On meditation and the birth of the universe.

On meditation and the birth of the universe.

This is part of a series of essays prepared to discuss in jail.

Our bodies are chaos engines. 

In our nearby environment, we produce order.  We form new memories.  We build things.  We might have sex and create new life.  From chaos, structure.

As we create local order, though, we radiate disorder into the universe. 

The laws of physics work equally well whether time is moving forward or backward.  The only reason we experience time as flowing forward is that the universe is progressing from order into chaos.

In the beginning, everything was homogeneous.  The same stuff was present everywhere.  Now, some regions of the universe are different from others.  One location contains our star; another location, our planet.  Each of our bodies is very different from the space around us.

This current arrangement is more disorderly than the early universe, but less so than what our universe will one day become.  Life is only possible during this intermediate time, when we are able to eat structure and excrete chaos. 

Hubble peers into a stellar nursery. Image courtesy of NASA Marshall Space Flight on Flickr.

Sunlight shines on our planet – a steady stream of high-energy photons all pointed in the same direction.  Sunshine is orderly.  But then plants eat sunshine and carbon dioxide to grow.  Animals eat the plants.  As we live, we radiate heat – low-energy photons that spill from our bodies in all directions.

The planet Earth, with all its life, acts like one big chaos engine.  We absorb photons from the sun, lower their energy, increase their number, and scatter them.

We’ll continue until we can’t.

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Our universe is mostly filled with empty space. 

But empty space does not stay empty.  Einstein’s famous equation, E equals M C squared, describes the chance that stuff will suddenly pop into existence.  This happens whenever a region of space gathers too much energy.

Empty space typically has a “vacuum energy” of one billionth of a joule per cubic meter.  An empty void the size of our planet would have about as much energy as a teaspoon of sugar.  Which doesn’t seem like much.  But even a billionth of a joule is thousands of times higher than the energy needed to summon electrons into being.

And there are times when a particular patch of vacuum has even more energy than that.

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According to the Heisenberg Uncertainty Principle, time and energy can’t be defined simultaneously.  Precision in time causes energy to spread – the energy becomes both lower and higher than you expected.

In practice, the vacuum energy of a particular region of space will seem to waver.  Energy is blurry, shimmering over time.

There are moments when even the smallest spaces have more than enough energy to create new particles.

Objects usually appear in pairs: a particle and its anti-particle.  Anti-matter is exactly like regular matter except that each particle has an opposite charge.  In our world, protons are positive and electrons are negative, but an anti-proton is negative and an anti-electron is positive.

If a particle and its anti-particle find each other, they explode.

When pairs of particles appear, they suck up energy.  Vacuum energy is stored inside them.  Then the particles waffle through space until they find and destroy each other.  Energy is returned to the void.

This constant exchange is like the universe breathing.  Inhale: the universe dims, a particle and anti-particle appear.  Exhale: they explode.

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Our universe is expanding.  Not only are stars and galaxies flying away from each other in space, but also empty space itself is growing.  The larger a patch of nothingness, the faster it will grow.  In a stroke of blandness, astronomers named the force powering this growth “dark energy.”

Long ago, our universe grew even faster than it does today.  Within each small fraction of a second, our universe doubled in size.  Tiny regions of space careened apart billions of times faster than the speed of light.

This sudden growth was extremely improbable.  For this process to begin, the energy of a small space had to be very, very large.  But the Heisenberg Uncertainty Principle claims that – if we wait long enough – energy can take on any possible value.  Before the big bang, our universe had a nearly infinite time to wait.

After that blip, our universe expanded so quickly because the vacuum of space was perched temporarily in a high-energy “metastable” state.  Technically balanced, but warily.  Like a pencil standing on its tip.  Left alone, it might stay there forever, but the smallest breath of air would cause this pencil to teeter and fall.

Similarly, a tiny nudge caused our universe to tumble back to its expected energy.  A truly stable vacuum.  The world we know today was born – still growing, but slowly.

