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Unveiling the Mystery of Terraforming Mars

The idea of transforming Mars into an Earthlike planet – terraforming – is captivating but also anxiety-inducing. Could we turn the Red Planet into a lush, habitable world? Is the dream of human-driven interplanetary colonization just around the corner? The Institute for Health Metrics and Evaluation Reveals The State of Health Care Worldwide Terraforming Mars. If we reshape human civilization and send a fleet of ships to colonize Mars, we will need a secure and reliable home. Terraforming is a moving concept because it represents the ultimate adventure – excellent. If we can replace the Martian landscape with something more like we have on Earth, we could shift our human ‘frontier’ to the other planetary body in our solar system. This would represent an enormous leap forward for our evolving interplanetary civilization. Where are we now in terms of terraforming Mars, and where do we want to go?

What is Terraforming?

Terraforming or Earth-shaping is modifying a planet’s environment to make it more like Earth’s. For Mars, this means altering the surface by changing its atmosphere, temperature, topography, and ecology to support human and other Earth life forms.

Mars The Next Frontier

Mars, regarded as the most terrestrial and thus the most feasible planet to terraform in our solar system, shares many qualities with Earth: a day length and size, polar ice caps, and possibly subsurface water. Its troubles—its cold temperature, tenuous atmosphere, and lack of a magnetic field—have distinctive features, too.

The Allure of the Red Planet

Humans have been mesmerized by Mars for centuries. Its familiar red, rosy color, visible to the naked eye, has allowed it to breed innumerable myths and fables and spark many scientific studies. Today, Mars is imbued with mystery, promising to be a new world—a second home for humanity. 

The Science and Speculation of Mars Terraforming

In a future technological era, terraforming the red planet would be a multifaceted feat, entailing such speculative engineering processes as constructing ‘mega mirrors’ to redirect sunlight, loading the atmosphere with hothouse gases, and indiscriminately draining the northern and southern ‘polar caps’ of their ice to generate a rain-fed ocean over centuries. These ideas are theoretically plausible, but they will require us to apply our technological ingenuity in a way that has not yet been done, an advanced understanding of Martian climatology and geology, and more time.

Challenges and Controversies

One can imagine why Mars is being considered. Terrestrial raw materials, including water, ice, dust, and carbon dioxide, are readily available. The challenges involved in terraforming Mars are technical and ethical, and they are challenging to contemplate. The energy demands of such a project are beyond most imagining. With presently available energy supplies, it could take thousands of years to complete the project. Terraforming could seriously affect the chemistry and biology inherent in the Martian soil if life already exists. The rights of others to modify the planetary environment have not been settled ethically or politically. People have wildly different assessments.

Vision for the Future

Still, it persists as a source of empowered fantasy. If Elon Musk succeeds in seeding Mars, it’ll stand as proof of humanity’s survival and our expansion into new realms of knowledge and experience, all while increasing our capacity to evolve into human beings. The road to Martian terraforming is less about altering a planet than creating more humans. 

To understand the story of terraforming Mars is to explore the ultimate questions of our nature and purpose in the cosmos, for which we are prepared to go to any lengths to secure our survival. The road to Mars terraforming is a mirror to ourselves on Earth, where our problems and hopes accelerate the challenge of being human to another level, prompting us to find ways to settle our footprints on other worlds. 

Historical Context and Progress

The story of how we might come to terraform Mars is fascinating—and confounding. You can chart it on any graph and smear it across any timeline. Still, it starts in science fiction and transitions halfway across the page into serious scientific deliberation and action. 

Once considered only the realm of science fiction, experiencing a recent crop of movies, the actual study of terraforming – altering a planet’s environment to make it more like that of Earth, especially as it pertains to humans – is becoming a subject for serious scientific discussion. A brief introduction to the history of terraforming Mars might be the story of humanity – of curiosity and ambition, of reaching a greater understanding.

Mars became imbued with speculations about life—and even civilizations—due to the misinterpretation of Martian surface features by late-19th—and early-20th-century astronomers such as Percival Lowell. Those speculations gave rise to a popular following and catalyzed thinking about Mars as a potential destination for humanity.

Forward to the space age, when the first successful Mars missions delivered a resounding millennial reality check: a desiccated, lifeless rock. But instead of dampening enthusiasm, these findings redirected attention to adapting Mars to its investigators.

Since the Viking landers of the 1970s, a steady stream of Mars missions by NASA, ESA, and other space agencies—most recently the SpaceX robots Perseverance and Ingenuity—have added to this understanding of Mars, focusing on the goal of colonizing and terraforming the planet. From the exploratory aspect of finding life, the desire to work towards making Mars our second home is vastly different from minimal interaction with other planets.

This historical sequence acknowledges that while terraforming began as a literary conceit, it has become a scientific project and engineering enterprise. It foregrounds the stages our understanding of Mars has progressed through, the hardware we have developed to get there, and the changing ways we might engineer the planet to make it a place where someone could eventually live.

The eventual journey toward terraforming Mars is not simply the tale of successful science and technology but also of humans’ will to extend life beyond its current cradle and overcome the colossal obstacles to interplanetary transformation. 

Scientific Principles Behind Terraforming Mars

In essence, terraforming (from the Latin terra, meaning ‘Earth,’ and the suffix forums, meaning ‘formed’) is how a planet’s environment is modified so humans can inhabit it. That’s a lot of preemption. It requires deep knowledge of planetary science, atmospheric chemistry, climatology, and astrobiology.

But, forming Mars would entail massive alterations to the atmosphere, temperature, and the nature of the surface. The key objectives are to increase atmospheric pressure, temperature, and oxygen levels to the point where humans can survive outside of space suits and life-support systems and where a self-sustaining biosphere can begin to flourish.

Atmospheric Enhancement

A significant barrier is that Mars’ thin atmosphere (which consists of more than 95 percent carbon dioxide, augmented by nitrogen and a little argon) would initially be one-hundredth of Earth’s atmospheric pressure. Converting the planet’s environment would mean adding more pressure and oxygen to the atmosphere—whether from gases Mars buries within its soil or volatile compounds elsewhere in the solar system.

Temperature Regulation

Mars’ mean surface temperature is around -60 degrees Celsius (-80 degrees Fahrenheit), way too cold for Earthlike life, so hence the need to warm the planet. Technologies under consideration include greenhouse gas accumulation (to retain solar radiation), nuclear-powered heat generators, and large mirrors in space to reflect more sunlight onto the surface.

