Donna Strickland: Nobel Lecture in Physics 2018

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our next speaker is Donna Strickland Donna is a Canadian experimental physicist born in May 1959 in the City of Guelph in southwestern Ontario she received her bachelor's degree in engineering physics from McMaster University in Canada in 1981 and obtained a PhD in optics from the University of Rochester New York in 1999 where she and her doctoral supervisor jajaja moo-hoo developed the technique to immensely amplify the intensity of short laser pulses without destroying the amplifying medium which was a severe limitation at the time for the achievable laser peak power this so-called chirp pulse amplification technique or cpa for short was described in a three pages long scientific paper published in 1985 donna was only 26 at a time and it was Donna Strickland's first scientific publication and a subject of her doctoral thesis her pulse amplification revolutionized the field of laser science and led to new advances in many different fields including medicine and the much-publicized eye treatments Donna Strickland is fascinated by lasers she has worked at the laser division of the Lawrence Livermore National Laboratory and at the Princeton Advanced Technology Center for photonics in optoelectronics materials in 1997 she joined the physics department of the University of Waterloo which is currently a professor leading an ultra-fast laser groups that develops high-intensity laser systems for nonlinear optics investigations she was named a fellow of the optical Society of America in 2008 and has chaired several of its committees in 2013 she serves as its president please join me in welcoming Donna Strickland on stage to tell us about the developments which led to this year's Nobel Prize [Applause] [Music] [Applause] [Music] so thank you very much so I'm here to tell you about how light interacts with matter and then when the light gets very intense it changes how it interacts with matter I'll tell you that how we made an intense laser and by the time we were finished we had to rethink how intense light interacted with matter so to start we first have to go back and see how does light interact with matter so through the centuries scientists wondered was light made up of particles or was light made up of waves and it went back and forth by the end of the 19th century scientists were pretty firmly in the light is a wave category so they were doing experiments with different colors of light shining it on material and watching electrons come off the material now when they shun the red light and I'm only going to describe light that we see the longest wavelength that we see with our eyes is red light and wavelength is given by the distance between the crests of the wave when they Shawn red light on material electrons did not come off when they tried to get the light as bright as they could electrons did not come off now when they switch to green light which has a little closer spacing of the crests electrons came off but they came off with very low speed they turned up the power of their green light and more electrons came off but always with very low speed and finally when they tried violet light which is the shortest wavelength that we can see with our eyes so the shortest distance between the crests the electrons came off with higher speeds and when they turned up the power more electrons came off but always with those same speeds now this flies in the face of light being a wave if you can imagine walking on a beach that's stony Beach and if you just have small sea I know I talk to a lot I don't need a mic so when you walk on a beach and there's stones and you just have little ripples in the waves the stones don't even move but if the waves are really crashing in you will see those stones flying up the beach and this is how waves would usually move objects and so when we turned up the power of the light we certainly expected that the electrons would fly off faster and yet they didn't so it's this man here Albert Einstein who probably thought of almost all of physics all on his own what he won the Nobel Prize for though was explaining this effect and so we and optics are pretty proud of the fact that this is what he won the Nobel Prize for so what he figured out was that light actually is quantized in its energy there is a minimum energy unit of light that we now call the Photon it's a wave-like particle so what it says though is that the total energy in your light is then the energy of an individual photon multiplied by the number of photons the other thing that he figured out then is that each photon has an energy given by this wavelength and so I'm going to do an analogy because it's harder for us to feel the energy of light so we'll use gravity that we all know about standing on the earth and that if we drop the ball from higher up it would be faster when it hit the ground the higher up you can drop it so now a red photon is a small photon so we're going to imagine playing basketball with a child size basketball depth and so if it's a red photon playing basketball no matter how they try even up on their tippy toes they cannot reach that net to drop their electron through and no matter how many of these childlike photons there are the electron is never going to get through that basketball net now if you have a green light that's like an adults playing with a child size basketball net and they can actually dunk through but only barely they're only staying slightly taller than the basketball net and so when they drop their ball through ups we have to go back you can only you have to drop your ball there you go see so slow because it's just slightly taller but the violet photon