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During the time of rapid expansion, empty vacuum had so much energy that particles stampeded into existence.  The world churned with particles, all so hot that they zipped through space at nearly the speed of light. 

For some inexplicable reason, for every billion pairs of matter and anti-matter, one extra particle of matter appeared.  When matter and anti-matter began to find each other and explode, this billionth extra bit remained.

This small surplus formed all of stars in the sky.  The planets.  Ourselves.

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Meditation is like blinking.  You close your eyes, time passes, then you open your eyes again.  Meditation is like a blink where more time passes.

But more is different.

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Our early universe was filled with the smallest possible particles.  Quarks, electrons, and photons.  Because their energy was so high, they moved too fast to join together.  Their brilliant glow filled the sky, obscuring our view of anything that had happened before.

As our universe expanded, it cooled.  Particles slowed down.  Three quarks and an electron can join to form an atom of hydrogen.  Two hydrogen atoms can join to form hydrogen gas.  And as you combine more and more particles together, your creations can be very different from a hot glowing gas.  You can form molecules, cells, animals, societies.

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When a cloud of gas is big enough, its own gravity can pull everything inward.  The cloud becomes more and more dense until nuclear fusion begins, releasing energy just like a nuclear bomb.  These explosions keep the cloud from shrinking further.

The cloud has become a star.

Nuclear fusion occurs because atoms in the center of the cloud are squooshed too close together.  They merge: a few small atoms become one big atom.  If you compared their weights – four hydrogens at the start, one helium at the finish – you’d find that a tiny speck of matter had disappeared.  And so, according to E equals M C squared, it released a blinding burst of energy.

The largest hydrogen bomb detonated on Earth was 50 megatons – the Kuz’kina Mat tested in Russia in October, 1961.  It produced a mushroom cloud ten times the height of Mount Everest.  This test explosion destroyed houses hundreds of miles away.

The fireball of Tsar Bomba, the Kuz’kina Mat.

Every second, our sun produces twenty billion times more energy than this largest Earth-side blast.

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Eventually, our sun will run out of fuel.  Our sun shines because it turns hydrogen into helium, but it is too light to compress helium into any heavier atoms.  Our sun has burned for about four billion years, and it will probably survive for another five billion more.  Then the steady inferno of nuclear explosions will end.

When a star exhausts its fuel, gravity finally overcomes the resistance of the internal explosions.  The star shrinks.  It might crumple into nothingness, becoming a black hole.  Or it might go supernova – recoiling like a compressed spring that slips from your hand – and scatter its heavy atoms across the universe.

Planets are formed from the stray viscera of early stars.

Supernova remains. Image by NASA’s Chandra X-Ray Observatory and the European Space Agency’s XMM-Newton.

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Our universe began with only hydrogen gas.  Every type of heavier atom – carbon, oxygen, iron, plutonium – was made by nuclear explosions inside the early stars.

When a condensing cloud contains both hydrogen gas and particulates of heavy atoms, the heavy atoms create clumps that sweep through the cloud far from its center.  Satellites, orbiting the star.  Planets.

Nothing more complicated than atoms can form inside stars.  It’s too hot – the belly of our sun is over twenty million degrees.  Molecules would be instantly torn apart.  But planets – even broiling, meteor-bombarded planets – are peaceful places compared to stars.

Molecules are long chains of atoms.  Like atoms, molecules are made from combinations of quarks and electrons.  The material is the same – but there’s more of it.

More is different.

Some atoms have an effect on our bodies.  If you inhale high concentrations of oxygen – an atom with eight protons – you’ll feel euphoric and dizzy.  If you drink water laced with lithium – an atom with three protons – your brain might become more stable.

But the physiological effects of atoms are crude compared to molecules.  String fifty-three atoms together in just the right shape – a combination of two oxygens, twenty-one carbons, and thirty hydrogens – and you’ll have tetrahydrocannibol.  String forty-nine atoms together in just the right shape – one oxygen, three nitrogens, twenty carbons, and twenty-five hydrogens – and you’ll have lysergic acid diethylamide.