Water Recovery and Management

At the deepest instinctual level, water means life. It seems increasingly likely that Mars’s surface was once dotted with lakes and rivers—that liquid water did flow out in the open. Terraforming will connect to these wells, these buckets of ancient water that were once free. Some of that ancient water might be sequestered in permafrost or subsurface aquifers, which warming the planet would help unbind and flow freely as lakes, streams, or oceans.

Soil Fertility and Ecosystem Creation

Mars’ fertilizer must do much work to make the regolith a suitable planting medium. Organic plant material might need to be imported, or the soil might be enriched with fixed nitrogen through engineered bacteria or other bioengineering treatments. A stable, self-sustaining ecosystem will likely need plants, microorganisms, and animals introduced in a carefully staged sequence to build a balanced biosphere gradually.

These scientific principles illustrate the magnitude and complexity of the task of terraforming Mars. They necessitate sophisticated technologies, many of which are created in the future, and a thorough comprehension of ecological and planetary dynamics. The task is Herculean, requiring technological innovation and an integrative approach to understanding such a transformative endeavor’s ethical, environmental, and societal ramifications.

Technological Advancements and Innovations

Whether terraforming could work is based partially upon theoretical science but hinges on new technological solutions that would eventually need to be invented (and many are being developed right now). Much work is required to make Mars’s surface habitable for people.

Robotic and Autonomous Systems

Robots and autonomous systems are leading the way in the exploration of Mars and will play a vital role in terraforming. They can drill, mine for resources, build habitats, and lay the groundwork for humans to arrive. These systems can work more adeptly in the harsh Martian environment thanks to rapid advances in robotics, artificial intelligence, and machine learning.

Space Transport and Habitat Construction

Improved space transport technology (e.g., SpaceX’s Starship rocket) would lower the cost of bringing materials to the surface of Mars and make it more feasible to transport humans. This would enable colonization efforts for life support, fuel, etc. We’ll also need a range of habitat-building technologies that make it cheaper and easier to construct structures on Mars, including improving habitats and increasing sustainability. This could be done by 3D printing with local materials.

Energy Production and Storage

To keep human beings alive on the Red Planet, the hunt is on for types of energy that won’t frustrate or kill them. Presently, the three front-runners for providing and storing energy on Mars include solar, nuclear reactors (derived from normal atomic fission), and, more in the future, wind. Whichever energy solution is introduced to Mars, it needs to be as efficient as possible, scalable, and able to survive in the Red planet’s conditions.

Life Support and Bioregenerative Systems

Air, water, and food will have to continue to be supplied, and certain kinds of waste products will have to be collected to make inhabiting the planet possible, even for a short time, and to prolong life. This must be accomplished using advanced techniques such as closed-loop life support systems, which recapture waste products and regenerate resources, recycling them to support human life in an earth-like system.

Terraforming Technologies

While only conceptual and experimental so far, these technologies for terraforming—atmospheric processors to increase the level of oxygen, greenhouse-gas-production machines to warm the planet from the bottom up, and methods for mobilizing Martian water—would amount to an advanced suite of chemical engineering, atmospheric science, and ecological management. 

They share that it will still take all of their technological potential to realize the dream of terraforming Mars. These technologies represent the state of the art in interplanetary transformation and colonization. The story of terraforming Mars is also a saga of innovation, showing how technology and science will evolve to contend with the most extreme conditions humans have had to operate under. 

Ethical and Societal Implications

Terraforming Mars offers the chance to contemplate a whole galaxy of ethical, sociological, and philosophical implications, from the foundations of environmental ethics to the future of our species. 

Moral Responsibility to Martian Environments

The most fundamental ethical question is whether humans have the right to transform an entire planet. Put, should we have the ability and authority to change Mars’ natural state — perhaps eradicating any microbes or altering the landscapes it might have? The ethics of stewardship on Mars rest on how we respond to the question of our responsibilities to extraterrestrial environments and their possible native life forms.

The Societal Impact of Multi-Planetary Life

In addition to the technical and practical aspects, having a human presence on Mars will bring profound societal consequences. How will extraterrestrial colonies be governed? What are Martians’ rights and responsibilities? What is the nature of Earth-Mar’s socio-political relationships? If humans someday outgrow Earth, would Mars be the next refuge for humanity? Considering all the potential existential, legal, ethical, and moral implications, Mars terraforming becomes a more pressing undertaking than simply a nice side-project of space exploration.

Economic and Resource Equity

Terraforming Mars would also entail massive resource usage, leading to issues of resource and equity. Who gets what and when? Could futuristic space missions and colonization projects further increase inequalities on Earth? Are the money and materials spent on space projects better spent on our communities’ needs and priorities? The ethical issues raised by rising terrestrial inequalities regarding space deserve careful and thoughtful consideration. 

Cultural and Historic Preservation

As a locus of humanity’s concerns, hopes, and fears, Mars is more than just a world; it is a cultural object. Questions of ethics concern the balance between exploiting Mars as an object of exploration on the one hand and of culture or memory on the other and between the traditional scientific values of curiosity and let alone on the other.) 

Informed Consent and Participation

Ethical questions arise about who is granted the power to decide over terraforming Mars and who reaps the benefits. These questions involve empowering international communities, scientists, and the public to make such decisions based on principles of informed consent and participatory governance.

As much as the science and engineering challenges of terraforming are fundamentally open-ended, ‘ethical terraforming’ likewise requires courage of imagination, inclusivity, and multidisciplinarity if humanity’s quest for a habitable Mars is to be nested within a broader ethic and way of life that ensures it as part of a mutually sustainable, equitable, and flourishing human interplanetary future.

Economic Perspectives

Along with significant environmental and astronomical considerations, terraforming Mars has enormous economic implications and ramifications. The Political Economy of Terraforming Mars is about the cost of terraforming Mars, its investment, expected returns, and the bigger-picture economic implications on Earth if humans successfully terraform the Red Planet.

Cost and Funding

Terraforming Mars would be incredibly expensive—the estimates run into trillions of dollars—and would likely require public, private, and international investment, coalition-building, and innovative financial mechanisms. As would private companies and, perhaps, international consortia, national space agencies would have to sink considerable money into research, development, and infrastructure.