is like your pro basketball player they're the very tall good people and so they're well above the net and when they drop their balls through the net boom a lot more speed but it wouldn't matter how many of these violet photons they had they would all be dropping at the same speed through the net just more electrons coming off so usually when people study the photoelectric effect it's about quantum mechanics but that's not what I want you to concentrate on what it really told us about how light interacts with matter is that it's always one photon meeting up with one atom at a time and they meet with each other and if that photon has enough energy more than the energy that the atom is holding on to its electron it can then send the electron on its way and when there's more photons coming they interact with more atoms but always one photon meeting one atom at a time and that's how we understood how light interacted with matter through the beginning of the 20th century and then Along Came this woman Maria gave admire the woman who won the second the second woman to win a Nobel Prize now I'm not going to talk about her Nobel prize-winning workers I know nothing about it I'm going to tell you what she did for her PhD in 1930 she published the paper in 1931 and I cited that 1931 paper in my own PhD so I don't know why she thought about this right maybe she brought her woman's way of looking at science and thought why don't photons get along why don't vote on want to work together right because if two photons would just come into that atom at one time they would share their energy and two little red photons would have the same energy as one violet photon and then the there we go it would have an electron come through with pretty high speed this is what we now call multiphoton ionization because there's more than one photon in the interaction she didn't get to call it that I don't know what she called it it was all in German um so so now we could understand that but nobody had seen it don't forget I Stein was actually sitting there wondering why the experimentalists were seeing what they were seeing Maria gave admirer had nobody had seen anything like this so I don't know what made this woman think about it but in fact nobody would see this effect for another thirty years it was Peter frankenz group at the University of Michigan and I know I have a lot of Michigan people in the audience that were the first people to see a multiphoton effect now they were doing their experiment not and with atoms that would eject electrons but what happened was that two red photons were momentarily absorbed by an atom and then when the atom wanted to let that energy go it didn't let it go as two red photons it let it go as one photon with twice the energy so you'll see then that the wavelength here is half well does that looks less than half what whatever look all of a half can't have everything right anyway so this is that what we call second harmonic generation all right and we now see it more routinely but this was something to see in 1961 so then it begs the question why did it take another 30 years to see what Maria gave admirer had predicted back in 1931 what was special about 1961 well so we've been mentioned in the previous talk what was special about 1961 is that in 1960 the laser was born so because I'm giving a Nobel lecture I do want to honor all of the people that have won Nobel prizes for the laser bass off broker often towns were really honored for developing the maser the maser came before the laser and the M is for microwaves rather than light in lasers and logically it was easier to make a maser than a laser and so that was done in the 50s and they won a Nobel Prize but it was the precursor to the laser art shallow than one for laser spectroscopy later on but he had a lot to do with understanding how laser works but I want to give credit to this man Theodore Maiman working at Hughes Aircraft he's the one who won the race there was a race on at the end of the 50s and into 1960 who would be the person who would first demonstrate the laser and it's this man Ted Nieman so 1960 the laser was born and that's why Peter Franklin's group could see this nonlinear optical effect now why is that regular light is shining on me very brightly here sunlight or what have you is like this bulb right up here and in normal light photons of every color is coming off that's why it looks white they go off in all directions and they also don't talk to each other they all go off whenever the heck they feel like it no cooperation whatsoever that's not how a laser works a laser as I'm using right here and I'm going to shine on the wall over there you will see that the light only goes in the one direction where I shine it you don't see it going over there because the light's not going into your eyes the light's going over there so we already have it concentrated into one beam you'll also see that the laser is just one color and in the case of the laser pointer just green they also the photons in the laser all talk to each other and when one's out of crest they're all at a crust and so each of these photons are going together and so they are making themselves to be a giant wave and a giant wave means there's the density of photons is greater so let's go back and think about the linear case here's what they saw before 1960 just regular light photons of every color just in case you don't recognize them those are the photons waving at you and because there was no cooperation the density of the photons is not very high so also when you may be take a lens and you think you should put in sunlight down to a point I'll tell you it's not going to a point we can only focus light down to a wavelength so the light