Tik:Research: Difference between revisions

From OpenWetWare
Jump to navigationJump to search
No edit summary
No edit summary
 
(10 intermediate revisions by the same user not shown)
Line 1: Line 1:
{{Tik}}
{{Tik}}


{| cellspacing="3"  
{| cellspacing="3"  
|- valign="top"
|- valign="top"
|width=710px class="MainPageBG" style="background-color: #ffffff"|
|width=670px class="MainPageBG" style="background-color: #ffffff"|
<div style="padding: 1px; color: #ffffff; background-color: #ffffff; width: 710px">
<div style="padding: 1px; color: #ffffff; background-color: #ffffff; width: 670px">
<font face="trebuchet ms" size=3 style="color:#000">'''Research Overview: </font> <br> </div>
<font face="trebuchet ms" size=3 style="color:#000">'''Research Overview: </font> <br> </div>


<div style="clear: right; text-align: left; float: left; width: 710px;">
<div style="clear: right; text-align: left; float: left; width: 670px;">


My research focuses on investigating physiochemical characteristics of biomass that affect their chemical and biological functions. In particular, I am exploring separation of biomass components (i.e., cellulose, hemicellulose and lignin). My diverse background in biology, chemistry, engineering, and economics allows me to formulate green yet efficient and economical processes using a hybrid system of enzymes and heterogeneous catalysts to achieve two goals: (1) energy goal, to produce low value, high volume fuels from renewables, and (2) economic goal, to generate additional revenues from high value, low volume building blocks for specialty chemicals. Here is a bit of my current research in a nutshell.  
My research focuses on investigating physiochemical characteristics of biomass that affect their chemical and biological functions. In particular, I am exploring separation of biomass components (i.e., cellulose, hemicellulose and lignin). My diverse background in biology, chemistry, engineering, and economics allows me to formulate green yet efficient and economical processes using a hybrid system of enzymes and heterogeneous catalysts to achieve two goals: (1) energy goal, to produce low value, high volume fuels from renewables, and (2) economic goal, to generate additional revenues from high value, low volume building blocks for specialty chemicals. Here is a bit of my current research in a nutshell.  
Line 19: Line 18:
{| cellspacing="3"  
{| cellspacing="3"  
|- valign="top"
|- valign="top"
|width=710px class="MainPageBG" style="background-color: #ffffff"|
|width=390px class="MainPageBG" style="background-color: #ffffff"|
<div style="padding: 1px; color: #ffffff; background-color: #ffffff; width: 710px">
<div style="padding: 1px; color: #ffffff; background-color: #ffffff; width: 390px">
<font face="trebuchet ms" size=3 style="color:#000">'''Technological:</font>  <font face="trebuchet ms" size=3 style="color:#00688B">Development of an efficient biomass saccharification process </font> <br> </div>
<font face="trebuchet ms" size=3 style="color:#000">'''Technological:</font>  <font face="trebuchet ms" size=3 style="color:#00688B">Development of an efficient biomass saccharification process </font> <br> </div>


<div style="clear: right; text-align: left; float: left; width: 710px;">
<div style="clear: right; text-align: left; float: left; width: 390px;">


Overcoming lignocellulosic biomass recalcitrance followed by enzymatic hydrolysis of reactive polymeric carbohydrates (i.e., cost-efficient liberation of fermentable sugars from biomass) is perhaps the most challenging technical and economic barrier to biorefinery success.  Pretreatment is among the most costly steps in biochemical conversion of biomass, accounting for up to 40% of the total processing cost.  Also, it affects the costs of other operations including size reduction prior to pretreatment and enzymatic hydrolysis and fermentation after pretreatment.  Pretreatment can also strongly influence downstream costs involving detoxification if inhibitors are generated, enzymatic hydrolysis rate and enzyme loading, mixing power, product concentration, product purification, power generation, waste treatment demands, and other process variables.   
Overcoming lignocellulosic biomass recalcitrance followed by enzymatic hydrolysis of reactive polymeric carbohydrates (i.e., cost-efficient liberation of fermentable sugars from biomass) is perhaps the most challenging technical and economic barrier to biorefinery success.  Pretreatment is among the most costly steps in biochemical conversion of biomass, accounting for up to 40% of the total processing cost.  Also, it affects the costs of other operations including size reduction prior to pretreatment and enzymatic hydrolysis and fermentation after pretreatment.  Pretreatment can also strongly influence downstream costs involving detoxification if inhibitors are generated, enzymatic hydrolysis rate and enzyme loading, mixing power, product concentration, product purification, power generation, waste treatment demands, and other process variables.   
Line 29: Line 28:
</div>  
</div>  


|width=300px class="MainPageBG" style="background-color: #ffffff"|
|width=250px class="MainPageBG" style="background-color: #ffffff"|