Economic Benefits

Levin says that the economic benefits of terraforming Mars down the line could be very significant, citing the creation of new industries (for example, space tourism), new markets such as Martian raw materials, and technology spin-offs with applications on Earth. ‘Innovation tends to be spurred by the development of new technology and new areas of endeavor,’ he notes. ‘So human beings exploring space would benefit and stimulate the economic growth of the country getting involved.’ 

Resource Utilization

It would divert resources from elsewhere and repurpose them for Mars. There are valuable minerals and metals, water, ice, and other resources that would be highly useful in this endeavor and Earth’s economy. We must develop efficient technologies to mine, process, and transport resources from Mars.

Economic Risks and Uncertainties

The economic risks from the fact that terraforming Mars is a lengthy enterprise, lasting tens or even a few hundred years, must be considered. Cost overruns, technological breakdown, or the possibility that Mars throws climate surprises at us all add to financial risk. Many uncertainties require detailed economic planning and risk mitigation.

Global Economic Impact

Terraforming Mars could dramatically change the current distribution of the global economy, be it through a change in focus and allocation of capital or shifting global markets.

Environmental Considerations

The transformation of Mars offers enormous environmental challenges. Given that terrestrial ecosystem engineering deals with changes to the specifics of our planet, reflecting on the shifts to the biosphere of an entire planet’s ecosystem moving from its original state to one suitable for Earthlike life raises much more profound questions. These go far beyond the environmental changes that may occur on Mars and its moons, ranging from questions of planetary ecology to the ethics of the management of celestial bodies.

Impact on Martian Ecology

Courtesy Wikimedia/NASAA second consideration is purely environmental. From a deep perspective, the deeper Martian ecology is essential. Although Mars is barren, it is part of Earth’s family of weakly inhabited planets, with surface pressures and temperatures in common. There could be potential micro-life or geological features we want to preserve before radically transforming the planet. We must understand the long-term environmental effects of changing Mars’ climate, the risk of disrupting or destroying any extant life forms, and potentially scientifically meaningful geological features as an integral part of deep Mars’ natural heritage.

Technological Interventions and Sustainability

Since terraforming heavily relies on atmospheric engineering, water resource acquisition and redistribution, and climate engineering, the risk remains that these numerous techno-ecological interventions could have adverse ecological consequences. This unacceptable risk must be prevented, especially considering unregulated economic activity threatens the Mars-Earth ecosystem.

Planetary Protection and Contamination

Planetary protection protocols help separate Earth and Mars without biological cross‑contamination. Terraforming Mars, however, introduces Earth’s life forms to Mars—a fundamental part of the process. It will require a careful balance between human interests and maintaining the integrity of ecosystems on both planets.

Ethical and Legal Frameworks

Even the environmental challenges of terraforming Mars are framed in ethical and legal terms. These include which life forms might have a claim to protection as indigenous Martian species, whether Mars as a celestial body will have legal status, whether it might constitute a global biosphere of its own, and whether changing a climatic regime of any world on such a profound and remorseless basis is morally acceptable. We must increasingly develop international treaties and agreements to reflect these ever-changing ethical considerations as they shape our environmental future. 

Long-term Ecological Monitoring and Management

Because terraforming will take a long time and cover vast areas of the planet, acceptable long-term goals for ecological monitoring and management should be developed in advance. These goals would help to steer Mars’s long-term transformation so that changes become less of a hindrance to the planet’s native state and more conducive to supporting humans as new inhabitants.

In conclusion, the environmental ramifications of terraforming Mars require a nuanced, scholarly approach that balances the goal of bringing human habitation to Mars with respect for its existing, perhaps unique natural environment. The effort to terraform Mars asks big questions of human technology. Still, its most significant challenges lie in developing our environmental values and conceptions of stewardship on a planetary scale. 

Legal and Political Landscape

Terraforming Mars belongs to the space between law and politics, and like Mars, it occupies legal and political spaces that are as challenging, otherworldly, and unexplored as the eventual landscapes of the Red Planet. The process of terraforming strikes not only at scientific and engineering issues but also at problems of international law, space governance, and interplanetary politics. 

Space Law and Sovereignty

As it stands, outer space, including Mars, is the common heritage of humanity, and no territory may legally belong to any state. Under current space law, as enshrined in the Outer Space Treaty of 1967 and other agreements, no part of space or adjacent celestial bodies (meaning Mars) can be appropriated by a state or any other entity. Terraforming all this would bring up knotty issues of sovereignty and jurisdiction over Mars and raise questions about who would have property rights. The legal framework for addressing these will need to be worked out. This will require great creativity, consensus, and international cooperation.

International Cooperation and Conflict

Because the terraforming effort on Mars seems destined to be multinational, these issues require unprecedented levels of international cooperation before they can be satisfactorily resolved. What is Mars’s governance structure going to look like? How will decisions be made, and what rules will be used to manage resources that must be handled in common? How will the scientific, technological, and economic gains from Mars terraforming be shared among nations, and what politics might result should some ideas about sharing fail?

Regulatory Frameworks

We also need to develop robust regulatory frameworks for the terraforming/colonization process itself and the emerging realities that will arise once it begins. This includes environmental protection and planetary protection regimes, adequate health and safety standards for Martian settlers, and a general framework for exploiting and utilizing Martian natural resources, with appropriate provisions to adapt to the changing dynamics that will unfold over time.

Ethical Governance

Beyond the legal and political controls, people must figure out how to terraform Mars ethically. Ethical governance will be necessary to guide decisions about how people should interact with Mars and its environments based on moral considerations and the best interplanetary ethical principles we can articulate. That is to say, terraforming Mars in the future will need to take account of the interests of Earthlings and Martians, including potential Martian ecosystems, tomorrow and into the future, as well as the interests of all the stakeholders and the fair treatment of those who haven’t yet decided whether they will be engaged on Mars, here or elsewhere.

Public and Private Sector Roles

That leads to assessments of the respective roles of the public and private sectors in terraforming Mars, which have found their way into legal and political discourse. The role of private actors and private companies like SpaceX and others who want to or are planning to explore space and even terraform Mars creates enormous problems as issues about responsibility, accountability, and governance become inflated. It is a constant struggle to navigate the boundaries between the realm of private commercial interests and that of the global public interest.

In short, the legal and political framework governing the terraforming of Mars will be challenging and dynamic. It will require careful balancing of international law and norms, political cooperation and coordination, rule-making, ethical regulation, and balancing public and private interests. As we inch ever closer to transforming Mars into a physically hospitable planet, the legal and political aspects of the situation emerge as essential factors in ensuring that this transformative endeavor – one that humanity has awaited for millennia – is conducted in a manner for the benefit of all humankind, fairly and sustainably. 