The effects of these molecules are very different from the effects of their constituent parts.  You’d never predict what THC feels like after inhaling a mix of oxygen, carbon, and hydrogen gas.

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An amino acid is comparable in scale to THC or LSD, but our bodies aren’t really made of amino acids.  We’re built from proteins – anywhere from a few dozen to tens of thousands of amino acids linked together.  Proteins are so large that they fold into complex three-dimensional shapes.  THC has its effect because some proteins in your brain are shaped like catcher’s mitts, and the cannibinoid nestles snuggly in the pocket of the glove.

Molecules the size of proteins can make copies of themselves.  The first life-like molecules on Earth were long strands of ribonucleic acid – RNA.  A strand of RNA can replicate as it floats through water.  RNA acts as a catalyst – it speeds up the reactions that form other molecules, including more RNA.

Eventually, some strands of RNA isolated themselves inside bubbles of soap.  Then the RNA could horde – when a particular sequence of RNA catalyzed reactions, no other RNA would benefit from the molecules it made.  The earliest cells were bubbles that could make more bubbles.

Cells can swim.  They eat.  They live and die.  Even single-celled bacteria have sex: they glom together, build small channels linking their insides to each other, and swap DNA.

But with more cells, you can make creatures like us.

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Consciousness is an emergent property.  With a sufficient number of neuron cells connected to each other, a brain is able to think and plan and feel.  In humans, 90 billion neuron cells direct the movements of a 30-trillion-cell meat machine.

Humans are such dexterous clever creatures that we were able to discover the origin of our universe.  We’ve dissected ourselves so thoroughly that we’ve seen the workings of cells, molecules, atoms, and subatomic particles.

But a single human animal, in isolation, never could have learned that much.

Individual humans are clever, but to form a culture complex enough to study particle physics, you need more humans.  Grouped together, we are qualitatively different.  The wooden technologies of Robinson Crusoe, trapped on a desert island, bear little resemblance to the vaulted core of a particle accelerator.

English writing uses just 26 letters, but these can be combined to form several hundred thousand different words, and these can be combined to form an infinite number of different ideas.

More is different.  The alphabet alone couldn’t give anyone insight into the story of your life.

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Meditation is like a blink where more time passes, but the effect is very different.

Many religions praise the value of meditation, especially in their origin stories.  Before Jesus began his ministry, he meditated for 40 days in the Judaean Desert – his mind’s eye saw all the world’s kingdoms prostrate before him, but he rejected that power in order to spread a philosophy of love and charity. 

Before Buddha began his ministry, he meditated for 49 days beneath the Bodhi tree – he saw a path unfurl, a journey that would let travelers escape our world’s cycle of suffering. 

Before Odin began his ministry, he meditated for 9 days while hanging from a branch of Yggdrasil, the world tree – Odin felt that he died, was reborn, and could see the secret language of the universe shimmering beneath him. 

The god Shiva meditated in graveyards, smearing himself with crematory ash.

At its extreme, meditation is purportedly psychedelic.  Meditation can induce brain states that are indistinguishable from LSD trips when visualized by MRI.  Meditation isolates the brain from its surroundings, and isolation can trigger hallucination.

Researchers have found that meditation can boost our moods, attentiveness, cognitive flexibility, and creativity.  Our brains are plastic – changeable.  We can alter the way we experience the world.  Many of our thoughts are the result of habit.  Meditation helps us change those habits.  Any condition that is rooted in our brain – like depression, insomnia, chronic pain, or addiction – can be helped with meditation.

To meditate, we have to sit, close our eyes, and attempt not to think.  This is strikingly difficult.  Our brains want to be engaged.  After a few minutes, most people experience a nagging sense that we’re wasting time.

