Studies of low-field nuclear magnetic resonance and Raman spectrometries for process analytical chemistry

McGill, Colin Adam

January 2001

No description available.

543

NMR spectrometry

Catalytic Pyrolysis of Cellulose, Hemicellulose and Lignin Model Compounds

Atadana, Frederick Williams

10 March 2010

The effect of HZSM-5 catalyst and NaOH pretreatment on the product distribution and bio oil properties from pyrolysis of cellulose, hemicellulose and lignin model compounds was investigated at 450 °C. NaOH pretreated and untreated cellulose was pyrolyzed on sand and the HZSM-5 catalysts; VPISU001 HZSM-5, BASF HZSM-5, and Sud-Chemie HZSM-5. The pyrolysis of cellulose on BASF and Sud-Chemie HZSM-5 catalysts increased the yields of the organic liquid fraction, total liquid and char while decreasing the gas yields. However the catalyst decreased the organic and char yields while increasing the water yields but there was no change in gas yields. The NaOH treatment caused a decrease in the organic and total oil yields relative to the control but the char yield increased. The change in gas yields was not significant. The characterization of the oils using FTIR and ¹³C−nmr showed that, the VPISU001 HZSM-5 with and without NaOH pretreatment caused elimination of the levoglucosan fraction while increasing the aromatic fraction. The NaOH pretreated cellulose pyrolyzed on sand reduced the levoglucosan groups while increasing the aromatic fraction of the bio oil. In the hemicellulose studies, birchwood xylan and NaOH treated xylan samples were pyrolyzed on sand and VPISU001 HZSM-5 catalyst. The organic liquid yields were very low and ranged from 3.3 wt% to 7.2 wt%, the water yields ranged from 17.8-25.7 wt%, the char yield were 17.8-25 wt% and gas yield were 40.9-49.6 wt%. The HZSM-5 catalysts increased the water and gas yields and produced the lowest char yield. NaOH pretreatment produced the lowest water yield while the char yield was the highest. The combined effect of NaOH pretreatment and HZSM-5 produced the lowest organic yield and highest char yield. The FTIR and ¹³C-nmr analyses of the organic liquids showed that the HZSM-5 catalyst promoted the formation of aromatic products, while the NaOH pretreatment promoted the formation of aliphatic hydrocarbons. The combined effect of NaOH pretreatment and HZSM-5 catalyst seem to promote the formation of anhydrosugars. The main gases evolved were CO, CO₂ and low molecular weight hydrocarbons. The HZSM-5 catalyst promoted CO formation while NaOH pretreatment promoted CO₂. The HZSM-5 catalyst produced the highest yield of low molecular weight hydrocarbon gases. The lignin and model compounds studies involved using low molecular weight kraft lignin, guaiacol, and syringol which were pyrolyzed on sand and VPISU001 HZSM-5 catalyst at 450 °C. The kraft lignin pyrolysis produced low liquid and gas yields and high char yields. The HZSM-5 catalysts increased the water yield and decreased the organic liquid yield. NaOH pretreatment increased the char yield and decreased the liquid products. NaOH and the HZSM-5 catalyst together decreased the char and increased the gas yields. The ¹³C-nmr and FTIR analysis showed that NaOH pretreatment promoted the formation of mainly guaiacol while the HZSM-5 catalyst formed different aromatic components. NaOH pretreatment promoted the formation of more CO₂ than CO whilst HZSM-5 catalyst promoted the formation of more CO than CO₂. Methane formation was enhanced by NaOH pretreatment. Other hydrocarbon gases were however enhanced by the HZSM-5 catalysts. Pyrolysis of the model compounds on the HSZM-5 catalyst showed an increase in pyrolytic water. The HZSM-5 catalyst promoted demethylation in syringol pyrolysis as compared to guaiacol. / Master of Science

oil properties

product distribution

char

bio oil

fast pyrolysis

model compounds

lignin

hemicellulose

cellulose

FT-IR spectrometry

13C-nmr spectrometry.

