Rising up, Donna Strickland had one aim in thoughts: Earn a Ph.D. However she didn’t know what topic she needed to pursue till she started her undergraduate research in physics at McMaster College, in Hamilton, Ont., Canada. It was there that she obtained fascinated by finding out lasers after taking a course on the topic.
The subject appeared “actually cool—like one thing from a science-fiction novel,” Strickland says. Little did she know that her newfound ardour would at some point earn her a Nobel Prize in physics.
Donna Strickland
EMPLOYER
College of Waterloo, in Ontario
TITLE
Physics professor
MEMBER GRADE
Honorary member
ALMA MATER
College of Rochester, in New York
Whereas conducting analysis in optics for her doctorate on the College of Rochester, in New York, Strickland labored with French physicist Gérard Mourou, a laser pioneer and Nobel laureate. Mourou led the event of the Excessive Mild Infrastructure community of physics laboratories constructed to generate and research intense laser gentle. Collectively, whereas experimenting with how one can improve a laser’s peak energy with out damaging it, they invented the chirped-pulse amplification approach. CPA, which produces quick laser pulses that attain excessive depth, now’s utilized in corrective eye surgical procedure, medical imaging, smartphone manufacturing, and lots of extra purposes.
Strickland and Mourou shared the 2018 Nobel Prize in physics with IEEE Life Fellow Arthur Ashkin, who invented a separate know-how: “optical tweezers,” which use low-power laser beams to govern residing cells and different tiny objects.
Receiving the Nobel was “life-changing,” Strickland says, including, “Your life can change in a single day with out you being prepared for it.”
Her invention additionally earned her this 12 months’s IEEE Honorary Membership, which is sponsored by IEEE. She says the popularity is particular as a result of her colleagues nominated her for it.
“Donna’s work has been transformative. Her seminal analysis on chirped-pulse amplification is the gold normal of analysis,” certainly one of her award endorsers stated. “Moreover, she is a real function mannequin to legions of engineers all over the world. She is a particularly giving individual and a shining instance of what an IEEE honorary member needs to be.”
Strickland is a physics professor on the College of Waterloo, in Ontario, the place she leads a gaggle of researchers that’s creating high-intensity laser programs for nonlinear optics investigations equivalent to producing midinfrared pulses by distinction frequency mixing and finding out the multifrequency Raman era approach.
Donna Strickland receives the 2018 Nobel Prize in physics from King Carl Gustaf of Sweden, on the Stockholm Live performance Corridor.Henrik Montgomery/TT Information Company/Getty Photographs
Paving the best way for high-intensity lasers
After graduating in 1981 with a bachelor’s engineering diploma in physics from McMaster, Strickland moved to New York to pursue a doctorate in optics on the College of Rochester, which on the time was thought of one of many high colleges for finding out laser optics. She joined Mourou on the college’s Laboratory for Laser Energetics, the place he was on the lookout for methods to extend lasers’ depth (its optical energy) with out damaging the gadget.
Pulsed lasers can focus gentle onto a small space for a short while to provide energy. Peak intensities elevated quickly for a number of years after physicist Theodore Maiman demonstrated the first laser in 1960. However the intensities plateaued for greater than a decade after 1970 as a result of amplifying the sunshine previous a sure level broken the laser.
In his analysis on how gentle interacts with matter, Mourou hypothesized in 1983 that spacing out and augmenting pulses earlier than bringing them again collectively may end in higher-intensity laser pulses with out harm. However he didn’t know how one can accomplish it, Strickland says. So for her doctoral analysis, she examined his speculation with completely different laser programs. None of her experiments labored, nevertheless.
“Donna is a real function mannequin to legions of engineers all over the world. She is a particularly giving individual and a shining instance of what an IEEE honorary member needs to be.”
It wasn’t till Strickland and Mourou attended the 1984 Worldwide Convention on Ultrafast Phenomena that they discovered the answer. The biannual occasion brings collectively scientists who’re creating instruments, methodologies, and methods used to review processes in atoms, molecules, or supplies that happen in millionths of a billionth of a second or sooner.