But meditation gives our minds a chance to re-organize.  To structure ourselves.  And structure is the property that allows more of something to become different.  Squirrels don’t form complex societies – a population of a hundred squirrels will behave similarly to a population of a million or a billion.  Humans form complex webs of social interactions – as our numbers grew through history, societies changed in dramatic ways.

Before there was structure, our entire universe was a hot soup of quarks and electrons, screaming through the sky.  Here on Earth, these same particles can be organized into rocks, or chemicals, or squirrels, or us.  How we compose ourselves is everything.

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The easiest form of meditation uses mantras – this is sometimes called “transcendental meditation” by self-appointed gurus who charge people thousands of dollars to participate in retreats.  Each attendee is given a “personalized” mantra, a short word or phrase to intone silently with every breath.  The instructors dole mantras based on a chart, and each is Sanskrit.  They’re meaningless syllables to anyone who doesn’t speak the language.

Any two-syllable word or phrase should work equally well, but you’re best off carving something uplifting into your brain.  “Make peace” or “all one” sound trite but are probably more beneficial than “more hate.”  The Sanskrit phrase “sat nam” is a popular choice, which translates as “truth name” or more colloquially as “to know the true nature of things.”

The particular mantra you choose matters less than the habit – whichever phrase you choose, you should use it for every practice.  Because meditation involves sitting motionless for longer than we’re typically accustomed, most people begin by briefly stretching.  Then sit comfortably.  Close your eyes.  As you breathe in, silently think the first syllable of your chosen phrase.  As you breathe out, think the second.

Repeating a mantra helps to crowd out other thoughts, as well as distractions from your environment.  Your mind might wander – if you catch yourself, just try to get back to repeating your chosen phrase.  No one does it perfectly, but practice makes better.  When a meditation instructor’s students worried that their practice wasn’t good enough, he told them that “even on a shallow dive, you still get wet.”

In a quiet space, you might take a breath every three to six seconds.  In a noisy room, you might need to breathe every second, thinking the mantra faster to block out external sound.  The phrase is a tool to temporarily isolate your mind from the world.

Most scientific studies recommend you meditate for twenty minutes at a time, once or twice a day, each and every day.  It’s not easy to carve out this much time from our daily routines.  Still, some is better than nothing.  Glance at a clock before you close your eyes, and again after you open them.  Eventually, your mind will begin to recognize the passage of time.  After a few weeks of practice, your body might adopt the approximate rhythm of twenty minutes.

Although meditation often feels pointless during the first week of practice, there’s a difference between dabbling and a habit.  Routine meditation leads to benefits that a single experience won’t.

More is different.

On meditation.

On meditation.

More is different.

In the beginning, subatomic particles careened too quickly to connect.  The universe was “hot.”  (Temperature is a measure of average speed as objects jiggle.  When physics people say that our universe was “hot,” they mean that everything was moving just shy of the speed of light.)

In the beginning, our universe wasn’t very interesting.  But then the homogeneous cloud of fast-moving particles cooled as it expanded.  Speeds slowed.  Soon, particles dawdled long enough in each others’ vicinity that they could interact.  Hydrogen atoms formed, then hydrogen gas, then stars. 

Stars are interesting – when a cloud of gas is big enough, its net gravity can pull everything inward until the density becomes so high that nuclear fusion begins.  This raging cascade of explosions counteracts the force of gravity and the star reaches an unsteady equilibrium until, eventually, it runs out of fuel and collapses or explodes.

An exploding star scatters heavier atoms across the sky.  When these are incorporated into a new star, they can participate in nuclear fusion events in turn, producing even heavier atoms. 

Then that star might explode, too.

Eventually, there were enough heavy atoms floating about the universe that a condensing cloud could form both a star and a set of orbiting satellites.  On these satellites – planets – atoms combine in more interesting ways than inside the bellies of stars. 

After all, the infernal core of a star is pretty hot, too.  Inside that blazing oven, particles can form atoms, and atoms can combine to form heavier atoms, but these are too frantic to form molecules – long strings of atoms bonded together.

