| Alliman |
Corinne |
Occurrence and distribution of valuable metals in fly ash from
Puertollano IGCC power plant, Spain |
98 |
| Akcaozoglu |
Kubilay |
The Use of a Non-Standard High Calcium Fly Ash in Concrete
and Its Response to Accelerated Curing |
23 |
| Alastuey |
Andrés |
Immobilization of Heavy Metals in Polluted Soils by the Addition
of Zeolitic Material Synthesized from Coal Fly Ash |
28 |
| Alvarez |
Diego |
Multicomponent Utilization of Fly Ash: Dream or Reality |
12 |
| Andrésen |
John M. |
Environmental Benefits of Producing Adsorbent Materials from
Unburned Carbon |
82 |
| Andrésen |
John M. |
Utilization of Unburned Carbon as a Low Sulfur Alternative to
Petroleum Coke |
81 |
| Arenas |
Luis Vilches |
Use of Coal Fly Ash in a Sprayed Mortar for the Passive
Protection Against Fire of Metallic Structures |
56 |
| Arenas |
Luis Vilches |
Production of Plates Based on Coal Fly Ash for Their Use as
Insulating Materials in Doors and Firebreak Wall |
55 |
| Arjunan |
P. Vilches |
Chemical Activation of Low Calcium Fly Ash: Part I: Identification of Most Appropriate Activators and Their Dosage |
105 |
| Arjunan |
P. Vilches |
Chemical Activation of Low Calcium Fly Ash
Part II: Effect of Mineralogical Composition on Alkali Activation |
106 |
| Atis |
Cengiz D. |
The Use of a Non-Standard High Calcium Fly Ash in Concrete
and Its Response to Accelerated Curing |
23 |
| Ayora |
Carles |
Fly Ash Zeolitization Products Applied to Waste Water and Flue
Gas Decontamination |
29 |
| Ayora |
Carles |
Immobilization of Heavy Metals in Polluted Soils by the Addition
of Zeolitic Material Synthesized from Coal Fly Ash |
28 |
| Badoe |
Daniel |
The Effects of Fly Ash and Portland Cement on Long Term
Excavatability of Flowable Fill |
30 |
| Bailey |
Thomas E. |
Long-term Monitoring and Evaluation of Water Quality Changes
from Utilization of Coal-Ash to Fill a Surface Coal Mine |
47 |
| Ban |
Heng |
Fly Ash Ammonia Leaching Characteristics |
95 |
| Barnwell |
William L. |
Ponded Bottom Ash, One Man's Treasure |
89 |
| Barra |
Marilda |
Use of Municipal Waste Incineration Bottom Ash As A Road
Material |
37 |
| Behel |
David |
TVA Research on Coal Combustion By-Products: Uses and
Environmental Impacts |
96 |
| Belkin |
Harvey E. |
Arsenic, Mercury and Other Trace Metals in Coal: Environmental and Health Implications |
103 |
| Bilim |
Cahit |
The Use of a Non-Standard High Calcium Fly Ash in Concrete
and Its Response to Accelerated Curing |
23 |
| Bittner |
James D. |
STI's Six Years of Commercial Experience in Electrostatic
Beneficiation of Fly Ash |
16 |
| Bittner |
J. |
Ammonia in Fly Ash: Consequences for Beneficial Use and a
Method for Removing Ammonia |
15 |
| Borrego |
Angeles G. |
Multicomponent Utilization of Fly Ash: Dream or Reality |
12 |
| Burgos |
Silvia |
Occurrence and distribution of valuable metals in fly ash from
Puertollano IGCC power plant, Spain |
98 |
| Brownfield |
Isabelle K. |
Mode of Occurrence of Arsenic in Feed Coal and its Derivative
Fly Ash, Black Warrior Basin, Alabama |
32 |
| Butalia |
T. |
Short and Long Term Variability of Flue Gas Desulfurization By-Product |