that we see is about half a micron the laser eye bildt's one micron so we're gonna go with that one micron is a thousandth of a millimeter and so you can't focus your beam any smaller than that to concentrate your photons any better than that but the size of an atom is much much smaller now because I'm standing in Sweden I'm going to tell you that the dimension of an atom is an angstrom but we're not really supposed to use that unit anymore I'm sorry about that my Swedish friends we have to say that it's 1/10 of a nanometer all right so this atom is actually 10,000 times smaller than you can focus the light so when you blow up that atom because of the concentration of photons you know you're lucky to have one atom meet one photon there's really almost no chance of two photons finding one atom at the very same time but not true with a laser light the laser light have all these single coloured photons happily shaking together I don't know if mine are shaking together but they should be shaking together and so they pack in a lot tighter and so you have some chance of seeing two photons in the volume of the atom at the same time I want to credit Nicholas Bloomberg and the person who won the Nobel Prize for nonlinear optics I'm also going to tell you that it would took a long time for me to realize there was a difference in multi photon physics and nonlinear optics because I was at a conference celebrating 50 years of nonlinear optics and I'll just tell you the people that study molecules and atoms those are the atomic physics types they say when they watch in the atom that they're doing multi photon physics those of us who actually study light coming out we're doing nonlinear optics but to me it was a very subtle difference so this man wanted for nonlinear optics so here we go we now have a chance of two photons so this gets me to my PhD Sherrard gave me a paper written by Stephen Harris of Stanford University and he had this idea that lasers were sort of stuck in the visible to the infrared but we might want this wonderful type of radiation in high-energy photons past the violet ultraviolet maybe even out to the extreme ultraviolet so for that we can't just do second harmonic or even third harmonic he had come up with theoretically ways to maybe have 15 photons be grabbed by one atom and release a photon that's got 15 times the energy so I'll George said you know do you want to do that just think about this paper and see what you want to do for your PhD so I came up with a way to maybe be in twice ionized nickel I would be able to absorb 9 photons so that was supposed to be my thesis never got to it anyways that's why I needed a high intensity laser and so I later it self was not going to get 9 photons squeezed in turn atom we needed an intense laser so how did we do it so first I want to go back to this laser that I have in my hand the power of this laser is about 1 milliwatt or a thousandth of a watt I can make it a pulse one second long pulse by stopping it opening it up and shutting it one second later now in that pulse of light then because powers energy per unit time if my time unit is 1 second that's 1 milli Joule of energy now I can also shine that on my hand and it doesn't hurt at all I won't shine it in your eyes but I'm gonna put it in my hand and tell you that that millijoules hitting my hand every second doesn't hurt at all and yet my paper that was only three pages long and got me this Nobel Prize only had one milli Joule of energy created it's also all the energy you need to slice your eyeball up it's all the energy you need to cut glass and yet it doesn't hurt my hand at all and so what's the difference well if I had shown that one second pulse of light out to where the moon is and I have no idea where the moon is but and and I couldn't do it anyway it would be the beginning part of the pulse would actually be this is always the one that for me let's go oh there we go the front part of the pulse would actually be 2/3 of the way to the moon before the end of the pulse would leave the laser that's how fast light travels and so now in our one-second pulse we have one mill a jewel of energy in this one second long pulse of light now what did the Franken group have in order to see that very first multiphoton effect they had light that was one millisecond long so that's a thousand times shorter still 300 kilometer long line of light I will tell you they had more than a millage oh they had a Joule so they had a thousand times shorter and a thousand times more energy and then with that million fold they were to see the odd time an atom grab two photons at once the laser that we built in Rochester though was shorter than that we squeezed it down some more and in fact we squeezed it down so that one milli Joule of energy was in one picosecond or just a third of a millimeter so all of the many photons it would have stretched two-thirds of the way to the moon were squeezed down till they were just a third of the millimeter we packed those photons in so I know that my supervisor and colleague will be coming up here and telling you all the amazing things this laser has done for us I'm sure even some of them are going to be he's going to talk about things going on in space but I'm going to bring us back to earth I'm gonna bring us to Rochester New York in the United States where I did my PhD at the Institute of optics at the University of Rochester and I did my research here at the laboratory for laser energetics and there I am back in the day now inside this laboratory for laser energetics was this absolutely beautiful dye laser it was red and green and as I said it just seemed like a Christmas tree to me and I wanted to work with Gerard in this wonderful group it is