The chemical bonds that hold a molecule together are much weaker than the electrostatic and nuclear forces that maintain an atom.  But planets – even broiling, meteor-bombarded ones – are peaceful places compared to stars.  On the primordial earth, lightning strikes or UV radiation probably catalyzed the formation of complex molecules like amino acids and nucleic acids.

These molecules are just big amalgams of subatomic particles.  The underlying stuff is the same … but there’s more of it.

More is different.

Consider the behaviors of a single amino acid.  An amino acid is complex compared to a quark or electron.  It can do acid-base chemistry!  Its mix of charged and neutral surfaces lets it interact in neat ways with various solvents. 

But if you compare that single amino acid to a protein – and a protein is just more amino acids joined together – you’ll realize that the single amino acid is total snoresville.

Proteins, though … wow!  They can fold into fantastical shapes.  They can function as molecular machines, their parts churning and twisting and flipping as they shuttle other molecules from place to place, or even create whole new molecules.

When you glom more and more and more subatomic particles together, eventually you create things that are complex enough to imprint patterns on the world.  They create more things like themselves.  Proteins and RNA make new proteins and RNA.

And then, a cell!  A cell is an amalgam of molecules all dissolved inside a bubble of fat.  If you thought proteins were cool, check this out!  Cells can swim, they can eat, they can live and die.

Or, what if there were more cells?  Then you can make us!  With many cells, you can make brains, which makes consciousness, which can give all those subatomic particles the ability to work together and realize that they are subatomic particles.

Well, no. One single human animal, in isolation, probably wouldn’t figure that out.  Each human, as an individual, can be pretty great – but to form a culture complex enough to study particle physics, you’ll need more people.  Contemporary physics papers list hundreds of authors, and that doesn’t even credit everybody who worked to build the equipment, and or worked to grow the food, and took care for the children, or taught the physicists, when they were young, allowing them to one day become physicists …

And each of those physicists, and engineers, and farmers, and caregivers, and teachers … each is a collection of cells, which are collections of molecules, which are collections of atoms, which are collections of subatomic particles.  As we transition between scales, we see qualitative differences in behavior from adding more.

This essay is made from a set of just 26 letters, but these can be combined to form a few hundred thousand different words, and those can be combined to convey an infinite number of different ideas.

We blink many thousands of times each day.  Our eyes close, pause, and then open again.  We need to blink.  Staring at screens – as I’m doing now, typing this essay, and as are you, reading it – causes us to blink less frequently, and that can lead to headaches.  But the quality of each blink doesn’t affect us much.  Most blinks pass by without our even noticing.

Meditation is just a long blink.  Close your eyes and let more time elapse before you open them again.

But more is different.  A blink doesn’t disrupt your thoughts.  Meditation, however, can be a psychedelic experience.

Many religions praise the value of meditation, especially in their origin stories.  Before he began his ministry, Jesus meditated in the Judaean Desert – he saw all the world’s kingdoms before him, but rejected that vision of power in order to spread a philosophy of love and charity.  Before he began his ministry, Buddha meditated beneath the Bodhi tree – he saw a path unfurl, a journey that would let travelers escape our world’s cycle of suffering.  Buddha decided to share that vision with others.

Before teaching his fellows to reshape the world with words, Odin meditated from a tree branch – he felt that he had died, transcended life, and could see the secret language of the universe shimmering before him.

I’ve been preparing anti-racist material about paganism and spirituality so that we have more things to send to people who contact Pages to Prisoners.  As part of this project, I’d like to include information about meditation.  After all, neo-paganism is invented – typically quite recently – and, as above, many religions have preserved stories suggesting that their founders’ meditation inspired their faith.  These religions don’t always prioritize meditation as a contemporary practice, but many do: Christian monks repeat prayers in a way that’s strikingly similar to mantra meditation, Hindu adherents are advised to sit and experience a simulacrum of Shiva’s asceticism, and even warrior cultures have prized pre-battle stillness as a way to focus attention and more fully inhabit the present.

