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We Will Never Have Enough Resources For Teleportation | The Real Science of Scifi

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Star Trek brought us so much scifi tech that we have been waiting to see come to life and one of the biggest dreams of all is teleportation! To boldly go… to the other side of the world without an 18 hour flight!

This is the second episode in a series about Scifi Tech we’ll never have…soz!
Today we’ll talk about matter vs information, how quantum teleportation actually works, how much information a human body contains, how we would measure that information and transfer it and ultimately, that it all comes down to an identity crisis.

Chapters:
00:00 Introduction.
02:32 For the love of scifi.
07:20 Quantum information.
11:46 Quantum teleportation.
16:19 The human factor.
20:20 Heisenberg compensators.
22:13 The measurement destruction problem.
24:15 The timing problem.
25:53 The data problem.
30:58 The unavoidable energy cost.
33:11 The identity question.

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Things to read — papers are all open access versions:

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Surprise: Free Will Needs Quantum Physics to Fail, Physicists Show

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Some physicists believe that human consciousness is somehow linked to the indeterministic element of quantum physics. But according to a surprising new argument that just appeared on the arXiv, a world where everything is ruled by quantum physics is incompatible with the idea of free will. Let’s take a look.

Paper: https://arxiv.org/abs/2510.

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Low-threshold lasing from colloidal quantum dots under quasi-continuous-wave excitation

Researchers demonstrate quantum dot lasing using excitation by an electrically modulated (0.1–1% duty cycle), low-power continuous-wave laser diode, achieving lasing at a pump intensity just above 500 W cm−2 at 77 K and 3.6 kW cm−2 at room temperature.

Why quantum computers have memory problems over time

A team of Australian and international scientists has, for the first time, created a full picture of how errors unfold over time inside a quantum computer—a breakthrough that could help make future quantum machines far more reliable.

The researchers, led by Macquarie University’s Dr. Christina Giarmatzi, found that the tiny errors that plague quantum computers don’t just appear randomly. Instead, they can linger, evolve and even link together across different moments in time.

The team has made its experimental data and code openly available, and the full study is published in Quantum.

Einstein in a Chip: Hidden Geometry Bends Electrons Like Gravity

A team at UNIGE has uncovered a geometric structure once thought to be purely theoretical at the core of quantum materials, opening the door to major advances in future electronics. How can information be processed almost instantly, or electrical current flow without energy loss? To reach these g

Scientists crack the atomic code behind single-photon quantum emitters

This achievement removes one of the biggest roadblocks in quantum materials science and brings practical quantum devices much closer to reality.

Quantum emitters work by releasing single photons, individual packets of light, on demand. This ability is critical because quantum technologies rely on absolute control over light and information.

The problem has always been visibility and control. The exact atomic defects responsible for these emitters are incredibly small and difficult to observe. Scientists could either study how they emit light or examine their atomic structure—but not both at the same time.

How to Measure a Tiny Beam Shift

Measuring very small displacements of a laser beam is important in many areas of science and technology, such as in an atomic force microscope. A quantum trick called weak-value amplification (WVA) has previously led to extremely sensitive measurements of beam shifts within interferometers. Now Carlotta Versmold of the Ludwig Maximilian University of Munich and her colleagues have extended such measurements to beam displacements outside of an interferometer [1]. For example, a laser beam reflecting off of a distant window could encode vibrations resulting from conversations inside the building.

In the WVA version applicable to shifts within an interferometer, a light beam is split and routed along two slightly unequal paths that later merge and lead to two output ports—a “bright” port where the beams largely reinforce one another and a “dark” port where they mostly cancel each other out. Any slight displacement of either beam is amplified in the position of the dim spot at the dark port. However, shifts in the beam entering the interferometer lead to offsetting shifts of the internal beams and thus to no measurable signal.

To extend the method to shifts of the incoming beam, Versmold and her colleagues added a so-called Dove prism to one of the beam paths. This type of prism generates an additional reflection, which effectively leads to opposite shifts in the two paths, resulting in an amplified signal at the dark port.

Physicists bring unruly molecules to the quantum party

Scientists have made leaps and bounds in bending atoms to their will, making them into everything from ultraprecise clocks to bits of quantum data. Translating these quantum technologies from obedient atoms to unruly molecules could offer greater possibilities. Molecules can rotate and vibrate. That makes molecules more sensitive to certain changes in the environment, like temperature.

“If you’re sensitive to something, it can be a curse, because you would like to not be sensitive, or it can be a blessing,” said NIST physicist Dietrich Leibfried. “You can use that sensitivity to your advantage.”

But that same sensitivity has made molecules difficult to control. Recently, physicists at the National Institute of Standards and Technology (NIST) achieved new levels of control over molecules. In a study published in Physical Review Letters, they were able to manipulate a calcium hydride molecular ion—made up of one atom of hydrogen and one atom of calcium, with one electron removed to make it a charged molecule—with almost perfect success. And this control opens possibilities for quantum technology, chemical research and exploring new physics.

A simple spin swap reveals exotic anyons

Researchers from the University of Innsbruck, the Collège de France, and the Université Libre de Bruxelles have developed a simple yet powerful method to reveal anyons—exotic quantum particles that are neither bosons nor fermions—in one-dimensional systems. Their paper is published in Physical Review Letters.

In conventional three-dimensional space, particles belong to one of two categories: fermions or bosons. In low-dimensional settings, however, quantum mechanics allows for more exotic behavior. Here, anyons can emerge—quasi-particles whose exchange properties continuously interpolate between those of bosons and fermions, leading to fractional statistics. Detecting and engineering such particles in one dimension has long been a central challenge, typically requiring, as theory proposals suggest, intricate scattering schemes or density-dependent tunneling processes.

The new study by teams led by Hanns-Christoph Nägerl at the University of Innsbruck and Nathan Goldman at the Université Libre de Bruxelles and Collège de France (CNRS) now introduces a remarkably simple yet powerful approach. The researchers propose an effective “swap” model that leverages the spin degree of freedom of ultracold atoms. By assigning a complex phase to the exchange—or “swap”—of two spins, the system naturally acquires the fractional statistical behavior characteristic of anyons.

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