a dye laser a dye laser is a type of short pulse laser in fact this laser the pulses were actually ten times shorter than what I'm talking about so only a 30th of a millimeter long so we had short laser pulses problem is dye lasers don't like to grab their energy and hang on to it and so that you can't get a big energy diet laser so you can have short pulses but the reason that the laboratory for laser energetics was there was to study laser fusion and to study laser fusion you need a big laser and they had a big laser this was known as the mega laser it was 24 beams and it could produce a kilojoule of energy not a millijoules a kilojoule that's a million times more energy so in the laser lab we had short pulses and we had big energy lasers but we couldn't put them together more than one problem one the dye laser had red photons and this one wants to amplify infrared photons so they wouldn't have spoken to each other but there was a bigger problem when people tried to put slightly short pulses even into these lasers what they found was that the rod would actually get drilled all the way through and you were left with a very expensive piece of glass that wasn't any good so that did so they had a stop trying to put short pulses down their laser rods because these nonlinear optical effects were happening inside the laser rods and they were drilling holes all the way through them so that was the conundrum that we were in in the early 1980s and then gerard had his beautiful idea so there are no pictures because I hate having my picture taken I've had to get used to it since October 2nd but there are no pictures which are not you together so we were out of meeting a few years back and took this picture so this is a very simple beautiful idea this is what we want here we want a lot of energy we want it in a very short pulse we just don't want that in our amplifier so if we don't want that in our amplifier what can we do just start with a short pulse strategy to make it a long pulse amplify it up and then about the end compress it all the way back down and here you have what I like to call a laser hammer so now how did we actually do it we're going to go back to this lab because this was the lab by now you'll see I've changed the title of it even though I'm showing you the very same laser and so the green beam is actually not a green laser this is the laser back here it's infrared you can't see the beam coming out of the laser because it's infrared and we can't see it neither can the camera the kind of mirrors that we use in a laser lab direct just the color we want to direct and so this green light bent at this mirror but the infrared came on through it would have gone to a beam dump to protect all of us from I feeling the heat of that very strong laser and so that laser how the same wavelength as the big neodymium glass amplifiers that we wanted to use so that was the laser I was to use you can also see there's simply no room in the end for me there was one packed lab but they shoved me into that corner where the infrared came out and there I am in 1985 with up 1.4 kilometers of optical fiber so why did we need this fiber well there was one advantage of it's not why we needed it because there was no room for me here once we had the light going down the fiber that fiber then went through the air ducts down the length of the laboratory for laser energetics where I built the amplifier at the other end of the building that was one thing but two other reasons that we needed this fiber is that the laser the pump the dye laser was not as short as we wanted and we needed more colors I'm going to explain why we needed more colors I don't have time to tell you what nonlinear optical effect made the colors you'll just have to believe me that it did and then this is the component though what we really needed the fiber for this was our pulse stretcher so first to understand pulse stretching we have to know why do we need a lot of colors in order to make a short pulse if you watch just one of these colors and we can just do the red one you see it goes along there a red wave would go on forever now if you take more colors and you say that you want all of them to start here you'll see that each wavelength starts to come apart you don't have to go very far until some pekes while others are troughs and so if one waves a peak and the other waves of trough they cancel each other out to be nothing and so the more colors you can add in the quicker you will get to where it's zero and so the more colors you have the shorter pulse you have so we created the colors in the fibre and now it's time to stretch it how does that work well in the way that light interacts with matter I said that the red photons have the least energy when they meet up with their atoms they sort of shake hands but then they say we have you know have nothing in common off you go so they actually run faster than the green and by the time it's a blue photon they're actually considering some time do we or do we not want to interchange your energy and it takes a little longer for that blue one to the side now and keep on going so now if you go down fiber you will see that the red ran the green walked and the blue sort of crawled and if you go down something like 1.4 kilometers of fiber well the red ran the green and now you have a long pulse so I want to explain the name of chirped pulse amplification a birds chirp it's called a chirp because the sound frequency changes in time through the note that he's making so you'll see that in the way to get a long pulse is to have the red frequencies out first and then the green and then the blue so through our laser pulse now the frequency changes and that's called a chirp it's called