Future of Terraforming Mars

The potential for terraforming Mars is a unique vision for the future that contains elements of hope, science, and a bit of science fiction. Fuelled by decades of exploration, argument, and research, this vision relies upon evolving technology, emerging ethics, and the collective effort needed to make Mars a livable planet. 

Technological Milestones and Innovations

Of course, the practicality of terraforming Mars is also strongly dependent on the passage of time. Advances in technology will play an essential role in this respect. Future developments in space travel and habitation, in environmental engineering and life support systems enabling us to make the long journey to Mars and undertake large-scale planetary engineering projects safely and cheaply, will have to be made.

Scientific Understanding and Research

This imperative makes it crucial to continue improving our scientific understanding of Mars, which remains an active research area. Ongoing and future missions to Mars will increase our knowledge of its geology, atmosphere, and climate and perhaps find signs of life on the Red Planet. This new information will profoundly affect future terraforming design, enabling researchers to predict how the design would affect Mars and anticipate potential problems.

Interplanetary Society and Culture

The transformative social implications of a terraformed Mars include changes in notions of human selfhood and positionality in the cosmos. They will be at the heart of emerging interplanetary societies and cultures (the novel social organization of Mars, including governance and socializing rules, community life, and contractual schemes).

Ethical and Environmental Stewardship

The ethical debate over terraforming Mars will continue to develop. Policies about how humans should protect and preserve Martian environments and life forms will be considered integral to our obligation to respectfully treat celestial bodies and the cosmos. Such policies of ethical stewardship and sustainability would be directly relevant to any terraforming, accompanied by the goal of maintaining Earthlike biomes and environments on Mars. 

Global Collaboration and Participation

Mars terraforming might represent an unparalleled global collaboration between governments, international space agencies, and private entities.

The Role of Public Perception and Media

Public perception and media remain vital in the political and financial support required to undertake such a massive scientific and engineering task as terraforming Mars. The narrative about terraforming Mars stems from public perception and media coverage, which then permeate every other aspect of this debate, including policy decisions and the ability to marry space as a thing to the space industry as a verb. 

Influencing Public Opinion

Media narratives about Mars and terraforming impact people’s feelings about the issue by creating a diffusion of influence. Normative evaluations are contagious such that readers are likely to become optimistic about Mars according to the tone of the coverage – or turn more skeptical and critical. How the media conveys the plausibility, dangers, and ethical stakes of terraforming has powerful consequences for shaping the public mood and, by extension, policy and resource commitments.

Educational Outreach

Media is a vital vehicle for educating the public and the politicians, scientists, and engineers who might ultimately shape decisions about Mars on the nuances and realities of terraforming. Documentaries, news coverage, papers and open journalism, and other forms of education and outreach could be employed to illustrate the ways terraforming would change the planet, what ways this technology is currently feasible and not, the technological, environmental, and societal complexities of participating in and responding to such a monumental feat, and much more. If a better-educated public is called for when it comes to space colonization, it is also necessary if Mars terraforming of any kind is on the horizon. 

Inspiring Future Generations

Media representations of Mars terraforming can help inspire future scientists, engineers, and policymakers. The stories of exploration and innovation that develop around the concept of terraforming can be part of the broader effort to engage the next generation in science, technology, engineering, and mathematics (STEM) to build the population of those who will contribute their skills in service of a human Mars. 

Media as a Platform for Debate

Moreover, the media might play a role in arguing about the ethical, legal, and environmental implications of whether Mars should be terraformed and, if so, how. By hosting such conversations and ensuring that they encompass alternative viewpoints, media outlets can facilitate a balanced and nuanced discussion of how humanity should pursue astronomical goals such as terraforming Mars. 

Public Engagement and Support

Finally, drawing public interest and support is crucial to encouraging the Earth’s people and government to fund and promote the terraforming of Mars. Enthusiastic public support translates into funding, political backing, and a social will to embark on this long-timescale change. Media is there to engage the people in the implementation stage, connecting them with the vicissitudes of the project through both setbacks and successes.

Finally, I come back to how public perception and media also form the core of the Mars mission. They don’t just inform and educate but also inspire and unify the global population in a shared cultural and societal understanding of one of the most ambitious and transformational projects humankind has ever dreamt of pursuing. 

Conclusion

Immense scientific, technical, ethical, and sociological considerations shape this broader story far beyond the actual work of terraforming Mars. This story happens as humanity continues discovering what it means to be a multi-planetary species. The Synthesis brings all these considerations into a single vision of the future. 

Synthesis of Multidisciplinary Efforts

Terraforming Mars would be the ultimate gift to the multidisciplinary world, and it would entail involvement in astronomy, planetary science, engineering, ethics, and more. It would be the quintessential example of something that can’t be done successfully unless you draw from a broad set of intellectual disciplines.

Reflecting on Human Ambition and Responsibility

In this respect, the desire to change Mars into a planet of our own is a quintessential statement of human hubris – and our insistence upon extending our frontier of habitation ever outward. Terraforming Mars is also an expression of a profound moral imperative to proceed with care, respect the inherent quality of Mars, and think across the political boundaries of time in terms of what we are doing to Mars and what we are doing to Earth. 

Emphasizing Sustainability and Ethical Stewardship

Questions about sustainability and responsible stewardship emerge as crucial starting points in the conversation about terraforming Mars. As humans plan potential terraforming activities, they must prioritize sustainable practices that maintain the well-being of Mars’ environment and explore the ethical considerations of altering a planetary ecosystem.

Global Collaboration and Future Generations

Terraforming Mars is a responsibility to future generations, to the generations beyond us who will have to follow through. This is something for all of humanity. It means global cooperation with shared goals. It implies a planet we leave behind that our children and their children can continue to reclaim and make sparkle. Terraforming Mars can give us a mutual purpose and a mission bigger than ours. 

Imagining a New World

In the end, all we’re left with is that tantalizing image – terraformed Mars, a monument to human ingenuity and an enormous gamble on the continued development of human civilization, a home for life in the universe, and a labor of love to seal the deal of human life in the cosmos. 

 Finally, terraforming Mars is our future—or rather, it is our future to make it. It is a dream worthy of action because it will require the very best innovations we can bring to humanity’s grandest and most inspiring feat of dreaming—if also of staring—which we have yet to attempt. It will speak across the ages and to the stars. It will be our legacy for all that we are to become. 