73 |
| Butalia |
Tarunjit S. |
Long-Term Monitoring of a Full-Scale FGD-Lined Pond Facility |
74 |
| Butalia |
Tarunjit S. |
Utilization of Ohio Coal Combustion Products |
75 |
| Butalia |
T.S. |
The Effect of Ettringite Formation on The Expansion Properties
of a Compacted Spray Dryer Ash Fill |
76 |
| Butalia |
T.S. |
Swell Potential in Fluidized Bed Combustion Ash |
78 |
| Cablik |
V. |
Possibility of Recovery Al and Ti in Fly Ashes from the
Opatovice power plant |
1 |
| Camacho |
Lucy Mar |
Combined Statistical Model for the Leaching of Heavy Metals
from Fly Ash Solidified/Stabilized Wastes |
86 |
| Chandra |
Satish |
Influence of Combustion Conditions on the Properties of Fly
ash- A Review |
24 |
| Chen |
Xu |
Ozonation for the Chemical Modification of Carbon Surfaces in
Fly Ash |
58 |
| Chen |
Liming |
Flue Gas Desulfurization By-products as Lime and Sulfur
Sources for Alfalfa and Soybean |
31 |
| Chimenos |
José M. |
Occurrence and distribution of valuable metals in fly ash from
Puertollano IGCC power plant, Spain |
98 |
| Cloke |
Mike |
The Removal of Carbon from Fly Ash using Supercritical Water
Oxidation |
85 |
| Copeland |
Audrey |
The Effects of Fly Ash and Portland Cement on Long Term
Excavatability of Flowable Fill |
30 |
| Crouch |
L.K. |
The Effects of Fly Ash and Portland Cement on Long Term
Excavatability of Flowable Fill |
30 |
| Dejaiffe |
Robert |
Production of Recycled Products from Coal Ash Using a Plasma Enhanced Melter™ |
101 |
| Deutsch |
Yoetz |
Time-related Changes in Coal Ash in Two Embankments and a
Roadbase |
83 |
| Dick |
Warren A. |
Flue Gas Desulfurization By-products as Lime and Sulfur
Sources for Alfalfa and Soybean |
31 |
| Dobbs |
Dennis D. |
A Utility Perspective: Subsidized Projects - How Much Should
You Pay? |
11 |
| Dotson |
Jamey |
The Effects of Fly Ash and Portland Cement on Long Term
Excavatability of Flowable Fill |
30 |
| Dudka |
S. |
Utilization of Coal Combustion By-products (CCBP) in Horticultural and Turfgrass Industries: Technical and Environmental Feasibility Studies |
99 |
| Ellis |
Stephen |
Trace Elements in Flyash by rf-Source Glow Discharge Mass
Spectrometry |
17 |
| Espiell |
Ferran |
Occurrence and distribution of valuable metals in fly ash from
Puertollano IGCC power plant, Spain |
98 |
| Farber |
Mark |
Ozonation for the Chemical Modification of Carbon Surfaces in
Fly Ash |
58 |
| Fecko |
Peter |
Possibility of Recovery Al and Ti in Fly Ashes from the
Opatovice power plant |
1 |
| Fernández-Pereira |
Constantino |
Fly Ash Zeolitization Products Applied to Waste Water and Flue
Gas Decontamination |
29 |
| Ferret |
L.S. |
Conversion of Coal Fly Ash into Soil Conditoner by Alkaline Hydrothermal Treatment |
88 |
| Finkelman |
Robert B. |
Arsenic, Mercury and Other Trace Metals in Coal: Environmental and Health Implications |
103 |
| Font |
Oriol |
Occurrence and distribution of valuable metals in fly ash from
Puertollano IGCC power plant, Spain |
98 |
| Flanagan |
D.C. |
Use of Calcium-Containing Coal Combustion Products and
Organic Matter to Reduce Soil Erosion |
63 |
| Foster |
Andrea L. |
