I've read time and again, as I dig through all the available literature, that in quantum computing, the smallest unit of valuea qubitmust remain "secret" or unknown until such a time as it is measured. In StackOverflow, I even read that, "in order for a qubit to work as one, its state has to be secret from the rest of the physical universe, not just from you. It has to be secret from wisps of air, from nearby atoms, etc. On the other hand, for qubits to be useful for a quantum computer, there has to be a way to manipulate them while keeping their state a secret. Otherwise its quantum randomness or quantum coherence is wrecked" (source: Does anyone know what "Quantum Computing" is?, answered by Greg Kuperberg). This notion of the the secrecy of a qubit went beyond anything I've read so far, but nonetheless, why should this be...I mean, what explains and justifies this strange propertythis secrecy or unmeasurability of a qubit? Hopefully the answer to this question will help me to start making the mental transition from classical computing machines.
It's because quantum stuff only interferes if every detail everywhere ends up the same.
For example, the Hadamard operation H
sends the state 0⟩
to √½0⟩+√½1⟩
and the state 1⟩
to √½0⟩√½1⟩
.
H 0⟩ = √½0⟩ + √½1⟩
H 1⟩ = √½0⟩  √½1⟩
A neat thing about H
is that it is its own inverse: if you apply it twice, it undoes itself.
H H 0⟩ = H (√½0⟩ + √½1⟩)
= √½ H 0⟩ + √½ H 1⟩
= √½ (√½0⟩ + √½1⟩) + √½ (√½0⟩  √½1⟩)
= ½ 0⟩ + ½1⟩ + ½0⟩  ½1⟩
= (½+½) 0⟩ + (½½) 1⟩
= 0⟩
H H 1⟩ = H (√½0⟩  √½1⟩)
= √½ H 0⟩  √½ H 1⟩
= √½ (√½0⟩ + √½1⟩)  √½ (√½0⟩  √½1⟩)
= ½ 0⟩ + ½1⟩  ½0⟩ + ½1⟩
= (½½) 0⟩ + (½+½) 1⟩
= 1⟩
But now consider what happens if, between those two Hadamards, we use a controllednot to attempt to copy the qubitbeingHadamarded's value onto a second qubit.
Even though we only use the qubit as a control, the owninverse property breaks:
H₁ C₁NOT₂ H₁ 00⟩ = H₁ C₁NOT₂ H₁ 0⟩⊗0⟩
= H₁ C₁NOT₂ (H0⟩)⊗0⟩
= H₁ C₁NOT₂ (√½0⟩ + √½1⟩)⊗0⟩
= H₁ C₁NOT₂ (√½00⟩ + √½10⟩)
= H₁ (√½00⟩ + √½11⟩)
= √½ H₁ 00⟩ + √½ H₁ 11⟩
= √½ (H0⟩)⊗0⟩ + √½ (H1⟩)⊗1⟩
= √½ (√½0⟩ + √½1⟩)⊗0⟩ + √½ H (√½0⟩  √½1⟩)⊗1⟩
= ½00⟩ + ½10⟩ + ½01⟩  ½11⟩
The second qubit adds more room to the state space, and the CNOT moves some of our state into that extra room. So instead of the computation folding the states back in on themselves to cause destructively interference they... just kinda spread out.
Without destructive interference, you might as well just be flipping coins instead of rotating qubits. So carefully managing this effect is very important in quantum computation.
You can try the example for yourself in the toy circuit simulator Quirk, which has inline state displays:

