Noted astrophysicist, cosmologist, and popular science author, Carl Sagan ends his book The Dragons of Eden with the following lines: “The universe is elegant and intricate. We wrest secrets from nature by the most unlikely routes”. Even though the subject matter of the book deals with his speculations on the evolution of human intelligence, this series of articles, should it manage to succeed in its aim, should serve the purpose of highlighting the veracity of his words. The fabric of the cosmos does present the human intellect with numerous challenges. As we unravel its umpteen layers, the excitement of having solved a mystery can be said to only marginally exceed the frustration at encountering new questions. In this mythical quest for secrets, as hope trumps disappointment, the cycle of discovery keeps reinventing itself as one puzzle replaces the next.
In my last piece, I had tried to illustrate how the element of uncertainty is embedded in the very fabric of quantum mechanics (QM). It is not of the kind we encounter in classical mechanics, where trusted laws can help us determine with absolute certainty which way a tossed coin will land. Uncertainty in QM refuses to reveal its secrets beyond a certain ‘probability wave’, or more precisely wavefunction , that predicts the likelihood of the occurrence of an event. It is only when we interact with the system, with the intention of measuring some of its property, that this haze of multiple possibilities clears and assumes a definite outcome.
Mathematically, this evolution can be said to have two distinct stages. In the first stage, the probability wave of an electron (or some other fundamental particle) evolves over time – smoothly and gradually – according to Schrödinger’s equation. The second stage is when we make contact with the observable reality, causing the electron to snap to, let’s say, a particular position, thereby ‘collapsing’ the wavefunction. And therein lies the heart of our ‘problem’.
The quantum mechanical description of reality is clueless about this collapse. According to Schrödinger’s equation, wavefunctions do not collapse. It is simply a convenient add-on that helps theory agree with observations (I have come to believe physicists often do that). Since the cat is never observed to be both dead and alive, the explanation safely posits that the act of measurement causes the wavefunction to relinquish its state of quantum limbo and usher one of the possibilities into reality. But what is so special about the act of observation that causes this choice to be made? How are the different possibilities converted onto an actual, sharply-defined outcome? This dilemma is what’s known as the Quantum Measurement Problem and forms the core of several contending interpretations of QM that seek to explain what has so far only been observed.
Werner Heisenberg, who, along with Neils Bohr, formulated the Copenhagen interpretation, provides some particular useful insights regarding the nature of quantum reality in his book Physics and Philosophy. He writes, “Reality is in the observations, not in the electron.” This view is embodied in the Copenhagen interpretation which claims that a wavefunction is merely the mathematical embodiment of what we know about reality. Before we observe the electron, it exists in a ‘coherent superposition’ of all possible positions, snapping out of this haze when we measure its position. In this respect, the collapse is nothing more than the change in our knowledge about the whereabouts of the electron. What goes on behind the scenes, strictly speaking, lies beyond the scope of physics.
Crudely translated, this would imply that the cat is to be considered alive and dead at the same time! Naturally, this worldview, even though quite popular, does not sit well with a number of physicists and, yes, philosophers. Detractors question why fundamental physics should so closely be tied to human awareness. If we were not here to tinker around with laboratory equipment, would wavefunctions never collapse, or better still, not exist? Can bacteria or ants not be observers of quantum reality and a change in their ‘knowledge’ be associated with the wavefunction collapse?
For several years, the Copenhagen interpretation of QM held sway in scientific circles. But its primacy was challenged 1957 by an approach formulated by Hugh Everett that subjects our classical instinct to another major upheaval. (I seem to be getting into the habit of saying this. But, well.) The many-worlds interpretation (MWI) denies the occurrence of the wavefunction collapse. Instead, it views reality as a multi-branched tree, where each possible quantum outcome is realized. The concept of the universe is enlarged to include an infinite number of ‘parallel universes’ within a larger multiverse so that anything that can happen actually does happen in one of the innumerable versions of our universe. In one universe you are reading these words while in another you are waiting anxiously for the grand gala opening of your first play. It’s all happening out there!