Mode of Occurrence of Arsenic in Feed Coal and its Derivative
Fly Ash, Black Warrior Basin, Alabama |
32 |
| Gao |
Yuming |
Mechanisms of Ammonia Adsorption and Desorption Relevant
to Fly Ash Utilization |
59 |
| Gao |
Yuming |
Ozonation for the Chemical Modification of Carbon Surfaces in
Fly Ash |
58 |
| García-Sánchez |
Antonio |
Immobilization of Heavy Metals in Polluted Soils by the Addition
of Zeolitic Material Synthesized from Coal Fly Ash |
28 |
| Gasiorowski |
S. |
Ammonia in Fly Ash: Consequences for Beneficial Use and a
Method for Removing Ammonia |
15 |
| Gasiorowski |
Stephen A. |
STI's Six Years of Commercial Experience in Electrostatic
Beneficiation of Fly Ash |
16 |
| Gayer |
Rod |
Characterization of fly ash from the Kangal power plant, Eastern
Turkey |
4 |
| Giannakou |
Aikaterini |
Properties of Structural-Grade Foamed Concrete Using Low-Lime Fly Ash as a Cement and Filler |
68 |
| Golightly |
D.W. |
Short and Long Term Variability of Flue Gas Desulfurization By-Product |
73 |
| Groppo |
Jack |
Energy to Ashes: The Coleman Power Plant Project |
104 |
| Gurnari |
Larry |
Ozonation for the Chemical Modification of Carbon Surfaces in
Fly Ash |
58 |
| Gurupira |
Tapiwa |
New Products from Coal Combustion Ash: Selective Extraction
of Particles with Density < 2 |
44 |
| Hamley |
Paul |
The Removal of Carbon from Fly Ash using Supercritical Water
Oxidation |
85 |
| Hassett |
David J. |
Release of Mercury Vapor from Coal Combustion Ash |
65 |
| Hassett |
David J. |
Coal Fly Ash Trace Element Mobility in Soil Stabilization |
64 |
| Hassett |
David |
Developing Beneficial Use Rules for Coal Combustion Products
(CCPs) |
67 |
| Heebink |
Loreal V. |
Release of Mercury Vapor from Coal Combustion Ash |
65 |
| Heebink |
Loreal V. |
Coal Fly Ash Trace Element Mobility in Soil Stabilization |
64 |
| Hernández |
Susana |
Fly Ash Zeolitization Products Applied to Waste Water and Flue
Gas Decontamination |
29 |
| Howard |
Allen |
New Products from Coal Combustion Ash: Selective Extraction
of Particles with Density < 2 |
44 |
| Hower |
James C. |
Studies of Mercury Capture on Fly Ash: Examples from Power
Plants Burning Kentucky Coals |
10 |
| Hrach |
F. |
Ammonia in Fly Ash: Consequences for Beneficial Use and a
Method for Removing Ammonia |
15 |
| Huffman |
G.P. |
Investigation of Cement and Fly Ash samples by X-ray
Absorption Fine Structure (XAFS) Spectroscopy and X-ray
Diffraction |
87 |
| Hurt |
Robert |
Mechanisms of Ammonia Adsorption and Desorption Relevant
to Fly Ash Utilization |
59 |
| Hurt |
Robert |
Ozonation for the Chemical Modification of Carbon Surfaces in
Fly Ash |
58 |
| Izquierdo |
Maria |
Use of Municipal Waste Incineration Bottom Ash As A Road
Material |
37 |
| Jacobs |
LeRoy |
Trace Elements in Flyash by rf-Source Glow Discharge Mass
Spectrometry |
17 |
| Janssen |
Maria |
Fly Ash Zeolitization Products Applied to Waste Water and Flue
Gas Decontamination |
29 |
| Jiang |
Kelvin X. |
The Influence of Ash Particle Interactions During Pneumatic
Transport, Triboelectric Beneficiation |
38 |
| Jones |
Akhnuwkh |
Environmental Benefits of Producing Adsorbent Materials from
