Femtosecond Laser Shaping

Marcos Dantus has pioneered the use of shaped ultrafast pulses to probe molecular properties and control chemical reactions, as well as for practical applications such as biomedical imaging, proteomics, and standoff detection of explosives. His contributions range from the discovery of nonlinear optical properties and processes to the invention of laser optimization instruments; the development of theory to simulate and predict the interaction of molecules with shaped laser beams, to the development of ultrafast electron diffraction, and inventing an instrument capable of automated pulse compression which is enabling research around the world, as well as novel fiber laser designs. Dantus received his BA and MA degrees in Chemistry from Brandeis University. He received his PhD from Caltech in 1991 where he worked with A. H. Zewail, the father of Femtochemistry and the winner of the 1999 Nobel Prize in Chemistry. Dantus published 20 articles with Zewail between 1986 and 1993 on the development of Femtochemistry. Dantus has over 225 publications and was named Inventor of the Year by Michigan State University, given his 43 invention disclosures and 22 issued patents. He is a Fellow of the National Academy of Inventors, The American Physical Society and The Optical Society of America. Dantus regularly collaborates with different branches of the U.S. Department of Defense. Dantus has founded three companies: KTM Industries, which manufactures biodegradable packing materials; Biophotonic Solutions, which commercialized automated femtosecond pulse compression, and MTBIsense LLC which is introducing affordable headgear sensors that are simple to read and provide quantitative information for return-to-play decisions in youth sports. Dantus serves as Director of Research and Development of Total Power Inc., for which he formulated a biodegradable fuel additive for reducing consumption and emissions related to heavy industry and mining.

Prologue; Chapter One: Introduction; Chapter Two: Why Femto; Chapter Three: What is a Light Pulse; Chapter Four: A Pulse Goes Through a Transparent Medium; Chapter Five: Light Matter Interactions (Part One); Chapter Six: Light Matter Interactions (Part Two); Chapter Seven: About Femtosecond Pulse Generation; Chapter Eight: How to Measure Femtosecond Pulses (Part One); Chapter Nine: Shaping the Laser Pulses; Chapter Ten: How to Measure Femtosecond Pulses (Part Two); Chapter Eleven: Applications of Shaped Pulses to Biomedical Imaging; Chapter Twelve: Applications of Shaped Pulses to Standoff Detection of Explosives and Other Materials; Chapter Thirteen: Applications of Shaped Pulses to Surgery, and Material Cutting or Processing; Chapter Fourteen: Applications of Shaped Pulses to Communications; Chapter Fifteen: Applications of Shaped Pulses in Science; Chapter Sixteen: A Survey of New Directions Being Explored, and Potential New Applications; Chapter Seventeen: The Ultrafast Laser Scaling Revolution.