.2 Legal Considerations 

5.2.1 Do Earth Laws Apply To Mars Colonists? 

5.2.2 Sovereignty 

5.2.3 Human Rights 

5.2.4 Abortion 

5.3 Ethical Considerations 

5.3.1 General 

5.3.2 Human Reproduction – Ethical Considerations 

5.3.3 Social Isolation and No Privacy – Rolled into One 

5.3.4 Advocacy for Mars – is it Ethical at All to Colonize it? 

5.4 Consideration of Resources 

5.5 Quo Vadis, the Only Civilization We Know? 

5.6 Afterword. Where are We Three Years Later? 

5.6.1 Current Programs and Their Status – in Brief 

5.6.2 Any News About Mars? 

5.6.3 Tasks and Challenges 

Acknowledgements 

References

Part 3: Ethical Exploration 

6 The Ethics of Terraforming: A Critical Survey of Six Arguments 

Ian Stoner

6.1 Introduction 

6.2 Audience and Method 

6.3 Preservationist Arguments 

6.3.1 We Should Preserve Mars’s Value as a Unique Object

of Scientific Interest 

6.3.2 We Should Preserve the Integrity of the Martian Wilderness 

6.3.3 We Should Avoid Expressing Colonialist Vices 

6.4 Interventionist Arguments 

6.4.1 We Should Fulfill our Inborn Nature as Pioneers 

6.4.2 We Should Increase Our Species’ Chance of Long-Term Survival 

6.4.3 We Should Rehabilitate Mars for Martians 

6.5 Conclusion 

Acknowledgments 

References 

7 Homo Reductio Eco-Nihilism and Human Colonization of Other Worlds 

Kelly Smith

7.1 Introduction 

7.2 Implicit Assumptions 

7.3 Conclusion 

Acknowledgements 

References 

8 Ethical, Political and Legal Challenges Relating to Colonizing

and Terraforming Mars 

Konrad Szocik

8.1 Introduction 

8.2 Ethical Issues in Colonizing and Terraforming Mars 

8.3 Ethics of Human Enhancement for Space 

8.4 Environmental Ethics in Space 

8.5 Political Issues in Colonizing and Terraforming Mars 

8.6 Legal Issues in Colonizing and Terraforming Mars 

8.7 Sexual and Reproductive Laws in a Mars Colony 

8.8 Migration Law in Space 

8.9 Why Terraforming Mars May Be Necessary from Ethical, Political

and Legal Perspectives 

8.10 Conclusions 

References 

Part 4: Indigenous Life on Mars 

9 Life on Mars: Past, Present, and Future 

Martin Beech and Mark Comte

9.1 A Very Brief Historical Introduction 

9.2 Indigenous Life: Past and Present 

9.2.1 Beginnings 

9.2.2 The Viking Experiments 

9.2.3 Martian Meteorites 

9.2.4 In Plain Sight 

9.3 Seeded Life: The Future 

9.4 Per Aspera ad Astra 

References 

10 Terraforming on Early Mars? 

M. Polgári, I. Gyollai and Sz. Bérczi

10.1 Introduction 

10.1.1 Aspects of Biogenicity 

10.1.2 Methodology 

10.1.3 Multihierarchical System Analyses 

10.2 Outline of Section 10.2 

10.2.1 Review of Research on Martian Life 

10.2.2 Biosignatures in Martian Meteorites Based on Mineralogical

and Textural Investigation 

10.2.3 Biosignatures in Chondritic Meteorites 

10.2.3.1 Interpretations 

10.2.3.2 Clay Formation 

10.2.3.3 Interpretation No. 1 

10.2.3.4 Interpretation No. 2 (Preferred) 

10.2.4 Terrestrial Analogues of Biosignatures 

10.2.5 Implications to Terraforming of Ancient Life on Mars on the Basis

of Terrestrial and Meteoritic Analogues 

10.3 Novel Interpretation of the Formation Process Based on Mineral

Assemblages 

10.3.1 Martian Meteorites 

10.3.2 Interpretation of Mineral Assemblages on Mars 

10.3.3 Novel Interpretation of Mineral Dataset of Exploration

of Curiosity in Gale Crater 

10.4 Conclusion 

Acknowledgment 

References 

Part 5: Living on Mars 

11 Omaha Field – A Magnetostatic Cosmic Radiation Shield for a Crewed

Mars Facility 

Gary Stewart

11.1 Introduction 

11.2 Methods 

11.2.1 Software 

11.2.2 Testing 

11.3 Design 

11.3.1 Crater 

11.3.2 Current 

11.3.3 Circuits 

11.4 Results 288

