Non-water. Inside the dead forest.

Photo by Vlad Bagacian from Pexels

Led by Professors Raffaele Mezzenga and Ehud Landau, a group of physicists and chemists from ETH Zurich and the University of Zurich have identified an unusual way to prevent water from forming ice crystals, so even at extreme sub-zero temperatures it retains the amorphous characteristics of a liquid.

In a first step, the researchers designed and synthesized a new class of lipids (fat molecules) to create a new form of “soft” biological matter known as a lipidic mesophase, by mixing those lipids with water. In the newly created material, the lipids spontaneously self-assemble and aggregate to form membranes. These membranes form a network of connected channels less than one nanometer in diameter. In this structure, there is no room in the narrow channels for water to form ice crystals, so it remains disordered even at extreme sub-zero temperatures. The lipids do not freeze either.

Using liquid helium, the researchers were able to cool a lipidic mesophase consisting of a chemically modified monoacylglycerol to a temperature as low as minus 263 degrees Celsius, which is a mere 10 degrees above the absolute zero temperature, and still no ice crystals formed. (1)

Water freezes at zero degrees.

Unless you mix it with something else.

But then, it is not water.

And it can freeze at lower temperatures.

Everything is what it is.

But it can change to something else.

At the end, all things freeze at the same temperature.

If they are the same.

Or at different. If they are not.

Nature doesn’t care.

In the deepest cold…

Under the heat of the summer sun…

There are no temperatures.

Just things which boil and freeze.

There are many paths inside the forest of existence.

Do you care about how Achilles will reach the turtle?


There is nothing to compare anything with.

For everything is connected with everything.

And all measurements are just reflections in the mirror.


At the end you will be in the clearing…

Only to realize that the clearing is you.

Consumed by fire.

Breathing cold air…

Reducing resistance… Non-knowledge…

Photo by Nick Wehrli from Pexels

The realization of so-called topological materials – which exhibit exotic, defect-resistant properties – has opened up a new realm in materials discovery.

Several of the hotly studied topological materials to date are known as topological insulators. Their surfaces are expected to conduct electricity with very little resistance, somewhat akin to superconductors but without the need for incredibly chilly temperatures, while their interiors do not conduct current.

A team of researchers working at the Department of Energy’s Lawrence Berkeley National Laboratory (Berkeley Lab) discovered the strongest topological conductor yet, in the form of thin crystal samples that have a spiral-staircase structure. The team’s study of crystals, dubbed topological chiral crystals, is reported in the journal Nature. (1)

We try to find ways to conduct electricity better through the materials we build. But the best way not to block the flow of something is not to build anything in its path in the first place.

We have split the cosmos into pieces.

And we try to find our way from one piece to the other.

But what is the next number of zero?


Can you find the next number of one?

Ask simple questions.

And your inability to answer will guide you through the dark forest of knowledge…

It used to be an illuminated forest.

Full of the light of ignorance.

But you chose to illuminate it. And everything went dark.

One step…

Two steps…

Three steps…


From the moment I started walking…

It feels like I am not walking at all…

Heat waves. Like… sound waves?

Photo by Spiros Kakos from Pexels

The next time you set a kettle to boil, consider this scenario: After turning the burner off, instead of staying hot and slowly warming the surrounding kitchen and stove, the kettle quickly cools to room temperature and its heat hurtles away in the form of a boiling-hot wave.

We know heat doesn’t behave this way in our day-to-day surroundings. But MIT researchers observed this seemingly implausible mode of heat transport, known as “second sound,” in a rather commonplace material: graphite.

At temperatures of 120 kelvin (-240 degrees Fahrenheit), they saw clear signs that heat can travel through graphite in a wavelike motion. Points that were originally warm are left instantly cold, as the heat moves across the material at close to the speed of sound. The behavior resembles the wavelike way in which sound travels through air, so scientists have dubbed this exotic mode of heat transport “second sound.”

The discovery, published in Science, suggests that graphite, and perhaps its high-performance relative, graphene, may efficiently remove heat in microelectronic devices in a way that was previously unrecognized. (1)

The world seems dominated by waves.

Waves of gravity.

Waves of sound.