[[Image:fig1.jpg|thumb|250x250px|
[[Image:fig1.jpg|thumb|250x250px|
Line 38: Line 37:
{| cellspacing="3"  
{| cellspacing="3"  
|- valign="top"
|- valign="top"
|width=250px class="MainPageBG" style="background-color: #ffffff"|
|width=130px class="MainPageBG" style="background-color: #ffffff"|
<div style="clear: right; text-align: left; float: left; width: 250px;">
<div style="clear: right; text-align: left; float: left; width: 130px;">


[[Image:NMR.jpg|thumb|300x300px|13C NMR spectra of switchgrass and Avicel pre-/post-pretreatment (''Biotechnol Bioeng'' '''108''', 521-529 [2011])]]
[[Image:NMR.jpg|thumb|250x250px|13C NMR spectra of switchgrass and Avicel pre-/post-pretreatment (''Biotechnol Bioeng'' '''108''', 521-529 [2011])]]


|width=730px class="MainPageBG" style="background-color: #ffffff"|
|width=450px class="MainPageBG" style="background-color: #ffffff"|
<div style="padding: 1px; color: #ffffff; background-color: #ffffff; width: 730px">
<div style="padding: 1px; color: #ffffff; background-color: #ffffff; width: 450px">
<font face="trebuchet ms" size=3 style="color:#000">'''Fundamental:</font>  <font face="trebuchet ms" size=3 style="color:#00688B">Physiochemical properties of biomass pre-/post-pretreatment that lend them susceptibility to enzymatic hydrolysis </font> <br> </div>
<font face="trebuchet ms" size=3 style="color:#000">'''Fundamental:</font>  <font face="trebuchet ms" size=3 style="color:#00688B">Physiochemical properties of biomass pre-/post-pretreatment that lend them susceptibility to enzymatic hydrolysis </font> <br> </div>


<div style="clear: right; text-align: left; float: left; width: 710px;">
<div style="clear: right; text-align: left; float: left; width: 450px;">


Biomass are characterized pre-/post-pretreatment by enzymatic hydrolysis,substrate accessibility assay, scanning electron microscopy,X-ray diffraction (XRD), cross polarization/magic angle spinning (CP/MAS) 13C nuclear magnetic resonance(NMR), and Fourier transform infrared spectroscopy (FTIR).
Biomass are characterized pre-/post-pretreatment by enzymatic hydrolysis,substrate accessibility assay, scanning electron microscopy,X-ray diffraction (XRD), cross polarization/magic angle spinning (CP/MAS) 13C nuclear magnetic resonance(NMR), and Fourier transform infrared spectroscopy (FTIR).

Latest revision as of 13:56, 9 February 2011

Home      Research      People      Publications      Curriculum Vitae      News      Contact     


Research Overview:

My research focuses on investigating physiochemical characteristics of biomass that affect their chemical and biological functions. In particular, I am exploring separation of biomass components (i.e., cellulose, hemicellulose and lignin). My diverse background in biology, chemistry, engineering, and economics allows me to formulate green yet efficient and economical processes using a hybrid system of enzymes and heterogeneous catalysts to achieve two goals: (1) energy goal, to produce low value, high volume fuels from renewables, and (2) economic goal, to generate additional revenues from high value, low volume building blocks for specialty chemicals. Here is a bit of my current research in a nutshell.


Technological: Development of an efficient biomass saccharification process

Overcoming lignocellulosic biomass recalcitrance followed by enzymatic hydrolysis of reactive polymeric carbohydrates (i.e., cost-efficient liberation of fermentable sugars from biomass) is perhaps the most challenging technical and economic barrier to biorefinery success. Pretreatment is among the most costly steps in biochemical conversion of biomass, accounting for up to 40% of the total processing cost. Also, it affects the costs of other operations including size reduction prior to pretreatment and enzymatic hydrolysis and fermentation after pretreatment. Pretreatment can also strongly influence downstream costs involving detoxification if inhibitors are generated, enzymatic hydrolysis rate and enzyme loading, mixing power, product concentration, product purification, power generation, waste treatment demands, and other process variables.

Biomass sacchrification strategies (unpublished)
13C NMR spectra of switchgrass and Avicel pre-/post-pretreatment (Biotechnol Bioeng 108, 521-529 [2011])
Fundamental: Physiochemical properties of biomass pre-/post-pretreatment that lend them susceptibility to enzymatic hydrolysis

Biomass are characterized pre-/post-pretreatment by enzymatic hydrolysis,substrate accessibility assay, scanning electron microscopy,X-ray diffraction (XRD), cross polarization/magic angle spinning (CP/MAS) 13C nuclear magnetic resonance(NMR), and Fourier transform infrared spectroscopy (FTIR).

Retrieved from "https://openwetware.org/mediawiki/index.php?title=Tik:Research&oldid=492506"