Unburned Carbon |
82 |
| Jones |
Charles L. |
New Products from Coal Combustion Ash: Selective Extraction
of Particles with Density < 2 |
44 |
| Jones |
Roderick |
Properties of Structural-Grade Foamed Concrete Using Low-Lime Fly Ash as a Cement and Filler |
68 |
| Juan |
Roberto |
Fly Ash Zeolitization Products Applied to Waste Water and Flue
Gas Decontamination |
29 |
| Kaczmarek |
Michael E. |
High Volume Fly Ash Flowable Fill |
70 |
| Kania |
Timothy |
The Use of FBC Coal Combustion Ash for Alkaline Addition at
Two Surface Coal Mine Sites in Pennsylvania, Success and
Failure |
49 |
| Karayigit |
Ali Ihsan |
Characterization of fly ash from the Kangal power plant, Eastern
Turkey |
4 |
| Kashi |
Mohsen G. |
High Volume Fly Ash Flowable Fill |
70 |
| Kazonich |
George |
Coal Combustion By-products: Major Cation Solubility |
40 |
| Keppeler |
James G. |
Carbon Burn-Out, an Update on Commercial Applications |
61 |
| Kim |
Ann G. |
Coal Combustion By-products: Major Cation Solubility |
40 |
| Kimlinger |
Joseph P. |
A Utility Perspective: Subsidized Projects - How Much Should
You Pay? |
11 |
| Kokmeijer |
Esther |
Field Leaching of Bricks and Concrete Containing Coal Fly Ash |
97 |
| Kolker |
Allan |
Arsenic, Mercury and Other Trace Metals in Coal: Environmental and Health Implications |
103 |
| Kruger |
Richard A. |
The Manufacture and Use of a Soil Ameliorant Based on Fly
Ash and Sewage Sludge |
80 |
| Kusnierova |
M. |
Possibility of Recovery Al and Ti in Fly Ashes from the
Opatovice power plant |
1 |
| LaBuz |
Lawrence |
Utilizing On-Line Carbon-In-Ash Analysis with Selective Hopper
Evacuation to Improve Salable Ash Yield |
42 |
| Lamminen |
M. |
Mine Three Years After Placement of Flue Gas Desulfurization
By-Product |
54 |
| Lee |
R. J. |
Swell Potential in Fluidized Bed Combustion Ash |
78 |
| Lee |
R.J. |
Investigation of Cement and Fly Ash samples by X-ray
Absorption Fine Structure (XAFS) Spectroscopy and X-ray
Diffraction |
87 |
| Lee |
R. J. |
The Effect of Ettringite Formation on The Expansion Properties
of a Compacted Spray Dryer Ash Fill |
76 |
| Leiva |
Carlos |
Use of Coal Fly Ash in a Sprayed Mortar for the Passive
Protection Against Fire of Metallic Structures |
56 |
| Lester |
Ed |
The Removal of Carbon from Fly Ash using Supercritical Water
Oxidation |
85 |
| Lister |
Robert |
Commercialization Status of a Pneumatic Transport,
Triboelectrostatic System for Carbon/Ash Separation |
46 |
| Lockert |
Cal |
New Products from Coal Combustion Ash: Selective Extraction
of Particles with Density < 2 |
44 |
| Lockert |
Charles A. |
Commercialization Status of a Pneumatic Transport,
Triboelectrostatic System for Carbon/Ash Separation |
46 |
| Lockert, |
Charles A. |
Utilizing On-Line Carbon-In-Ash Analysis with Selective Hopper
Evacuation to Improve Salable Ash Yield |
42 |
| López-Soler |
Ángel |
Use of Municipal Waste Incineration Bottom Ash As A Road
Material |
37 |
| López-Soler |
Angel, |
Occurrence and distribution of valuable metals in fly ash from
Puertollano IGCC power plant, Spain |
98 |
| Lu |
Zhe |
Environmental Benefits of Producing Adsorbent Materials from