Hi! I did check out your simulator months ago and had fun tinkering with it! I'll try and revisit it later today with a fresh mind and see if it makes more sense. Your tutorial video was very welcome. – ShieldOfSalvation Oct 25 '17 at 15:59
Since you quoted my own answer to another SO question, I hope that I can give you something of a conceptual answer. It's one of the principles of quantum probability that if you measure a property of a quantum object, you always might change its state. This is illustrated for instance in the SternGerlach experiment with electron spin, which is described very nicely in the Feynman Lectures on Physics. The spin state of an electron is a clean example of a qubit and it is very convenient for thought experiments (even though it is not popular at this time for qubit implementations in QC technologies). You can measure whether a qubit is spin UP or spin DOWN, or you can measure whether it is spin LEFT or spin RIGHT. If you measure the spin in the same direction twice in a row, you will get the same answer, so that the qubit can (among other things) act like an ordinary bit. However, if the qubit is spin RIGHT, and if you then measure its spin vertically, then that measurement has the effect of erasing the answer to the horizontal spin measurement. I.e., you will get an answer of either UP or DOWN, and for either answer, a horizontal spin measurement afterwards will be split 5050 between UP and DOWN.
This is just one example of a more general principle, that two measurements can interfere with each other. (Mathematically, the measurements might not commute.) Moreover, what matters is not whether you personally carry out the measurements, but rather whether any entity measures your qubit, or in other words whether any entity interacts with its qubit state. These delicate probabilities, that can be ruined by noncommuting measurements, are exactly what powers quantum computation as, what I called it before, "randomized computation on steroids". Thus the qubits must be kept secret until the end of the computation, or else the rules of quantum probability will be wrecked and the quantum computer will degenerate to (at best) a classical computer with access to ordinary randomness.
In this answer I'm not saying much about what exactly is different about quantum probability. Well, that is not an easy topic and if you want to learn it, I would recommend a textbook such as Nielsen and Chuang. But part of the essence of it is that in quantum probability, different probabilistic histories can "interfere". This is illustrated for instance in the twoslit experiment, where a photon has some probability of making it through either of two slits to reach a detector. But if both slits are open, the probability (or more precisely the quantum amplitudes that yield the probabilities) can cancel; or they can reinforce each other to produce an amplified probability that is greater than the chance of passing through either slit alone. Precisely because these effects violate the normal rules of probability, they require secrecy, i.e., the effect is wrecked if any entity witnesses which slit the photon travelled through.

I notice both in your response and in Craig Gigney's, no mention is made of the HUP, i.e., the Heisenberg Uncertainty Principle (google.com/…). I've recently started studying this. Is the need for the "secrecy" of a qubit somehow explained by the HUP? – ShieldOfSalvation Oct 25 '17 at 15:01

There is a generalized version of the Heisenberg uncertainty principle which is due to Robertson and Schrodinger and is often called just the "generalized uncertainty principle". You could say that the need for secrecy of a qubit is explained by this uncertainty principle, or you could even say more directly that it is expressed by this uncertainty principle. The issue is noncommuting measurements in general, and not just position and momentum as in the Heisenberg case. en.wikipedia.org/wiki/Uncertainty_principle – Greg Kuperberg Oct 26 '17 at 1:03
Here's a short answer:
The state of a qubit must remain secret because of the measurement postulate in quantum mechanics. When you measure a quantum state, the wavefunction of the state collapses to the measurement's result.
In the case of a qubit in quantum computing, the said qubit would very likely be entangled with other qubits and the collapse of its wave function would affect the entire state of the computation.
As for the part "in order for a qubit to work as one, its state has to be secret from the rest of the physical universe, not just from you"::: It does not matter what or who measures a given qubit or what happens with the measurement result afterwards. If your qubit interacts with a nearby atom in a way that collapses its wave function in a subspace (in other words, the atom measured the qubit), it still affects the overall computation.

I'd like to add that you also mention a very important challenge in quantum computing. The qubit must remain secret (completely isolated from all environment) but you must also be able to access it for readout and logical gates... The challenge is to have an on/off switch for interaction, and that's a nontrivial task. Some architectures have incredible individual qubits (ex: spin qubits in donors), but the price of that highquality is that it's very hard to perform 2qubit operations on the said qubit (it's so well isolated...) – Exeko Mar 17 '18 at 18:12