FAQ

What is terraforming?

Terraforming is a set of techniques intended to change a planet’s or moon’s environmental conditions so that they are comfortable for Earth-like life forms, especially human beings. The atmosphere, temperature, surface features, and ecology have been changed to support Earthly life forms.

Why is Mars considered a viable candidate for terraforming?

The planet with polar ice caps, seasons, water hiding under its soil, a day length nearly identical to Earth’s, and a planet rich in carbon, nitrogen, and hydrogen could be ripe for terraforming. Mars could be it.

How long would it take to terraform Mars?

As terraforming Mars is conjectural and depends on the technologies developed, both in scale and type, the timeline required to accomplish such an effort is still being determined. The range could be as brief as decades to hundreds of years.

What are the main challenges of terraforming Mars?

Thickening the atmosphere, getting a suitable composition, and raising the temperature, water resources, and biodiversity would be challenging. There are no apparent technologies for terraforming Mars or many obvious solutions. Doubts and uncertainties still plague us. Profound scientific, technological, and logistical advancements would be necessary to overcome these challenges.

Could terraforming Mars affect Earth?

Changes to Earth will be more indirect due to terraforming Mars; nevertheless, on Earth, technology, economics, culture, and policy will experience a broader shift in focus toward interplanetary expansion. Other environmental and logistical concerns over the allocation of resources will undoubtedly play a role.

Is terraforming Mars ethically justified?

Before overturning the Martian environment, huge ethical questions must be considered: What rights do we have to alter a planetary atmosphere? Is there a possibility of other life on Mars, and is there a moral imperative to extend human life to the planet? An ethical account of engineering the environmental conditions of Mars depends on weighing the tension between exploration and preservation, the benefits and risks of altering our solar system’s red planet, and evolutionary pathways that factor in immense humanity and its responsibility in planetary stewardship. 

How will terraforming Mars be funded?

Funding for terraforming Mars would likely come from public sector investment by space agencies, private sector contributions, international partnerships, and new economic models or funding mechanisms that can support long-term, large-scale space activities.

1. NASA’s Mars Exploration Program:https://mars.nasa.gov
   • This official NASA site offers extensive information on past, current, and future missions to Mars, including scientific research and findings relevant to the planet’s environment and potential for terraforming.
2. SpaceX’s Mars Plan:https://www.spacex.com/human-spaceflight/mars/
   • SpaceX’s vision for traveling to Mars, including plans for colonization and potential terraforming efforts, as envisioned by Elon Musk.
3. The Planetary Society – Terraforming Mars:https://www.planetary.org/articles/terraforming-mars
   • This page provides an overview of the concept of terraforming Mars, discussing the scientific and technological challenges and possibilities.
4. European Space Agency (ESA) – Mars Express:https://www.esa.int/Science_Exploration/Space_Science/Mars_Express
   • The ESA’s Mars Express mission provides valuable scientific data on Mars’ atmosphere, geology, and potential for water, all crucial for terraforming research.
5. Astrobiology at NASA – Life in the Universe:https://astrobiology.nasa.gov
   • This site explores the study of life in the universe, including the possibilities of life on Mars and how terraforming might impact Martian biology.
6. The Mars Society:https://www.marssociety.org
   • An organization dedicated to promoting the exploration and settlement of Mars, offering resources and discussions on terraforming Mars.
7. “Red Mars” by Kim Stanley Robinson:
   • A science fiction novel that extensively explores the terraforming of Mars, providing insights into potential scientific, social, and political aspects of the process.
8. TED Talks on Mars and Terraforming:https://www.ted.com/topics/mars
   • A collection of TED Talks from experts discussing various aspects of Mars, including terraforming, exploration, and colonization.

Interstellar Space colonization

The quest to become an interstellar civilization through Space colonization is human civilization’s most ambitious and visionary project. At stake is the ability of people to expand their civilization out into the galaxy, to other stars, and, ultimately, to other planets. In this introductory chapter, I want to set the stage for exploring what it means for human beings to become a civilization among the stars. I’ll tackle the primary issues and fundamental questions that can be asked of any attempt to engage in interstellar colonization.

It concerns theoretical humanity’s expansion into worlds beyond our solar system via colonization of the planets or moons of other stars (referred to as exoplanets). Unlike interplanetary travel within the solar system, which is a well-developed field and is in its early stages of colonization, interstellar travel entails distances so great that they require new physical principles, new propulsion technologies, and more international cooperation than has ever been accomplished.

Behind the push toward interstellar colonization are complex motives. Science: we want to understand and learn our role in our universe. Our species’ survival as well: a spreading of human enclaves around the cosmos could be a safeguard against the next rogue asteroid or nuclear holocaust. Then there’s that old, fearless spirit of exploration and the drive to seek what’s beyond the horizon. It has generated and will continue to produce all kinds of cosmic ramifications.

It’s the encounter of Big Science and Technology with Big Dreams. Realizing the dream of interstellar colonization is utterly daunting: it will require either faster-than-light (FTL) travel, mammoth generational starships, or sustained manned. These challenges raise serious ethical questions as well.

This section functions as a primer to the vast saga of interstellar colonization. What is it, why do we want to do it, and what will it take from us regarding ingenuity and courage? Motivation: our fear of death drives our desire to colonize the cosmos. Humanity has set its sights on the stars. In preparing to embark on this cosmic journey to a time and place vastly different from where we find ourselves today on an average, undistinguished day on Earth, we enter into one of the great unknowns of our species, which is both scary and invigorating. We do it because it is human nature to explore, seek out new horizons, and push the envelope of human experience in ways that ensure our eventual survival across the vast unknown of the cosmos.

The Science Behind Interstellar Travel

Interstellar travel (the foundation of a multi-planetary, or even multi-galactic, civilization) is inherently much more complex: we might have to leap the entire Sethioearing directly to a new paradigm in science and engineering.

Understanding interstellar flight requires the ability to cross astronomical distances in finite timeframes. Proxima Centauri is the closest star system to the Earth, at 4.24 light years away. Even if we adopt the lower end of the range of fast propulsion systems we will build and use first; it would still take thousands of years. The practical need for propulsion that would slash voyage times to human-lifespan scales is a fact we must face. 