Unburned Carbon |
82 |
| MacLean |
James H. J |
Microwave Carbon Burnout (MCB) Gas Byproducts and Deportment of Specific Metallic Elements |
107 |
| McCarthy |
Michael J |
Stockpile and Pond Stored Fly Ash for Use in Structural
Concrete |
69 |
| McGee |
Stuart Munson |
Combined Statistical Model for the Leaching of Heavy Metals
from Fly Ash Solidified/Stabilized Wastes |
86 |
| McGlincy, |
Dorothy A. |
High Volume Fly Ash Flowable Fill |
70 |
| March |
María J. |
Occurrence and distribution of valuable metals in fly ash from
Puertollano IGCC power plant, Spain |
98 |
| Maroto-Valer |
M. Mercedes |
Utilization of Unburned Carbon as a Low Sulfur Alternative to
Petroleum Coke |
81 |
| Maroto-Valer |
M. Mercedes |
Studies of Mercury Capture on Fly Ash: Examples from Power
Plants Burning Kentucky Coals |
10 |
| Maroto-Valer |
M. Mercedes |
Environmental Benefits of Producing Adsorbent Materials from
Unburned Carbon |
82 |
| Meeker |
Gregory P. |
Mode of Occurrence of Arsenic in Feed Coal and its Derivative
Fly Ash, Black Warrior Basin, Alabama |
32 |
| Mehta |
Arun |
Ozonation for the Chemical Modification of Carbon Surfaces in
Fly Ash |
58 |
| Mehta |
Arun |
Mechanisms of Ammonia Adsorption and Desorption Relevant
to Fly Ash Utilization |
59 |
| Meij |
Ruud |
Health aspects of coal fly ash |
21 |
| Meij |
Ruud |
Field Leaching of Bricks and Concrete Containing Coal Fly Ash |
97 |
| Menendez |
Rosa |
Multicomponent Utilization of Fly Ash: Dream or Reality |
12 |
| Miller |
E. Cheri |
Radon Emissions from a High Volume Coal Fly Ash Structural
Fill Site |
91 |
| Miller |
W.P. |
Utilization of Coal Combustion By-products (CCBP) in Horticultural and Turfgrass Industries: Technical and Environmental Feasibility Studies |
99 |
| Minkara |
Rafic Y. |
Chemical Treatment of Ammoniated Ash |
102 |
| Moreno |
Natalia |
Determination of the Available Si and Al from Coal Fly Ashes
under Alkaline Conditions with the Aim of Synthesising Zeolite
Products |
71 |
| Moreno |
Natàlia |
Immobilization of Heavy Metals in Polluted Soils by the Addition
of Zeolitic Material Synthesized from Coal Fly Ash |
28 |
| Moreno |
Nàtalia |
Fly Ash Zeolitization Products Applied to Waste Water and Flue
Gas Decontamination |
29 |
| Murarka |
Ishwar P. |
Long-term Monitoring and Evaluation of Water Quality Changes
from Utilization of Coal-Ash to Fill a Surface Coal Mine |
47 |
| Mymrin |
Vsevolod A. |
Soils Strengthening by Fly and Bottom Ash for Road Base
Construction |
9 |
| Nathan |
Yaacov |
Time-related Changes in Coal Ash in Two Embankments and a
Roadbase |
83 |
| Nelson |
Sid, Jr. |
Flue Gas Desulfurization By-products as Lime and Sulfur
Sources for Alfalfa and Soybean |
31 |
| Nicol |
Lorne |
Properties of Structural-Grade Foamed Concrete Using Low-Lime Fly Ash as a Cement and Filler |
68 |
| Nugteren |
Henk W. |
Determination of the Available Si and Al from Coal Fly Ashes
under Alkaline Conditions with the Aim of Synthesising Zeolite
Products |
71 |
| Olivares del
Valle |
Joaquín |
Use of Coal Fly Ash in a Sprayed Mortar for the Passive
Protection Against Fire of Metallic Structures |
