Hitchhiker's Guide meets Star Trek Meets a Modern Feminist Perspective . . .

If you've ever wondered what Star Trek would be like if it were written by a woman, check out Becky Chambers sci-fi novel The Long Way to a Small Angry Planet.

It's a space-opera with a sociological bent-- and while I like it much much more than Star Trek-- there's an archetypal similarity in the mission. The Wayfarer is a tunneling ship that opens up lanes through hyperspace in the Galactic Commons so that there can be communication and commerce between the affiliated species that live throughout the galaxy.

Instead of five years, the diverse crew of The Wayfarer is on a one year trip, but they are definitely going boldly to seek out new life and civilizations and strange new worlds.

The characters are modern and funny and mainly and manifoldly alien . . . humans are on the low end of the totem pole. The new clerk aboard the ship, Rosemarie, is just trying to fit in, knowing full well that the human race-- mainly by pure luck-- has just passed out of this stage:

Perhaps the most crucial stage is that of “intraspecies chaos.” This is the proving ground, the awkward adolescence when a species either learns to come together on a global scale, or dissolves into squabbling factions doomed to extinction, whether through war or ecological disasters too great to tackle divided. We have seen this story play out countless times. 

Along the episodically plotted journey, Chambers tackles interspecies coupling, AI rights, gene-tweaking, symbiotic sentient viruses, alien diplomacy, specieism, cloning, and moral relativism. But the book is mainly about a well-developed and fascinating group of sentient beings trying to get along in a small space on an epic journey.

I also learned the word "ansible."

Here's how the reptilian Aandrisk feel about children . . .

The death of a new hatchling was so common as to be expected. The death of a child about to feather, yes, that was sad. But a real tragedy was the loss of an adult with friends and lovers and family. The idea that a loss of potential was somehow worse than a loss of achievement and knowledge was something she had never been able to wrap her brain around. 

Chambers works with the conceit that life abounds in the universe, that it will evolve towards intelligence, and that it is carbon-based. With limitations, is it any wonder that sentient creatures have more similarities than differences. Even so, Captain Ashby is mired in this mess . . .

As open and generous as Aeluons generally were to their galactic neighbors, interspecies coupling remained a mainstream taboo.

Every alien race has to come to grip that there are others out there, with goals and dreams and culture that has evolved on a grand scale, in some ways parallel to all life, and in some way completely different and unexpected. 

In the middle of the book, there is a wonderful essay on this. The way it is inserted into the novel reminds me of The Hitchhiker's Guide to the Galaxy by Douglas Adams. It is ostensibly written by a sagacious Aandrisk scientist . . . but it's definitely Becky Chambers laying out the reason her story works. I've put it here in its entirety-- thanks to my Kindle-- and because it's so good.