Two more promising theoretical propulsion technologies include light sails, which use the pressure of sunlight or high-powered lasers to achieve high speeds, and nuclear propulsion, which uses atomic reactions to generate high thrusts. These technologies still need to open up the stars, but they all show great promise.

Beyond the propulsion problem, interstellar science will demand self-contained life-support systems capable of maintaining human existence for decades or centuries, including food, breathable air, built-in hospitals, and ways to support physical and mental health in the deep space milieu.

Astronauts will also have formidable navigational tasks: interstellar voyagers will need highly reliable and accurate equipment to determine their position in this virtually infinite space, which follows tiny but potentially disastrous curving paths towards its distant destinations.

The science of interstellar travel is just as much a science of exploration as it is a science of departure – it encompasses not just the journey itself but everything that goes into making it possible, which is all the ranges of science that get drawn into service of the ambition to become a species that lives and thrives among the stars. This final section details the integrative nature of the science of the interstellar, demonstrating how it summons ingenuity and endurance to take the ‘blasted frontiers,’ as John Constable put it in The Opening of the Tidal Basin in Central Park (1916), into deep space.

Historical Milestones in Space Exploration

This long vision of interstellar colonization begins with a history of human endeavor in space that gathers momentum over a century of steady, unrelenting progress. Each milestone in the saga of space exploration has enriched our knowledge of our universe and our place within it and has also changed what the human species can achieve and do, expanding the scale of being human itself. This section briefly chronicles several of those pivotal aha moments in our skyward journey—the boldness and creativity of human spaceflight.

Sputnik 1, launched by the Soviet Union in 1957, is often considered the beginning of the space age, as it was the first Earth satellite to orbit Earth. The competition between the Soviet Union and the United States for exploration priority led to a series of missions that pushed the boundaries of human capabilities, including landing humans on the Moon in 1969 in the Apollo 11 mission – arguably one of the crowning achievements of human exploration.

The following decades have witnessed the transformation of the human space flight program from manned flights to the Moon to a fleet of complicated and sophisticated robotic probes and rovers to planets and moons thousands of times more distant. For example, the twin Voyager missions launched in 1977, whose probes provided humanity’s first close-up images of the outer planets, eventually escaping the solar system into interstellar space.

This new era of space exploration began with the development of reusable spacecraft, like the Space Shuttle, which flew from 1981 to 2011. It also included hundreds of scientific missions to space and the building, refueling, and servicing of the Hubble Space Telescope, expanding our cosmic horizons and understanding.

Space exploration has slowly ceded to a mixture of states and private companies, as NASA’s rovers land on Mars, the European Space Agency’s Rosetta Mission bangs on a comet, and SpaceX launches reusable rockets. Interstellar might be next. 

This isn’t meant to downplay the obstacles or importance of those historic milestones – each is a small leap toward humanity’s growing mastery of space. But those markers of the past are also the future and the legacy by which we will see interstellar colonization portrayed, uniting discovery and ingenuity as critical tenets of human exploration. 

Potential Targets for space colonization

Finding the ideal destinations for interstellar colonization is a vital part of the overall story – the ultimate purpose, if you like – of the search for galaxies teeming with habitable planets. One key milestone in that process is to examine the bodies in our system that leak our gaze into space, the distant worlds we are already dreaming of reaching. Which are the ones we might head for first? How far away are they, and what weather and conditions will we find there? How does any of this relate to life on Earth?

An example is Proxima Centauri b, an exoplanet located in the habitable zone around the nearest star to the Sun, Proxima Centauri. The possibility of the planet-hosting liquid water and Earth-like conditions has excited astronomers, with the possibility of it being a terraformed colony for us.

Second, it’s not too far outside our immediate stellar neighborhood, the system of seven Earth-sized TRAPPIST-1 planets, some of which are in that star’s habitable zone. It’s relatively nearby and has multiple Earth-sized planets, some of which are Earth-like.

Perhaps the best-publicized is the so-called ‘second Earth,’ Kepler-452b, a slightly larger cousin around a warmer, somewhat bigger cousin of our Sun that is 1,400 light-years from us. This one has already received billing as Earth’s cousin because it is so close in diameter, orbital period, and sheer power received from its star that it, too, might have water and life.

Further, the possibility of habitable exomoons orbiting other solar system’s giant planets has stimulated a renewed interest in separating the constraints on exploring our solar system from the considerations that might apply to extra-solar systems. Some of our better prospects for new oases and habitable lands are to be found in larger celestial bodies than Earth. We may have to leave our home world behind, yet for a time, giant planet vistas might still frame our everyday horizons. 

It’s important not to forget that the quest for possible worlds to colonize is also a quest for feasible worlds – worlds with a pathway towards them that’s realistically open to us shortly. It’s not simply the habitability of distant worlds that will weigh upon us. The means we need to get there and the amount of time and money spent finding conditions that could be primed for colonization (as opposed to actually primed) will likely be a significant consideration.

Lastly, the potential for colonization points to the distant future, the direction that human spacefaring will take as we learn more and more about these extraterrestrial worlds. Planetary astronomy and targeted planet-hunting can serve as essential tools as homo sapiens become interstellar. 

Challenges of Long-Duration Space Travel

Long missions are the technical and psychological heart of interstellar colonization, posing critical issues that must be mastered for humans to survive and thrive over the extreme duration of space travel. This section discusses some of the significant challenges of extended deep-space missions, focusing on the technical, physiological, and psychological limits inherent in such missions.

First is the technical problem of propulsion. To be viable, a spacecraft designed for interstellar travel & space colonization must accelerate in a straight line to a considerable fraction (at least 10 percent) of the speed of light, significantly reducing travel time. Unfortunately, existing propulsion technologies, such as chemical rockets, cannot provide this velocity boost over interstellar distances if we are not content with sending missions to planets and moons in distant galaxies rather than to the stars themselves. More exotic propulsion systems are needed. 

These include nuclear pulse propulsion, using atomic bombs as thrusters; antimatter propulsion, for which much more antiparticles must be produced than can currently be made; solar sails, which require incredibly lightweight yet highly reflective material to flex in response to sunlight; and other forms of radiation pressure. But all of these are still at a very early stage of technology, requiring significant breakthroughs in energy management.

Add to that the harsh conditions of space: high levels of cosmic radiation take a toll on astronauts’ health by increasing their probability of contracting cancer and other diseases. Finding a way to shield spacecraft from high-energy particles such as galactic cosmic rays without adding prohibitively massive amounts of material is an astounding engineering challenge.