11.4.1 Shielding Against 500 MeV Protons 

11.4.2 Shielding Against 1 GeV Protons 

11.4.3 Shielding Effectiveness in the Mars Environment 

11.5 Discussion 

11.5.1 Electrostatics 

11.5.2 Refrigeration 

11.5.3 Self-Shielding Solenoids 

11.5.4 Alternate Self-Shielding and Source-Shielding 

11.5.5 Safety in Transit Across Crater Rim 

11.5.6 Safety in Spacecraft Launch and Landing 

References 

12 Mars Future Settlements: Active Radiation Shielding and Design

Criteria About Habitats and Infrastructures 

Marco Peroni

12.1 Introduction 

12.2 The Problem of Cosmic Radiations 

12.3 The Protection System with Artificial Magnetic Fields 

12.4 Details of Our Proposal 

12.5 Further Developments 

12.6 Modular Settlement on Mars 

Acknowledgments 

References 

13 Crop Growth and Viability of Seeds on Mars and Moon Soil Simulants 

G.W.W. Wamelink, J.Y. Frissel, W.H.J. Krijnen and M.R. Verwoert

13.1 Introduction 

13.2 Materials and Methods 

13.2.1 Regoliths 

13.2.2 Species Selection 

13.2.3 Organic Matter and Bacteria 

13.2.4 Experimental Design 

13.2.5 Harvest and Measurements 

13.3 Results 

13.3.1 Fruit Setting and Biomass 

13.3.2 Seed Weight and Germination 

13.4 Discussion 

13.5 Outlook Issues for the Future 

Acknowledgements 

References 

Appendix 

14 The First Settlement of Mars 

Chris Hajduk

14.1 Introduction 

14.2 Colony Location 

14.3 Colony Timeline 

14.3.1 Setup Phase 

14.3.2 Investment Phase 

14.3.3 Self-Sufficiency 

14.4 Colony Design 

14.5 The Basics – Power, Air, Water, Food 

14.5.1 Food 

14.5.2 Water 

14.5.3 Air 

14.5.4 Power 

14.6 The Material World 

14.6.1 Metals 

14.6.2 Plastics 

14.6.3 Ceramics and Composites 

14.6.4 Mining 

14.7 Exports, Economics, Investment and Cash Flow 

14.7.1 Interplanetary Real Estate 

14.7.2 Intellectual Property Export 

14.7.3 Research Tourism 

14.7.4 Investment and Cash Flow 

14.8 Politics – A Socialist’s World 

14.9 Conclusion and Further Thoughts 

References 

Part 6: In Situ Resources 

15 Vulcanism on Mars 

Ian M. Coulson

15.1 Introduction 

15.2 Martian Geology 

15.2.1 Mars: Creation and Thermal Evolution 

15.2.2 The Martian Crust 

15.3 Vulcanism 

15.3.1 Types of Volcanoes 

15.3.1.1 Earth 

15.3.1.2 Mars 

15.3.2 Recognition of Other Styles of Vulcanism 

15.3.3 Martian Meteorites 

15.3.4 Is Mars Still Volcanically Active? 

References 

16 Potential Impact-Related Mineral Resources on Mars 

Jake R. Crandall, Justin Filiberto and Sally L. Potter-McIntyre

Introduction 

Terrestrial Ore Deposit Types Associated with Impact Craters 

Progenetic Deposits 

Syngenetic Deposits 

Epigenetic Deposits 

Martian Target Craters 

Ritchey Crater 

Gale Crater 

Gusev Crater 

Conclusions 

References 

17 Red Gold – Practical Methods for Precious-Metal Survey, Open-Pit

Mining, and Open-Air Refining on Mars 

Gary Stewart

17.1 Introduction 

17.2 Martian Precious-Metal Ore from Asteroids 

17.3 Martian Precious-Metal Survey and Physical Assay 

17.4 “Mars Base Alpha” – A Red Gold Mining Camp 

17.5 Semi-Autonomous Open-Pit Mining 

17.6 Comminution and Separation of Meteorite Ore 

17.7 Extracting Metals with Induction/Microwave Smelter 

17.8 Refining with Hydrometallurgical Recovery and the Miller Process 

17.9 Separating Precious Metals with Saltwater Electrolysis 

17.10 Kovar Foundry 

17.11 Maximizing ISRU, Minimizing Mass and Complexity 

17.12 Scale-Up and Scale-Out 

17.13 Conclusion, with Observations and Recommendations 

References 

Part 7: Terraforming Mars 

18 Terraforming Mars: A Cabinet of Curiosities 

Martin Beech

18.1 Introduction and Overview 

18.2 Planet Mars: A Brief Observational History and Overview 

18.3 The Beginnings of Change 