ITEM NAME: Thoughts on the Galaxy—Chapter Three
AUTHOR: oshet-Tekshereket esk-Rahist as- Ehas Kirish isket-Ishkriset
ENCRYPTION: 0
TRANSLATION PATH: [Reskitkish:Klip] 
TRANSCRIPTION: 0 NODE IDENTIFIER: 9874-457-28, Rosemary Harper
When meeting an individual of another species for the first time, there is no sapient in the galaxy who does not immediately take inventory of xyr physiological differences. These are always the first things we see. How does xyr skin differ? Does xe have a tail? How does xe move? How does xe pick things up? What does xe eat? Does xe have abilities that I don’t? Or vice versa? These are all important distinctions, but the more important comparison is the one we make after this point. Once we’ve made our mental checklists of variations, we begin to draw parallels—not between the alien and ourselves, but between the alien and animals. The majority of us have been taught since childhood that voicing these comparisons is derogatory, and indeed, many of the racial slurs in colloquial use are nothing more than common names for nonsapient species (for example, the Human term lizard, to describe Aandrisks; the Quelin term tik, to describe Humans; the Aandrisk term sersh, to describe Quelin).
Though these terms are offensive, examining them objectively reveals a point of major biological interest. All demeaning implications aside, we Aandrisks do look like some of the native reptilian species of Earth. Humans do look like larger, bipedal versions of the hairless primates that plague the sewer systems of Quelin cities. Quelin do bear some resemblance to the snapping crustaceans found all over Hashkath. And yet, we evolved separately, and on different worlds. My people and the lizards of Earth do not share an evolutionary tree, nor do Humans and tiks, nor Quelin and sersh. Our points of origin are spread out across the galaxy. We hail from systems that remained self-contained contained for billions of years, with evolutionary clocks that all began at different times. How is it possible that when meeting our galactic neighbors for the first time, we are all instantly reminded of creatures back home—or in some cases, of ourselves?
The question becomes even more complicated when we start to look beyond our superficial differences to the wealth of similarities. All sapient species have brains. Let us consider that seemingly obvious fact for a moment. Despite our isolated evolutionary paths, we all developed nervous systems with a central hub. We all have internal organs. We all share at least some of the same physical senses: hearing, touch, taste, smell, sight, electroreception. The grand majority of sapients have either four or six limbs. Bipedalism and opposable digits, while not universal, are shockingly common. We are all made from chromosomes and DNA, which themselves are made from a select handful of key elements. We all require a steady intake of water and oxygen to survive (though in varying quantities). We all need food. We all buckle under atmospheres too thick or gravitational fields too strong. We all die in freezing cold or burning heat. We all die, period. How can this be? How is it that life, so diverse on the surface, has followed the same patterns throughout the galaxy—not just in the current era, but over and over again?
We see this pattern in the ruins of the Arkanic civilization at Shessha, or the ancient fossil beds on the now-barren world of Okik. This is a question that scientific communities have wrestled with for centuries, and it seems unlikely that an answer will present itself in the near future. There are many theories—asteroids carrying amino acids, supernovae blowing organic material out into neighboring systems. And yes, there is the fanciful story of a hyperadvanced sapient race “seeding” the galaxy with genetic material. I admit that the “Galactic Gardener” hypothesis has fueled the plots of some of my favorite science fiction sims, but scientifically speaking, it is nothing more than wishful thinking. You cannot have a theory without evidence, and there is absolutely none that supports this idea (no matter what the conspiracy theorists lurking on Linking feeds would have you believe).
For my part, I think that the best explanation is the simplest one. The galaxy is a place of laws. Gravity follows laws. The life cycles of stars and planetary systems follow laws. Subatomic particles follow laws. We know the exact conditions that will cause the formation of a red dwarf, or a comet, or a black hole. Why, then, can we not acknowledge that the universe follows similarly rigid laws of biology? We have only ever discovered life on similarly sized terrestrial moons and planets, orbiting within a narrow margin around hospitable stars. If we all evolved on such kindred worlds, why is it such a surprise that our evolutionary paths have so much in common? Why can we not conclude that the right combination of specific environmental factors will always result in predictable physical adaptations? With so much evidence staring us in the face, why does this debate continue?
The answer, of course, is that the laws of biology are nearly impossible to test, and scientists hate that. We can launch probes to test theories of gravity and space-time. We can put rocks in pressure cookers and split atoms in classrooms. But how does one test a process as lengthy and multifaceted as evolution? There are labs today that struggle to find the funding to keep a project running for three standards—imagine the funding needed to run a project for millennia! As it stands, there is no way for us to efficiently test the conditions that produce specific biological adaptations, beyond the most rudimentary observations (aquatic climates produce fins, cold climates produce fur or blubber, and so on).
There have been bold attempts at creating software that could accurately predict evolutionary paths, such as the Aeluon-funded Tep Preem Project (which, though well-intentioned, has yet to unravel the mysteries of biological law). The problem with such endeavors is that there are too many variables to consider, many of which we remain ignorant of. We simply don’t have enough data, and the data that we do possess is still beyond our understanding. We are experts of the physical galaxy. We live on terraformed worlds and in massive orbital habitats. We tunnel through the sublayer to hop between stellar systems. We escape planetary gravity with the ease of walking out the front door. But when it comes to evolution, we are hatchlings, fumbling with toys. I believe this is why many of my peers still cling to theories of genetic material scattered by asteroids and supernovae. In many ways, the idea of a shared stock of genes drifting through the galaxy is far easier to accept than the daunting notion that none of us may ever have the intellectual capacity to understand how life truly works.

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