56 |
| Olivares del
Valle |
Joaquín |
Production of Plates Based on Coal Fly Ash for Their Use as
Insulating Materials in Doors and Firebreak Wall |
55 |
| Palmer |
Curtis A. |
Arsenic, Mercury and Other Trace Metals in Coal: Environmental and Health Implications |
103 |
| Parapar |
José Vale |
Production of Plates Based on Coal Fly Ash for Their Use as
Insulating Materials in Doors and Firebreak Wall |
55 |
| Parapar |
José Vale |
Use of Coal Fly Ash in a Sprayed Mortar for the Passive
Protection Against Fire of Metallic Structures |
56 |
| Pattanaik |
S. |
Investigation of Cement and Fly Ash samples by X-ray
Absorption Fine Structure (XAFS) Spectroscopy and X-ray
Diffraction |
87 |
| Peña |
Francisco
García |
Occurrence and distribution of valuable metals in fly ash from
Puertollano IGCC power plant, Spain |
98 |
| Pereira |
Constantino
Fernández |
Use of Coal Fly Ash in a Sprayed Mortar for the Passive
Protection Against Fire of Metallic Structures |
56 |
| Pereira |
Constantino
Fernández |
Production of Plates Based on Coal Fly Ash for Their Use as
Insulating Materials in Doors and Firebreak Wall |
55 |
| Peterson |
J.R. |
Use of Calcium-Containing Coal Combustion Products and
Organic Matter to Reduce Soil Erosion |
63 |
| Petzrick |
Paul A. |
The Use of Power Plant Combustion Products in Maryland |
51 |
| Pflughoeft-Hassett |
Debra |
Developing Beneficial Use Rules for Coal Combustion Products
(CCPs) |
67 |
| Pietraszkiewicz |
W. |
Fly Ash as Carrier of Catalysts in the Claus Process |
| Pimraksa |
Kedsarin |
A New Approach to the Production of Bricks Made of 100% Fly
Ash |
84 |
| Plana |
Felicià |
Use of Municipal Waste Incineration Bottom Ash As A Road
Material |
37 |
| Plana |
Felicià |
Occurrence and distribution of valuable metals in fly ash from
Puertollano IGCC power plant, Spain |
98 |
| Poliakoff |
Martyn |
The Removal of Carbon from Fly Ash using Supercritical Water
Oxidation |
85 |
| Poston |
Randall W. |
The Behavior of Coal Combustion Products in Structural Fills - A
Case History |
77 |
| Quapp |
William J. |
Production of Recycled Products from Coal Ash Using a Plasma Enhanced Melter™ |
101 |
| Querol |
Xavier |
Fly Ash Zeolitization Products Applied to Waste Water and Flue
Gas Decontamination |
29 |
| Querol |
Xavier |
Use of Municipal Waste Incineration Bottom Ash As A Road
Material |
37 |
| Querol |
Xavier |
Determination of the Available Si and Al from Coal Fly Ashes
under Alkaline Conditions with the Aim of Synthesising Zeolite
Products |
71 |
| Querol |
Xavier |
Immobilization of Heavy Metals in Polluted Soils by the Addition
of Zeolitic Material Synthesized from Coal Fly Ash |
28 |
| Querol |
Xavier |
Occurrence and distribution of valuable metals in fly ash from
Puertollano IGCC power plant, Spain |
98 |
| Rathbone |
Robert F. |
Rates of Ammonia Loss from Mortar and Concrete |
72 |
| Rathbone |
Robert F. |
Thermal Characteristics of Ammonia Release from Combustion
Ash |
39 |
| Rethman |
Norman F.G. |
The Manufacture and Use of a Soil Ameliorant Based on Fly
Ash and Sewage Sludge |
80 |
| Reynolds |
Kelley A. |
