Aufrufe
vor 7 Monaten

Issue 03/2022

  • Text
  • Healthcare
  • Beauty
  • Injection moulding
  • Renewable carbon
  • Biodegradable
  • Compostable
  • Biobased
  • Wwwbioplasticsmagazinecom
  • Sustainable
  • Technologies
  • Polymers
  • Carbon
  • Renewable
  • Products
  • Plastics
  • Bioplastics
  • Recycling
  • Materials
Highlights: Injection Moulding Beauty & Healthcare Basics: Biocompatibility of PHA Starch

Feedstock Even biomass

Feedstock Even biomass has an expiration date Renewable biomass is one of the key clean energy resources that will help manifest a low-carbon future. However, the process of developing viable and sustainable biobased fuels, chemicals, and products from biomass suffers from similar limitations to stored produce – they decay and expire. Lynn Wendt, senior scientist at Idaho National Laboratory (Idaho Falls, ID, USA), has dedicated much of her research toward addressing biomass decay challenges. She pioneered the development of high-moisture lignocellulosic biomass – like switchgrass, corn stover, and miscanthus – and microalgae storage and handling systems. These systems not only stabilize biomass by delaying its decomposition but also by increasing its value in downstream conversion, making it easier to break down the biomass cell walls. A loaf of bread, a quart of milk, and a vat of microalgae… will eventually expire Fuel for the human body is typically grown or raised on the farm or in a garden and then stored, either as a dry good or in a refrigerator or freezer. While it’s stored, food can spoil. The same can be said for the biomass used to develop biofuels and bioproducts. After harvest, biomass is stored until it can be processed, and it has a shelf life, subject to the same natural decomposition methods. Like many of the foods we regularly enjoy, biomass and microalgae are best used when fresh or well preserved. Physiological and physiochemical processes, like internal heat generation and decomposition, degrade biobased materials after harvest and collection. The root of the problem is microbial respiration occurring within harvested materials, breaking down large molecules which are converted to carbon dioxide and lost to the atmosphere. These processes can rot or shrink the biomass materials and can even in very rare cases cause spontaneous combustion. Using science to control rot and decay Wendt’s course of research and discovery on valueadded biomass storage systems began in 2007 as she worked to define an approach to preserve high-moisture corn harvest remnants (e.g. corn stover) from uncontrolled decomposition. These efforts began her quest to understand the critical factors to carbon retention during storage and the use of microbial fermentative by-products (e.g. CO 2 and methane), anoxic environments (i.e. without oxygen), and other approaches to stabilize biomass storage systems and add value. The laboratory and field studies that Wendt organized defined both the practical considerations for biomass stabilization [1] and the economic [2] and environmental value proposition for this approach. It was while researching corn stover that Wendt expanded her research scope to include microalgae. Her goal was to manage its moisture and stability challenges. Microalgae have a high potential to remove atmospheric carbon as well as to be used for biofuels and bioproducts development. Microalgae: Not your average pond scum The microalgae moisture and stability challenges stem from inherently metabolically active conditions due to the combination of actively growing microalgae cells and the diverse bacterial community associated with outdoor cultivation ponds. If left to their own accord in high moisture environments post-harvest, microalgae can lose nearly half their value in one month. During their research on microalgae, Wendt and her team identified conditions that shifted microbial communities within microalgae storage ecosystems for preservation and production of value-added metabolic products for downstream conversion [3], namely lactic and succinic acids. Corn to algae to corn: The path to value-added biomass storage is not linear Applying lessons learned from her studies on post-harvest microalgae as value-added chemical producers [4], Wendt then applied the principle of value-added storage back to corn stover biomass, which ultimately spurred one of her fundamental scientific achievements: developing valueadded storage systems for corn stover. Wendt’s team embarked on a pathway to reduce the barriers responsible for biomass recalcitrance, or the resistance of plant cell walls to breakdown by enzymes and microbes. Focusing her research at the cellular level, Wendt began by observing the natural biomass recalcitrance within corn stover cell wall layers and tissues. She studied how these factors could be shifted during long-term high moisture storage so that the plant’s cell walls break down more easily. The alkali is sprayed onto freshly harvested corn stover, which is then compacted to remove oxygen and then stored so that alkali reacts with other elements in the corn stover to further the breakdown of the biomass. The culmination of this work involved detailing the fundamental connections and characterization of alkali-assisted storage to the downstream processing and reactivity of corn stover. Alkali added to the corn stover is a method to remove lignin, a compound in the cell walls of plants that makes them rigid and woody. Facilitating lignin removal during longterm storage and before further downstream processing, offers a more elegant, innovative, and cost-effective biomass feedstock processing method [5]. Alkali storage for corn stover helps create a more costeffective biomass feedstock processing method. Image courtesy of Idaho National Laboratory Securing the nation’s supply chains from uncontrolled loss in biomass storage is critical to increased production of decarbonized, sustainable biofuels and products. Through her scientific innovation and team leadership, Wendt is bridging the gap between fundamental and applied sciences and exploring an approach critical for commercialization of sustainable bioenergy. AT 14 bioplastics MAGAZINE [03/22] Vol. 17

Feedstock References [1] Compatibility of High-Moisture Storage for Biochemical Conversion of Corn Stover: Storage Performance at Laboratory and Field Scales, Frontiers in Bioengineering and Biotechnology, https://doi.org/10.3389/fbioe.2018.00030 [2] Techno-Economic Assessment of a Chopped Feedstock Logistics Supply Chain for Corn Stover, Frontiers in Energy Research https://doi.org/10.3389/fenrg.2018.00090 [3] Evaluation of a high-moisture stabilization strategy for harvested microalgae blended with herbaceous biomass: Part I—Storage performance, Algal Research https://doi.org/10.1016/j.algal.2017.05.016 [4] Microbial Community And Chemical Changes Related To Biological Self-Heating And Heat Damage During Storage Of Corn (Maize) Stover Biomass Feedstock. [5] Screening of Alkali-Assisted Storage Conditions to Define the Operational Window of Deacetylation within Storage Systems in the Bioenergy Supply Chain, Biofpr, https://doi.org/10.1002/bbb.2288 https://www.energy.gov/eere/bioenergy/articles/search-later-biomassexpiration-date This is a depiction of the feedstock logistics supply chain for wet storage. Image courtesy of Idaho National Laboratory 8–9 MARCH 2023 SAVE THE DATE cellulose-fibres.eu Cellulose Fibres Conference, the fastest growing fibre group in textiles, the largest investment sector in the bio-based economy and the solution to avoid microplastics bioplastics MAGAZINE [03/22] Vol. 17 15

bioplastics MAGAZINE ePaper