Long-duration space travel will pose a profound challenge around the question of keeping people alive: can a closed-loop system be created on spacecraft to maintain human life for tens of years, let alone hundreds or even thousands of years – to recycle air, water, and waste; to ensure food; to keep people hydrated and comfortable; to treat their wounds and illnesses; and to allow babies to flourish and grow? These systems have to be perfect, or you could kill the crew. Failure has to be avoidable.

Long-duration spaceflight has significant psychological effects. Astronauts trapped in a controlled environment hundreds of thousands of kilometers away from the most basic stimuli and human comforts are at risk of mental health problems such as depression, anxiety, and interpersonal conflicts. Maintaining the cognitive functioning of the crew is as essential as their physical health. Careful selection of world-class personnel and ensuring their environment, training, and support needs must also be carefully catered for during the trip.

Lastly, the social dynamics of an interstellar mission by travelers who will depart Earth with little chance to return and are stranded into large-scale temporal disconnection by the time-dilation effects of near-light-speed travel raise ethical, philosophical, and existential questions about human nature and motivation and the very purpose of exploration. 

Conquering the challenges of living on a spaceship for long durations is critical to successfully colonizing the stars. This involves more than just building the machines and expanding the frontiers of space science. Living on a spaceship in the extreme space environment will be more about addressing human needs than technical capabilities. 

The Role of Robotics and AI in Space Colonization

If appropriately developed, robotics and artificial intelligence (AI) will spearhead human civilization into space—the vanguard of outer-space colonization. This section addresses the development and integration of these technologies, which can assist and extend the human agent well into space when perfectly fine-tuned to human will and spirit.

Robotics is the foundation of the initial phases of space colonization, including populating extraterrestrial worlds or moons by enabling autonomous functionality under environments that are hostile to living beings. Entire assembly lines can be built to operate on alien planets, constructing habitats and infrastructure to support survival and colonization. Robots can even be sent to mine extraterrestrial resources for building materials and conducting other scientific research. Robots can operate anywhere that humans can’t – from the vacuum of space to icy moons in low temperatures without the need for clothing or oxygen tanks to planets where the radiation levels would instantly kill a human being. Robots are the indispensable stepping stones by which any world can be prepared for human colonization.

Conversely, robots are equipped to travel where humans can’t or shouldn’t go. While this is enough for specific simple tasks, such as exact surface probing, it’s not enough for more complex missions. If we expect robots to deal with the unexpected, they need the capability of intelligent guidance. Bringing AI to bear on robotics transforms the latter into something capable of autonomous action. As control surfaces continue to recede from Earthly sight – the further we go, the longer the comms latency – those autonomous robots will have to become more innovative, self-directing, more agile, and with higher bandwidth to cope with new mission requirements, new environments, and new problems.

However, AI also supports the ‘back-end’ operational infrastructure of space missions by helping to manage the mountains of data that space science missions generate. AI can be trained to improve spacecraft navigation, for example, and the recognition of alien geographies and ecosystems, ultimately helping to process data more rapidly and effectively than human operators could ever manage.

Furthermore, robotics and AI can be utilized for spacecraft and habitat servicing and repair work: autonomous systems can conduct inspections and repairs, reducing the likelihood that an issue will develop into a significant problem and keeping human colonists healthy and safe.

Working together, robotics and AI technologies will form an ever-more crucial set of tools for overcoming the complexity of the problem of interstellar colonization. As those technologies improve, though, they will dominate matters more and more intimately, just as they will become the extensions of our ownership and possession of the other worlds we seek to inhabit in our quest to become a genuinely space-faring humanity. 

Architecting New Worlds: Terraforming

Terraforming is one of the most ambitious tasks in pursuing interstellar colonization: adapting an exoplanet environment to suit the needs of terrestrial life. This section examines engineering exoplanets and moons around distant worlds to sustain human life. It unpacks the science, technology, and ethics of terraforming.

In summary, terraforming aims to change a celestial body’s atmosphere, temperature, surface topography, and ecology to make it resemble the planet Earth. It might involve melting the polar ice caps to release water and carbon dioxide, planting vegetation to seed a biosphere, and engineering an atmosphere to make it habitable for animals and humans. Eventually, the vision is to achieve a self-sustaining ecosystem where human presence would be completely unnecessary.

Terraforming remains firmly within the realm of science, not science fiction. The most promising candidates for terraforming might be Mars and Venus. Given enough modification, both these planets can be transformed into solar-system analogs of Earth. In the case of Mars, the idea might be to warm up the earth and thicken its atmosphere, whereas Venus would require both cooling and changing its dense, soupy, toxic atmosphere.

From a technological perspective, terraforming is uncharted territory, indeed. It would require large-scale, advanced geoengineering techniques and vexing amounts of time, material, and effort, all coordinated over hundreds or thousands of years. This process likely relies on a hybrid idea in which robotics and AI could do much of the heavy environmental lifting on a large scale before humans ever set foot on the surfaces of Mars or Venus.

Ethical concerns play into these discussions, too. Terraforming would lead us to alter another planet’s environment, but does that task permit us the right to tamper with extraterrestrial ecosystems? What ecological surprises could result when a planet undergoes significant remodeling? And, if extraterrestrial life exists, should we be responsible for preserving it? These discussions debate how to treat these environments as part of our cosmological heritage.

The ultimate architects of whole new worlds, terraformers embody the pinnacle of human creativity and ambition in astroengineering – the end product of our journey beyond our solar system. A commencement and guidepost of a new epoch of human history and civilization, the self-directed colonization of the galaxy will create a new Earth and defy the odds of our cosmos, the outermost elements of human nature. This peculiar science and human aspiration reveals how life may transform across lightyears, even under the harshest conditions.

International Cooperation and Policy for space colonization

The desire to explore interstellar space cuts across state boundaries and depends on a level of international cooperation and policy-making unprecedented in human history. Here, the final section turns to the central role that global collaboration and policy-making will play in determining humanity’s collective trajectory into the Cosmos.

International cooperation has also been achieved in the past: multiple countries and space agencies have contributed to successful space projects, including the International Space Station (ISS). The ISS is a prime example of international cooperation, requiring countries to work together for a shared space goal. Some argue that the ISS project is a testament to how the collaborative development of space technology can unite currently estranged nations in peaceful, productive initiatives.