The Manufacture and Use of a Soil Ameliorant Based on Fly
Ash and Sewage Sludge |
80 |
| Ridley |
W. Ian |
Mode of Occurrence of Arsenic in Feed Coal and its Derivative
Fly Ash, Black Warrior Basin, Alabama |
32 |
| Robl |
Thomas L. |
Research in Ammonia Diffusivity in Portland Cement Based Mixes |
100 |
| Robl |
Thomas L. |
Rates of Ammonia Loss from Mortar and Concrete |
72 |
| Robl |
Thomas L. |
Ashes to Energy: The Coleman Plant Project |
104 |
| Rodríguez-Piñero |
Miguel |
Production of Plates Based on Coal Fly Ash for Their Use as
Insulating Materials in Doors and Firebreak Wall |
55 |
| Roy |
D.M. |
Chemical Activation of Low Calcium Fly Ash: Part I: Identification of Most Appropriate Activators and Their Dosage |
105 |
| Roy |
D.M> |
Chemical Activation of Low Calcium Fly Ash
Part II: Effect of Mineralogical Composition on Alkali Activation |
106 |
| Rubel |
Aurora M. |
Thermal Characteristics of Ammonia Release from Combustion
Ash |
39 |
| Sahu |
B.K. |
Improvement in California Bearing Ratio of Various Soils in Botswana by Fly Ash |
90 |
| Sahu |
S. |
Investigation of Cement and Fly Ash samples by X-ray
Absorption Fine Structure (XAFS) Spectroscopy and X-ray
Diffraction |
87 |
| Sakulpitakphon |
Tanaporn |
Studies of Mercury Capture on Fly Ash: Examples from Power
Plants Burning Kentucky Coals |
10 |
| Sauter |
Heather J. |
The Effects of Fly Ash and Portland Cement on Long Term
Excavatability of Flowable Fill |
30 |
| Schlossberg |
M.J. |
Utilization of Coal Combustion By-products (CCBP) in Horticultural and Turfgrass Industries: Technical and Environmental Feasibility Studies |
99 |
| Schobert |
Harold H. |
Environmental Benefits of Producing Adsorbent Materials from
Unburned Carbon |
82 |
| Schueck |
Joseph |
The Use of FBC Coal Combustion Ash for Alkaline Addition at
Two Surface Coal Mine Sites in Pennsylvania, Success and
Failure |
49 |
| Sebastia |
Eva |
Determination of the Available Si and Al from Coal Fly Ashes
under Alkaline Conditions with the Aim of Synthesising Zeolite
Products |
71 |
| Serci |
A. |
Heavy Metal Immobilization by Fly Ash in the Soils
Contaminated by Mine Activity |
6 |
| Sevim |
Umur K. |
The Use of a Non-Standard High Calcium Fly Ash in Concrete
and Its Response to Accelerated Curing |
23 |
| Silsbee |
M.R. |
Chemical Activation of Low Calcium Fly Ash: Part I: Identification of Most Appropriate Activators and Their Dosage |
105 |
| Silsbee |
M.R. |
Chemical Activation of Low Calcium Fly Ash
Part II: Effect of Mineralogical Composition on Alkali Activation |
106 |
| Schmaltz |
Thomas |
Radon Emissions from a High Volume Coal Fly Ash Structural
Fill Site |
91 |
| Soler |
Angel López |
Immobilization of Heavy Metals in Polluted Soils by the Addition
of Zeolitic Material Synthesized from Coal Fly Ash |
28 |
| Steenari |
Britt-Marie |
Influence of Combustion Conditions on the Properties of Fly
ash- A Review |
24 |
| Stencel |
John |
The Influence of Ash Particle Interactions During Pneumatic
Transport, Triboelectric Beneficiation |
38 |
| Stencel |
John M. |
Thermal Characteristics of Ammonia Release from Combustion
Ash |
39 |
| Stencel |
John M. |