Heat waves.

Waves on the rough sea.

Waves of people moving together.

Places of high heat. Places of extreme cold.

Taking turns in the split of a second.

Because there is no heat to be transferred.

Only the cosmos’ potential to change on the spot.

A cosmos full of consciousness.

A cosmos full of empty space.

Both taking turns on the substrate of existence.

With Being orchestrating everything.

A rock on a pond.

Generating waves.

Watch the waves reaching the shore.

Slowing degrading.

No, it is not the rock which made them be.

But the surface of the lake itself.

Look deep inside that lake, and you will see…

That no rock ever reached the bottom…

Going back in time… With no change…

Photo by Spiros Kakos from Pexels

We cannot reverse the arrow of time any more than we can erase all our wrinkles or restore a shattered teacup to its original form.

Or can we?

An international team of scientists led by the U.S. Department of Energy’s (DOE) Argonne National Laboratory managed to return a computer briefly to the past.

To achieve the time reversal, the research team developed an algorithm for IBM’s public quantum computer that simulates the scattering of a particle. In classical physics, this might appear as a billiard ball struck by a cue, traveling in a line. But in the quantum world, one scattered particle takes on a fractured quality, spreading in multiple directions. To reverse its quantum evolution is like reversing the rings created when a stone is thrown into a pond.

In nature, restoring this particle back to its original state – in essence, putting the broken teacup back together – is impossible, since you would need a ​”supersystem” to manipulate the particle’s quantum waves at every point. The time required for this supersystem to properly manipulate the quantum waves would extend longer than that of the universe itself.

The team managed to overcome this complexity, at least in principle. Their algorithm simulated an electron scattering by a two-level quantum system,​ “impersonated” by a quantum computer qubit and its related evolution in time. The electron goes from a localized, or​ “seen,” state, to a scattered one. Then the algorithm throws the process in reverse, and the particle returns to its initial state – in other words, it moves back in time, if only by a tiny fraction of a second. (1)

Going back in time.

By returning to the original state.

Because time is defined by change.

But what does this mean?

This doesn’t mean they go back in time.

But that time wasn’t there in the first place…

The 2nd law of thermodynamics.

The arrow of time.

The fate of the universe.

Everything will be back to their original state at the end.

And the end will be the new beginning.

Going back in time.

Where time is nothing but a fleeting feeling.

Open your eyes.

Can you dream of how you started dreaming?

Chaos… Order… Chaos…

Photo by Martin Péchy from Pexels

Can chaotic systems also synchronize with each other? Physicists from Bar-Ilan University in Israel, along with colleagues from Spain, India and Italy, analyzed the Rossler system and discovered new phenomena that have been overlooked until now.

For the first time the researchers were able to measure the fine grain process that leads from disorder to synchrony, discovering a new kind of synchronization between chaotic systems: Topological Synchronization. Traditionally, synchronization has been examined by comparing the time-course of activity of the two systems. Topological Synchronization instead examines synchronization by comparing the structures of the systems.

As per the researchers, “Every chaotic system attracts its own unique strange attractor. By Topological Synchronization we mean that two strange attractors have the same organization and structures. At the beginning of the synchronization process, small areas on one strange attractor have the same structure of the other attractor, meaning that they are already synced. At the end of the process, all the areas of one strange attractor will have the structure of the other and complete Topological Synchronization has been reached.”

This means that chaotic systems synchronize gradually through local structures that, surprisingly, kick off in the sparse areas of the system and only then spread to the more populated areas. In these sparse areas the activity is less chaotic than in other areas and, as a result, it is easier for these areas to sync relative to those that are much more erratic. (1)

In a fully chaotic system.

Small clearings of order.

And at the end, the system will be in sync.

In a totally ordered system.

Vast hidden oceans of chaos.

And at the beginning, the system will breed a new cosmos…

A new cosmos which will again be in order once more.

An order which will create a new chaos to engulf everything…

For the cosmos we live in is neither ordered nor chaotic.

The cosmos we live in just Is.

Trying to speak to us.

Trying to break its limitations and communicate.

Throw that stone into the calm lake.

Can you hear the roaring abyss?

Exit mobile version