The scientific literature is also replete with papers about meditation — but most of these are junk. It’s fairly easy to find published studies claiming that mindfulness training can confer disease resistance, immunity to aging, or even paranormal abilities like extra-sensory perception.  Scientific papers aren’t inherently more trustworthy than the internet.

But it’s true that your mind is plastic, and your moods can dramatically alter the way you perceive the world.  Conditions that affect our nervous system – like depression, insomnia, and even chronic paincan be treated through meditation.  The experiments that scientists use to assess things like “creativity” or “attentiveness” are often open to interpretation, but it’s not unreasonable to imagine that meditation would help.

All people are creative.  Our problem, often, is that our ideas can flit away before we fully grasp them.  Like dreams, they fade, and we’re left with the irksome sensation that “I feel like I just had a good idea, but …”

Meditation can clear the turbid waters of your mind.  Like gazing into a pellucid lake, it could become easier to spot your good ideas when they come.

I’ve never been inside a prison, so I’ll have to collaborate with friends who have spent time there as I make the pamphlets.  But everything I’ve read suggests that most prisons are loud, chaotic, stressful, and dangerous.  Which has obvious implications for how easily people can meditate.  If you live near a beautiful glen, you could probably do well by your brain by simply taking some time each day to sit peacefully beside some flowing water.

Instead, I’ve been learning about mantra meditation.  By silently intoning the same phrase over and over – even if it’s just a nonsense word – you can overcome a fair bit of external distraction.  To test, I’ve tried meditating at the YMCA.  This place is very calm compared to our county jail, which I’ve heard is itself calmer than a prison, but where I sit, people are usually conversing, and there are a variety of rattling exercise machines.

Several of the guide books I’ve read recommend that you pay somebody a bunch of money to teach you transcendental meditation.  During your training, you’ll be given a secret Sanskrit word or phrase.  People who’ve taken these training courses have posted a bunch of the words online, and apparently a mantra is selected based upon your age and gender. 

That seems silly to me – although it’s possible that different people’s minds would respond best to different mantras, my gender isn’t a big component of my identity, nor is my age. 

I did pick out a Sanskrit phrase, which is perhaps a silly choice in and of itself.  After all, I can’t speak Sanskrit.  But I thought it might be nice to have a set of sounds that didn’t carry a lot of semantic meaning in the rest of my daily life.  Although Sanskrit mantras would have held meaning to the original practitioners of this style of meditation, Sanskrit is generally considered a formal, ritual language, not something that people speak at home with their families.  Even for native speakers, the chance of crossed wires, in which people were inadvertently saying their special mantras at other times of day, was probably pretty low.

While meditating, there are times when I’m pretty oblivious to my environs, even though I’m sitting in a crowded, noisy place.  I assume that I should recommend, for people meditating in prison, that they use a buddy system.  Unless somebody you trust immensely was sitting nearby, I assume it would feel too unsafe to allow yourself to completely let go in the way that deep meditation requires.

In case you’re interested in trying, I can tell you what’s worked so far for me.  I’ve been thinking the phrase “sat nam.”  I liked the translation when I looked it up online, and it’s felt convenient to have two discrete sounds – I think the “sat” while breathing in, and “nam” while breathing out.  I’ve read that people aim to spend about six seconds each on inhalation and exhalation, but I breath much more rapidly than that. 

If nothing too distracting is going on nearby – maybe just some clanking from the ellipticals, treadmills, and stairmasters – I breath in and out once every four to eight seconds.  But when people are having a conversation right next to me, I take a breath every one or two seconds, which means I’m intoning my little mantra more often and can do a better job of isolating myself from what’s going on around me.