chirp pulse amplification because this is an hour stretched pulse that we want to amplify up so how does the amplification work so it's it's some material that has some atoms and sitting there not doing anything they have to be excited by some kind of energy source the original lasers and the laser that I used you just use flash lamps you'll see that it lights up most not all most of the atoms and a good storage medium will hang on to that energy and stay excited until a photon decides to come by so then you can have a photon come along and meet up with an atom and because we've excited these atoms so they have the very same energy as the photon that we're going to try to amplify they meet each other the photon says to the atom I'll take your energy with me and now we have two photons and that atom lost its energy those two photons are marching and step together and they meet two more atoms and now we have four photons and we've given up two atoms of energy and by the end we'll have eight photons and they've given up the out four more atoms of energy now this is actually very wasteful because you'll see that by the end of it we've left most of the energy there in the amplifier so that's a complete waste and we don't want to do that if it was a laser we were putting mirrors on either end and have it go back and forth until we steal all of that energy and this is then why we have to keep building huge lasers if we want a lot of energy the laser rod itself determines the energy per unit area that you can take and if you want to grab it all you actually have to put in almost that much energy to start to snowplow through and take the energy so each amplification gets a certain energy per unit area if you want more energy you must get make your beam bigger you must make your amplifier bigger and you plow through again the other thing I want to point out that is that the laser material decides what's the energy per unit area but the nonlinear things that can cause damage is the energy per unit volume so once you know what laser you're using that determines how much you must stretch the pulse so that you keep it below any kind of damage threshold so that's why we would have to chirp based on the type of laser that we used so now that we're amplified up it's just time to compress and so with a pair of parallel gratings greetings are act like prisms that send different colors of light out to different angles and so if you watch the path and you'll see the red because it was stretched it's further ahead than the green and the blue is trailing that when it comes off this grate and in each goes and their own angles the by the time the blue one has managed to get to the grading the red one had to travel all the way back here and could get here so that when they all leave the second grading they're all going together and we've put all of the photons back to gather in time and so we have a short pulse so then it was just time to measure it my colleague Steve Williamson came into my lab with history camera one night and together we measured did I or did I not actually have an intense short pulse and the answer was yes so we were very happy that night in 1985 so what did we do with it well remember I wanted to study well I want to study harmonic generation that proved too difficult so we're going to go back to the idea of multiphoton ionization and we thought that we would just kick that electron and give it so much energy that it would be able to come out of this well that it sits in in the atom and so all those photons would come up and kick that electron out that's what we were expecting to see but that's not what we saw we have made such an intense laser that the photons were packed in there so tight we no longer had to worry about them being photons it was back to being just one giant wave now although it's a short pulse wave so each crest gets a little bit more intense and a little bit more intense and so what happens when you have a giant wave is that it interacts with the atom that was sitting in its potential my head can be the electron and it would the wave would push it this way and then the wave would push it that way and then it pushed it more and it pushed it more and finally pushed it so much that electron was allowed to go out of the wealth but not only does it go out of the well it goes out of the well into this giant electric force and it is like a cannon being shot right out of there now can either leave or in two femtoseconds that lights to own back and it may be driven right back to the ionic core it just depends and I'm not here to tell you about what happens oops let me show you did I show you at least the electron right now no there you go the electron at least went out I'm gonna leave that to my PhD supervisor colleague and friend Gerard mermoo to tell you about what we understand now about the new standing intense laser light interacting with atoms and I will just thank all the people I want to thank the people that built the orig cpa with me of course yard but also steve williamson and Marcel Bouvier who are here with me today Gerard likes to tell people how I said that CPA would not be a good PhD project or thesis could not be my PhD thesis I don't know why he tells the story because I was right it could not be I had to do science with it which I did multiphoton ionization and I want to thank the gentleman that helped me with that project as well and finally I would like to thank the creative team at the University of Waterloo for making these wonderful slides for me thank you very much [Applause] [Music] [Applause] [Music] [Applause] [Music] you

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Length: 32min 14sec (1934 seconds)

Published: Mon Dec 10 2018