Seminar | November 22 | 2-3 p.m. | 120 Latimer Hall
Every year we extract over 4.2 GT of oil, 2.5 GT of natural gas, and 3.4 GT of coal to sustain our economies. Thats equivalent to 8.7 GT of carbon and 1.3 GT of Hydrogen. Almost all of these resources are burned to generate energy, causing over 30 GT of CO2 to enter the atmosphere which is unsustainable in view of climate changethe only significant exception is polymers, which fix 0.35 GT/yr of hydrocarbon resources (~3% of the total production) into valuable solid materials.
At the same time, every year we use over 12% of the world energy production (over 60 EJ) towards primary metals; most of this energy goes into mining, refining, and processing ~3 GT/yr of metal ores into usable metals, chiefly 1.6 GT/yr of steel, 50 MT/yr of Aluminum, and 20 MT/yr of Copper; it is accompanied by the generation of 3.7 GT of CO2 emissions, equivalent to ~20% of the emissions caused by burning oil and gas. This is the extent of our materials-energy nexus.
Could we break this inefficient cycle and replace metals with materials made directly from hydrocarbons? Carbon Nanomaterialsprimarily CNTs and grapheneoffer an opportunity. They can be made via pyrolysis of methane and other light hydrocarbons, with concurrent production of hydrogen. In the past decade, methods have been developed to convert CNTs and graphene into macroscopic materials (fibers, sheets, 3D structures) that could displace metals based on their propertiesstrength, electrical and thermal conductivity.
In this talk, I will present our work on understanding and controlling fluid phases of carbon nanomaterials and on converting such fluid phases into ordered macroscale materials with remarkable properties. I will show some early small-scale, high-value applications (medical, wearable, and aerospace) where these CNT materials are already proving to be advantageous.
I will then discuss why carbon nanomaterials could be great candidates to utilize natural gas on a very large scale (GT/yr) to make materials with zero CO2 footprint and positive hydrogen production. I will outline the scientific problems that need to be solved to realize highly-efficient synthesis and conversion of these materials and will present an estimate of the potential benefits of such a transition in our use of fossil hydrocarbons.
Matteo Pasquali is the Chair of the Chemistry Dept. at Rice Univ. He also served as Co-Director of the Carbon Nanotechnology Lab in the Richard E. Smalley Institute.