As far as I can tell, that isolation is the goal of meditation.  Our minds evolved to expect constant stimulus during our waking lives.  If you reduce the degree of outside stimulation, like with a sensory deprivation chamber, you invite your mind to conjure strange thoughts, visions, and sounds to replace the inputs that it expects.  But you have to keep at it long enough.

When particle physicist Richard Feynman described his experience with sensory deprivation tanks, he wrote:

Ordinarily it would take me about fifteen minutes to get a hallucination going, but on a few occasions, when I smoked some marijuana beforehand, it came very quickly.  But fifteen minutes was fast enough for me.

Mr. Lilly had a number of different tanks, and we tried a number of different experiments.  It didn’t seem to make much difference as far as hallucinations were concerned, and I became convinced that the tank was unnecessary.  Now that I saw what to do, I realized that all you have to do is sit quietly.

I would like to have done it at home, and I don’t doubt that you could meditate and do it if you practice, but I didn’t practice.

I’ve only had a bit of practice, but when I sit still with my eyes closed and block out the outside world with a repeated phrase, my mind will sometimes drift.  I’ve been trying to sit for twenty minutes, although I often inadvertently rouse myself after about fifteen – which hasn’t seemed to be quite enough, for either me or Dr. Feynman.  But I get the feeling that it has to be continuous.  Once I’ve opened my eyes and glanced at the clock, I stop for the day.  Even if nothing much has happened.

On these days, I console myself with a quote from Maharishi Mahesh Yogi that I learned from Bob Roth’s Strength in Stillness:Even in a shallow dive, you still get wet.

I begin by stretching – although I’m practicing in a relatively distracting environment, it seems reasonable to minimize the distractions of my own body.  I try not to move while meditating, and it’d be harder to maintain a single posture if I could feel my body ache.

After I close my eyes, the first few minutes typically feel like a waste of time.  I’m sitting there repeating a nonsense phrase and I can’t help but think of the myriad other things that I ought to be doing.

As long as I can force myself to keep at it, though, the experience changes.  More becomes different.  Undulating phosphenes blossom in the umber field of my closed eyes.  Sometimes I slip into reverie; if I catch myself daydreaming, I’ll resume intoning my bit of Sanskrit, which helps me set aside whatever vein of thought led me astray.

Nobody is totally sure why we need sleep, but recent results have suggested that nitrogenous waste and other metabolic toxins can only be cleared from brain cells while we’re snoozing.  If you stay awake too long, trash piles up along the roadways of your mind, and all that junk prevents learning, memory formation, and attentiveness. 

During my classes in jail, I often work with men who have stayed awake for weeks at a time by taking methamphetamine – they’ve experienced a wide variety of hallucinations, paranoia, and mental turmoil.  Amphetamines aren’t very toxic, but loss of sleep can seriously damage a person’s brain.

One day without sleep won’t kill you.  Luckily so – since having kids, there have been many nights when a little one wakes up screaming and I never get to rest.  But more is different.  After three days without sleep, the shadow people start talking.  After eight days, my students have started talking back: “I knew they weren’t real … but I still didn’t want to be rude.  But we got into all these arguments.

Sleep washes away the argumentative shadow people.

When meditation goes well, I sometimes imagine my mind being cleansed – I’ll sit there thinking sat nam, sat nam and envision a cascade of water flowing over me like Heracles used to clean King Augeas’s stables.  But meditation might not help with keeping a brain tidy – those experiments on the waste-clearing function of sleep were done with mice, and (to the best of my knowledge) nobody has taught mice to meditate.

If you trust my spouse’s subjective evaluation, though, meditation seems to help.  I’ve apparently been more pleasant to live with since I started practicing. 

If you’re going to try, aim for at least twenty minutes, maybe once or twice a day for a few weeks.  My apologies if it seems pointless at first.  I’d recommend you keep at it – just like a single minute won’t give you the same benefit as twenty, it seems reasonable to expect that a single day wouldn’t have the same benefit as a month’s daily practice.

After all, more is different.

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Featured image by Mitchell Joyce on Flickr.