Strickland and Mourou attended a presentation on the convention concerning the newly developed optical fiber pulse compression of neodymium-doped yttrium aluminum garnet (Nd:YAG) lasers. With the approach, 100-picosecond pulses might be compressed to 1 ps utilizing nonlinear optics in an optical fiber to extend a laser’s spectral bandwidth. It was discovered that compression was most profitable when the pulses have been allowed to stretch by way of dispersion within the fiber.
“I used to be utilizing those self same lasers for my experiments,” Strickland recalled.
She and Mourou found out how she may safely create the high-intensity pulse: The heart beat wanted to be stretched earlier than it was amplified somewhat than afterward, as what had been performed. Stretching the heart beat meant it might be recompressed to provide the specified depth.
To check her concept, Stickland and Mourou constructed a system on the Laboratory for Laser Energetics that was composed of a 2-watt Nd:YAG laser, 1.4 kilometers of optical fiber, an amplifier, and a pair of parallel gratings.
The Nd:YAG laser pumped a brief pulse at 100 ps into the optical fiber. As the speed of sunshine relies on wavelength, the pink element of the sunshine propagates sooner than the blue throughout the fiber.
That’s known as a “chirped pulse,” Strickland says, as a result of a hen’s chirp has an identical frequency construction.
The chirped pulse makes the length of the heart beat longer and spreads out the depth in order that it doesn’t harm the laser. The stretched, lower-energy density pulse was then amplified and handed by way of a pair of parallel diffraction gratings—which allowed the trailing blue element to catch as much as the pink. Each have been reassembled by reflecting off the gratings. The reassembled pulse was thrice extra highly effective than the unique one, Stickland says.
The approach, which was named after the chirped pulse, has since paved the best way for the shortest and most intense laser pulses ever created, making it attainable to construct extra compact and exact laser programs.
Strickland and Mourou’s 1985 paper “Compression of Amplified Chirped Optical Pulses,” was printed in Optics Communications. It was Strickland’s first printed analysis paper.
From Princeton to Waterloo
After serving to develop CPA, Strickland nonetheless wasn’t positive what profession path to pursue. She sought recommendation from her colleagues, and one informed her that Paul Corkum, a physicist who labored within the Canadian Nationwide Analysis Council’s ultrafast-phenomena division, was getting his first postdoctoral analysis fellow that 12 months. Corkum, who specialised in laser science, pioneered the event of attosecond physics. Strickland favored the sound of that.
“I keep in mind telling the opposite doctoral candidates in my analysis lab that Corkum could not know my title but, however I used to be going to be his second postdoc,” she says. She obtained her dream job in 1988 and labored for him for 3 years.
In 1991 she grew to become a physicist on the Lawrence Livermore Nationwide Laboratory, a U.S. Division of Vitality facility in California.
Whereas she lived on the West Coast, her husband, a physicist, lived on the East Coast, working at Bell Labs in Murray Hill, N.J.
After spending a 12 months aside, Strickland moved to New Jersey to affix the technical workers at Princeton’s Superior Expertise Heart for Photonics and Opto-electronic Supplies. She labored with electrical engineers, mechanical engineers, and chemists there, she says, and “if they’d a laser, I helped them out.” She helped a professor construct a CPA laser and assisted a analysis group that was conducting nonlinear optical characterization of a brand new pulse amplifying materials.
Strickland says she thought she’d be working at Princeton till she retired, however after her husband left Bell Labs in 1996, they returned to Canada. Strickland joined the College of Waterloo’s physics division as an assistant professor. She was promoted to affiliate professor in 2002. From 2007 to 2013, she served as affiliate chair of the division.
“After I was younger, I simply needed to get a Ph.D. and keep at school,” Strickland says. “Being a professor is the following smartest thing to being a pupil.”
She acquired the IEEE Honorary Membership on 5 Might on the IEEE Imaginative and prescient, Innovation, and Challenges Summit and Honors Ceremony, held on the Hilton Atlanta.