To start interstellar colonization, this spirit of collaboration needs to be scaled up and deepened, pooling the resources, knowledge, and expertise of all who participate. With the scale of the technology, the costs, and the timescales involved, interstellar missions are way beyond the capabilities of any individual nation or organization.

Policy development serves as a base camp for this multifaceted endeavor. Developing the legal and regulatory infrastructure necessary for interstellar colonization—from the governance of space sovereignty to the use of extraterrestrial resources, the stewardship of virgin worlds, and the rights and duties of space travelers and span dwellers—is of the utmost importance. Such policies must be derived from a vision of inclusivity and equity. Space colonization must benefit all humanity. 

Additionally, international policies should be flexible and resilient, capable of adapting to new space technologies and the potential future changes of interstellar exploration. They must also address ethical and moral questions, such as how to treat any lifeforms discovered in extraterrestrial space and how to protect their environments.

Collaborative international policy in space colonization is, therefore, a profound, inevitable advance on historic human space exploration; where we could once only voyage alone within our solar system – then, ambitiously, to the Moon – we now can move in concert far beyond, connecting us with a more significant share of the cosmos than ever before. Working together, humankind can leave behind a legacy of triumphant space exploration driven not only by technological prowess but by ethical conviction, mutual respect, and a collective aspiration for the common good of all humans, wherever they may reside in the Universe. 

Ethical and Philosophical Considerations for space colonization

Those questions can illuminate some of the most profound difficulties and ethical issues in the prospect of interstellar colonization: our place in the cosmos and our role as interplanetary adventurers. This section addresses some of the most consequential of these questions and difficulties. 

At the center of all these questions is the issue of our entitlement to colonize the cosmos – whether we should land people on other worlds, exploit their resources, or even terra-form them into at least partial copies of Earth at the cost of eradicating their unique biospheres. The notion of cosmic non-interference – a space-based analog of the environmental ethic of ‘leave no trace’ – comes into play here. One could form it into guidelines stipulating that any space-exploring activity should be conducted respectfully and minimally intrusively.

Another major ethical issue is planetary protection, or mitigating the risk of biological contamination between worlds. With this context in mind, all missions visiting potentially life-bearing environments must follow very restrictive protocols to avoid any accidental transfer of stowaway life forms that could ignite a process of terrestrial biological invasion, with potentially disastrous consequences for native life forms and ecosystems on other planets; alternatively, allowing extraterrestrial biological contaminants to infiltrate Earth’s biosphere.

Philosophically, questions of interstellar colonization relate to the overall meaning and purpose of human life and our identity as a species – now environmental, but potentially across light years. It is also concerned with our legacy in the Universe if we have any offspring or are descendants of civilizations that have become extinct. If we find or contact extraterrestrial intelligence, they will also raise these questions through their ability to expand the philosophical concerns related to the meaning of life, consciousness, mind, and intelligence.

Also, the ethics of resource use in space must be considered, including the equitable extraction and use of extraterrestrial resources, which are essential for the sustainability of any off-world colonies and the support of a space economy.

These questions are as wide as the universe and as deep as any ethical considerations and philosophical questioning on human stewardship could be. It is hard to overstate the importance of interstellar colonization in posing such questions to serious contemplation. It is equally challenging to overstate the importance of the responsible way we treat the vast diversity of beings we might meet, not to mention the never-ending array of planetary environments we might alter. These are essential aspects of the dialogue that must accompany our interstellar ambitions if we plan to reach for the stars with our heads held high, buoyed by wisdom and the knowledge that we approach the Sister Stars as respectful stewards. 

The Future of Interstellar Colonization

The vision of interstellar humanity projects current trends in technology, society, and spaceflight into a future characterized by interstellar outposts. This final section contemplates likely developments, innovations, and mindset changes that will evolve as humanity becomes an interstellar civilization. 

Only then will immense advancements in propulsion technologies – like nuclear fusion or antimatter engines – become crucial to authentic interstellar colonization. Space travel to nearby star systems will shrink by years or even decades, putting many more targets within reach. Miniature and power-dense technologies for spacecraft propulsion will also continue to improve, making them more efficient and sustainable. Eventually, higher-level autonomous systems will develop with their agency for exploration and colonization.

Further giant steps in life support and habitat building are also likely to feature prominently in the future of interstellar colonization. Indeed, establishing viable self-sustaining ecologies in space and on alien worlds will become a prerequisite for our long-term biological and psychological comfort off Earth. The most plausible ways of doing this will draw on cutting-edge biotechnology, closed-loop ecological self-sufficiency, and terraforming techniques.

It will also provoke new questions about community, identity, and nationality. The latest social worlds created in space will require new forms of organization, governance, and cultural evolution. Some societies, embedded in a shared heritage from Earth but influenced by their new contexts, will still create new mores, values, and laws.

Furthermore, colonizing space’s ethical and philosophical nuances would no doubt create extensive debate and discourse. These include the rights of potential extraterrestrial life, the moral obligations of alien ecological modification, and the fair resource distribution among interstellar settlers.

Ultimately, but not surprisingly, interstellar colonization’s future looks promising but also highly daunting. It is the next step, indeed the logical next step, in the saga of human beings seeking to understand reality and learn enough to survive, thrive, and flourish ethically and cognitively on ever larger scales and more fully in a more extensive Universe. May our journey there rise to the occasion.

Websites:

NASA: https://www.nasa.gov/aeronautics/

SpaceX: https://www.spacex.com/

Blue Origin: https://www.blueorigin.com/

The Planetary Society: https://www.planetary.org/

Space Foundation: https://www.spacefoundation.org/

Space.com: https://www.space.com/

Universe Today: https://www.universetoday.com/

Astronomy Magazine: https://www.astronomy.com/magazine/

Sky & Telescope: https://skyandtelescope.org/

Articles:

The Case for Becoming a Multi-Planetary Species: https://www.highexistence.com/why-humanity-must-become-a-multi-planetary-species/

The Challenges and Risks of Becoming a Multi-Planetary Civilization:https://meetings.aps.org/Meeting/MAR23/Session/K33.1

The Ethical Considerations of Space Exploration and Colonization:https://link.springer.com/book/10.1007/978-3-319-39827-3

The Economic Potential of Space Exploration and Colonization: https://thestarfish.ca/journal/2021/11/the-social-environmental-and-economic-impacts-of-space-colonization

How to Get Involved in the Space Industry: https://www.lauraforczyk.com/spacecareer