Needless to say, I have only scarcely begun to realize the impact that this can have on our understanding of not only science but widely disparate disciplines like philosophy and spirituality. What if I were to put a gun to my head and pull the trigger? Would I be able to pull off this ‘quantum suicide’? If MWI is right, there will be a copy of our universe where I am alive and well. Should that mean my consciousness is, in essence, immortal? Quacks have been quick to jump on this bandwagon and have sought to use MWI to give credence to the idea of a soul that defies death and simply changes its ‘vessel’ as it hops from one universe to the next. Maybe that is how our ancestors tried to comprehend the strangeness of the universe we inhabit. Who knows!
But physicists are not in the business of mysticism and they have never really liked playing with odds. Some promising steps have been taken in the direction of separating spirituality from science through work on the phenomenon of ‘decoherence’. Decoherence provides an explanation for the appearance of the wavefunction collapse by postulating that much of the quantum weirdness of large objects ‘leaks’ from large objects because of their interaction with their environment. In other words, it is the framework which tries to explain how quantum uncertainty morphs into the well determined outcomes of classical experimental physics and our intuitive understanding of reality. MWI, with its decoherence updating, can prove to be an encouraging direction in the evolution of quantum theory.
Through the course of this debate, I have tried to emphasize how the resolution of one conundrum often leads to the genesis of a new one. When Newton tried to describe the ‘music of the spheres’, he could have scarcely imagined a world in which reality is neither deterministic nor viewed as a single unfolding history. Nevertheless, standing on the shoulders of such giants, we have been steadily hacking away at the myriad layers of our cosmic onion. As our intuition grapples with what is revealed to us, we will continue to reconsider our definitions truth and reality. The implications are exciting and manifold. But, as I will attempt to elaborate on in my next article, we must be careful enough to view them through the lens of reason and scientific analysis. One must sift through all the hoopla and take care to not be swept away by the wave. Doing so, we will realize that science does not undermine the beauty of the stars. Instead, it makes even larger the canvas of their mysticism. After all, it was Bohr who said, “Anyone who is not shocked by quantum theory has not understood it”.
Note: For the sake of simplicity (and to avoid making this article too tedious a read), I have discussed only two of the several contending interpretations of quantum mechanics. Interested readers can, obviously, choose to further this understanding. The following Wikipedia page should be a good starting point: http://en.wikipedia.org/wiki/Interpretations_of_quantum_mechanics.
Images from http://farside.ph.utexas.edu and http://en.wikipedia.org.
In my last piece, I had tried to illustrate how the element of uncertainty is embedded in the very fabric of quantum mechanics (QM). It is not of the kind we encounter in classical mechanics, where trusted laws can help us determine with absolute certainty which way a tossed coin will land. Uncertainty in QM refuses to reveal its secrets beyond a certain ‘probability wave’, or more precisely wavefunction , that predicts the likelihood of the occurrence of an event. It is only when we interact with the system, with the intention of measuring some of its property, that this haze of multiple possibilities clears and assumes a definite outcome.
Mathematically, this evolution can be said to have two distinct stages. In the first stage, the probability wave of an electron (or some other fundamental particle) evolves over time – smoothly and gradually – according to Schrödinger’s equation. The second stage is when we make contact with the observable reality, causing the electron to snap to, let’s say, a particular position, thereby ‘collapsing’ the wavefunction. And therein lies the heart of our ‘problem’.
The quantum mechanical description of reality is clueless about this collapse. According to Schrödinger’s equation, wavefunctions do not collapse. It is simply a convenient add-on that helps theory agree with observations (I have come to believe physicists often do that). Since the cat is never observed to be both dead and alive, the explanation safely posits that the act of measurement causes the wavefunction to relinquish its state of quantum limbo and usher one of the possibilities into reality. But what is so special about the act of observation that causes this choice to be made? How are the different possibilities converted onto an actual, sharply-defined outcome? This dilemma is what’s known as the Quantum Measurement Problem and forms the core of several contending interpretations of QM that seek to explain what has so far only been observed.