18.4 The Foundations 

18.5 First Blush 

18.6 Digging In 

18.7 (re)Building the Martian Atmosphere 

18.8 Magnetic Shielding 

18.9 Heating the Ground 

18.10 A Question of Time 

18.11 Conclusions 

References 

19 Terraforming Mars Rapidly Using Today’s Level of Technology 

Mark Culaj

19.1 Introduction 

19.2 Solar Wind 

19.2.1 Solar Wind Abundances 

19.2.2 Magnetic Lens 

19.3 Conclusions 

Acknowledgments 

References 

20 System Engineering Analysis of Terraforming Mars with an Emphasis

on Resource Importation Technology 

Brandon Wong

20.1 Summary 

20.2 Introduction 

20.3 Key Problem 

20.4 Key Stakeholders 

20.5 Goals 

20.6 Macro Level Alternatives 

20.6.1 Terraforming 

20.6.2 Paraterraforming 

20.6.3 Bioforming 

20.7 Macro-Level Trade Study 

20.8 Macro-Level Conclusions 

20.8.1 Concept of Operations 

20.8.2 High-Level Requirements 

20.8.3 Requirements Decomposition 

20.8.4 Macro High-Level Design 

20.9 Terraforming Efforts System - Detailed Requirements 

20.10 Space Transportation System 

20.11 Importing Resources Subsystem 

20.11.1 Resources Needed 

20.11.2 Resource Locations 

20.11.3 Subsystem Needs 

20.11.3.1 Subsystem Goals for Importing Resources Subsystem 

20.11.3.2 Detailed Requirements for Importing Resources Subsystem 

20.11.3.3 Alternatives for the Importing Resources Subsystem 

20.11.3.4 Importing Resources Trade Study 

20.11.3.5 Findings 

20.11.3.6 Importing Resources Subsystem Design 

20.12 Risks 

20.12.1 Macro-Level Risks 

20.12.2 Importing Resources Subsystem Risks 

20.13 Lean Strategies 

20.14 Ethical Considerations 

20.15 Overall Conclusions 

20.15.1 Proposed Implementation Plan 

20.16 Acknowledgements 

20.17 Appendix 

20.17.1 Requirements Flowdown to System Implementation 

References 

21 The Potential of Pioneer Lichens in Terraforming Mars 

Richard A. Armstrong

21.1 Introduction 

21.2 Potential Role of Lichens in Terraformation 

21.3 Exploiting Indigenous Lichens

21.4 Exploiting Lichen Symbionts on Mars 

21.5 Inoculating Lichen Symbionts from Earth Cultures 

21.6 Transplanting Terrestrial Lichens to Mars 

21.7 Conclusions 

References 

Index

The table of contents is several pages and the index at the end spans 12 pages of double columns. I want to say I could not put the book down. But I had to put it down. Many of the pieces required thought and reflection before moving on. Not just looking at the technical implications, and various theories of the how, but looking at the questions of ‘How?’ and even “If?” we much more impactful. During one of my breaks from reading this, as I often only read a section or sub section a day I read a novel written by a different scientist. Under An Orange Sky by Manuel Alfonseca Solar System Book 1 when I picked it up, I was unaware it was the first in a trilogy, but it raises the question of should we Terraform Mars even if it would mean the elimination of native life, and in this case life with deep intelligence, but simple appearing lifeform. 

I have mentioned this book to numerous people. It is one of those volumes I will be talking about for years. Much like How To Think Like A Neandertal mentioned at the beginning, this volume has stayed with me days and night over the over 2 months it has took me to read, and will stay with me for a long time to come. If you can lay your hands on it I can easily recommend it, no matter how much a stretch it is. It is an excellent read!

Related Fiction:

Jane Killick's Terraforming Mars Series:

In the Shadow of Deimos

Edge of Catastrophe

…

Manuel Alfonseca's Solar System Series:

Under an Orange Sky

Descent into the Hell of Venus

Operation Quatuor

...