Influence of a Biodegradable Litter Amendment on the Pyrolysis of Poultry Litter

Tarrant, Ryan Carl Allen

02 November 2010

The effects of adding a biodegradable litter amendment (AmmoSoak), developed from steam exploded corncobs, to poultry litter prior to pyrolysis on the product yields and qualities were investigated. Mixtures of litter and AmmoSoak were pyrolyzed in a bench-scale fluidized bed reactor. The objective of the second phase was to start-up a pilot-scale fluidized bed reactor unit. The poultry litter had a lower higher heating value (HHV), higher moisture, ash, nitrogen, sulfur, and chlorine contents than AmmoSoak. Analysis of the poultry litter indicated a mixture of volatiles, hemicelluloses, cellulose, lignin, ash, and proteins. AmmoSoak had a simpler composition than the litter; mainly hemicelluloses, cellulose, and lignin. Bench-scale studies indicated that adding AmmoSoak affected the yields and characteristics of the products. Addition of Ammosoak increased the bio-oil and syngas yields and decreased char yields. Adding AmmoSoak to the feed decreased the pH, water contents, initial viscosity, and the rate at which the viscosity increased with time, while densities and HHVs increased. The addition of Ammosoak to poultry litter also increased the carbon and oxygen contents of the boi-oils while nitrogen, hydrogen, sulfur, chlorine and ash contents decreased. A pilot-scale fluidized bed reactor was designed, constructed, installed and investigated for the pyrolysis of poultry litter. Fluidization and thermal equilibrium of the reactor were successfully demonstrated. The reactor was heated by combustion of propane. To ensure complete combustion, the combustion water was collected and compared to the stoichiometric yield. Complete combustion was achieved. Bio-oil yields on the pilot scale were lower than those obtained on the bench-scale pyrolysis unit. The water soluble fractions of the bio-oils were rich in oxygen. Water insoluble fractions were rich in carbon and ash. / Master of Science

Oil Properties

char

Bio-oil

Fast Pyrolysis

Corncob

Steam Exploded

Litter Amendment

Poultry Litter

13C-nmr spectrometry

FT-IR Spectrophotometry

HIGH THROUGHPUT EXPERIMENTATION AS A GUIDE TO THE CONTINUOUS FLOW SYNTHESIS OF ACTIVE PHARMACEUTICAL INGREDIENTS

Zinia Jaman (6618998)

25 June 2020

<div> <div> <p>Continuous flow chemistry for organic synthesis is an emerging technique in academia and industry because of its exceptional heat and mass transfer ability and, in turn, higher productivity in smaller reactor volumes. Preparative electrospray (ES) is a technique that exploits reactions in charged microdroplets that seeks to accelerate chemical synthesis. In Chapter 2, the flow synthesis of atropine, a drug which is included in the WHO list of essential of medicines and currently in shortage according to the U.S Food and Drug Administration (FDA)is reported.The two steps of atropine synthesis were initially optimized separately and then continuously synthesized using two microfluidic chips under individually optimized condition.The telescoped continuous-flow microfluidics experiment gave a 55% conversion with an average of 34% yield in 8 min residence time. In Chapter 3, a robotic HTE technique to execute reactions in 96-well arrays was coupled with fast MS analysis. Palladium-catalyzed Suzuki-Miyaura (S-M) cross-coupling reactions were screened in this system and a heat map was generated to identify the best reaction condition for downstream scale up in continuous flow. <br></p><p><br></p><p>In Chapter 4, an inexpensive and rapid synthesis of an old anticancer drug, lomustine,was synthesized. Using only four inexpensive commercially available starting materials and a total residence time of 9 min, lomustine was prepared via a linear sequence of two chemical reactions performed separately in two telescoped flow reactors. Sequential offline extraction and filtration resulted in 63% overall yield of pure lomustine at a production rate of 110 mg/h. The primary advantage of this approach lies in the rapid manufacture of lomustine with two telescoped steps to avoid isolation and purification of a labile intermediate, thereby decreasing the production cost significantly. A high throughput reaction screening approach based on desorption electrospray ionization mass spectrometry (DESI-MS) is described in Chapter 4 and 5 for finding the heat-map from a set of reaction conditions. DESI-MS is used to quickly explore a large number of reaction conditions and guide the efficient translation of optimized conditions to continuous flow synthesis that potentially accelerate the process of reaction optimization and discovery. Chapter 5 described HTE ofSNAr reactions using DESI-MS and bulk techniques with 1536 unique reaction conditions explored using both in DESI-MS and bulk reactors. The hotspots from the HTE screening effort were validated using a microfluidic system that confirmed the conditions as true positives or true.<br></p> </div> </div>

Organic Chemistry

Analytical Spectrometry

Flow Analysis

active ingredient

Organic Synthesis

mass spectrometry techniques

NMR spectrometry

Flow Systems