Werner Heisenberg, who, along with Neils Bohr, formulated the Copenhagen interpretation, provides some particular useful insights regarding the nature of quantum reality in his book Physics and Philosophy. He writes, “Reality is in the observations, not in the electron.” This view is embodied in the Copenhagen interpretation which claims that a wavefunction is merely the mathematical embodiment of what we know about reality. Before we observe the electron, it exists in a ‘coherent superposition’ of all possible positions, snapping out of this haze when we measure its position. In this respect, the collapse is nothing more than the change in our knowledge about the whereabouts of the electron. What goes on behind the scenes, strictly speaking, lies beyond the scope of physics.
Crudely translated, this would imply that the cat is to be considered alive and dead at the same time! Naturally, this worldview, even though quite popular, does not sit well with a number of physicists and, yes, philosophers. Detractors question why fundamental physics should so closely be tied to human awareness. If we were not here to tinker around with laboratory equipment, would wavefunctions never collapse, or better still, not exist? Can bacteria or ants not be observers of quantum reality and a change in their ‘knowledge’ be associated with the wavefunction collapse?
For several years, the Copenhagen interpretation of QM held sway in scientific circles. But its primacy was challenged 1957 by an approach formulated by Hugh Everett that subjects our classical instinct to another major upheaval. (I seem to be getting into the habit of saying this. But, well.) The many-worlds interpretation (MWI) denies the occurrence of the wavefunction collapse. Instead, it views reality as a multi-branched tree, where each possible quantum outcome is realized. The concept of the universe is enlarged to include an infinite number of ‘parallel universes’ within a larger multiverse so that anything that can happen actually does happen in one of the innumerable versions of our universe. In one universe you are reading these words while in another you are waiting anxiously for the grand gala opening of your first play. It’s all happening out there!
Needless to say, I have only scarcely begun to realize the impact that this can have on our understanding of not only science but widely disparate disciplines like philosophy and spirituality. What if I were to put a gun to my head and pull the trigger? Would I be able to pull off this ‘quantum suicide’? If MWI is right, there will be a copy of our universe where I am alive and well. Should that mean my consciousness is, in essence, immortal? Quacks have been quick to jump on this bandwagon and have sought to use MWI to give credence to the idea of a soul that defies death and simply changes its ‘vessel’ as it hops from one universe to the next. Maybe that is how our ancestors tried to comprehend the strangeness of the universe we inhabit. Who knows!
But physicists are not in the business of mysticism and they have never really liked playing with odds. Some promising steps have been taken in the direction of separating spirituality from science through work on the phenomenon of ‘decoherence’. Decoherence provides an explanation for the appearance of the wavefunction collapse by postulating that much of the quantum weirdness of large objects ‘leaks’ from large objects because of their interaction with their environment. In other words, it is the framework which tries to explain how quantum uncertainty morphs into the well determined outcomes of classical experimental physics and our intuitive understanding of reality. MWI, with its decoherence updating, can prove to be an encouraging direction in the evolution of quantum theory.
Through the course of this debate, I have tried to emphasize how the resolution of one conundrum often leads to the genesis of a new one. When Newton tried to describe the ‘music of the spheres’, he could have scarcely imagined a world in which reality is neither deterministic nor viewed as a single unfolding history. Nevertheless, standing on the shoulders of such giants, we have been steadily hacking away at the myriad layers of our cosmic onion. As our intuition grapples with what is revealed to us, we will continue to reconsider our definitions truth and reality. The implications are exciting and manifold. But, as I will attempt to elaborate on in my next article, we must be careful enough to view them through the lens of reason and scientific analysis. One must sift through all the hoopla and take care to not be swept away by the wave. Doing so, we will realize that science does not undermine the beauty of the stars. Instead, it makes even larger the canvas of their mysticism. After all, it was Bohr who said, “Anyone who is not shocked by quantum theory has not understood it”.
Note: For the sake of simplicity (and to avoid making this article too tedious a read), I have discussed only two of the several contending interpretations of quantum mechanics. Interested readers can, obviously, choose to further this understanding. The following Wikipedia page should be a good starting point: http://en.wikipedia.org/wiki/Interpretations_of_quantum_mechanics.
Images from http://farside.ph.utexas.edu and http://en.wikipedia.org.