The Influence of Ash Particle Interactions During Pneumatic
Transport, Triboelectric Beneficiation |
38 |
| Stencel |
John M. |
Commercialization Status of a Pneumatic Transport,
Triboelectrostatic System for Carbon/Ash Separation |
46 |
| Stencel |
John M. |
New Products from Coal Combustion Ash: Selective Extraction
of Particles with Density < 2 |
44 |
| Sumner |
M.E. |
Utilization of Coal Combustion By-products (CCBP) in Horticultural and Turfgrass Industries: Technical and Environmental Feasibility Studies |
99 |
| Sun |
P. |
Short and Long Term Variability of Flue Gas Desulfurization By-Product |
73 |
| Surma |
Jeffrey E. |
Production of Recycled Products from Coal Ash Using a Plasma Enhanced Melter™ |
101 |
| Sutton |
Michael E. |
Radon Emissions from a High Volume Coal Fly Ash Structural
Fill Site |
91 |
| Suuberg |
Eric |
Mechanisms of Ammonia Adsorption and Desorption Relevant
to Fly Ash Utilization |
59 |
| Suuberg |
Eric |
Ozonation for the Chemical Modification of Carbon Surfaces in
Fly Ash |
58 |
| Sweet |
Palmer C. |
Use of Coal Combustion Products in Virginia |
14 |
| Taerakul |
P. |
Short and Long Term Variability of Flue Gas Desulfurization By-Product |
73 |
| Taerakul |
P. |
Mine Three Years After Placement of Flue Gas Desulfurization
By-Product |
54 |
| Tamboer |
Leendert |
Field Leaching of Bricks and Concrete Containing Coal Fly Ash |
97 |
| Tapp |
Kenny |
Ponded Bottom Ash, One Man's Treasure |
89 |
| Tarantino |
Joseph |
The Use of FBC Coal Combustion Ash for Alkaline Addition at
Two Surface Coal Mine Sites in Pennsylvania, Success and
Failure |
49 |
| Taulbee |
Darrell N. |
Studies of Mercury Capture on Fly Ash: Examples from Power
Plants Burning Kentucky Coals |
10 |
| Thomas |
Jane |
Trace Elements in Flyash by rf-Source Glow Discharge Mass
Spectrometry |
17 |
| Thompson |
Alan |
The Removal of Carbon from Fly Ash using Supercritical Water
Oxidation |
85 |
| Tishmack |
J.K. |
Use of Calcium-Containing Coal Combustion Products and
Organic Matter to Reduce Soil Erosion |
63 |
| Tittle |
Paul A J |
Stockpile and Pond Stored Fly Ash for Use in Structural
Concrete |
69 |
| Topping |
Gerald |
High Volume Fly Ash Flowable Fill |
70 |
| Tranquilla |
J.M. |
Microwave Carbon Burnout (MCB) Gas Byproducts and Deportment of Specific Metallic Elements |
107 |
| Truter |
Wayne F. |
The Manufacture and Use of a Soil Ameliorant Based on Fly
Ash and Sewage Sludge |
80 |
| Tütünlü |
Fatih |
Utilization of Fly Ash in Manufacturing of Building Bricks |
13 |
| Tyra |
Mark A. |
Rates of Ammonia Loss from Mortar and Concrete |
72 |
| Tyra |
Mark A. |
Research in Ammonia Diffusivity in Portland Cement Based Mixes |
100 |
| Umaña |
Juan C. |
Fly Ash Zeolitization Products Applied to Waste Water and Flue
Gas Decontamination |
29 |
| Vassilev |
Stanislav V. |
Multicomponent Utilization of Fly Ash: Dream or Reality |
12 |
| Vazquez |
Enric |
Use of Municipal Waste Incineration Bottom Ash As A Road
Material |
37 |
| Vilela |
A.C.F. |
Conversion of Coal Fly Ash into Soil Conditioner by Alkaline Hydrothermal Treatment |
88 |
| Vories |
Kimery C. |
The Office of Surface Mining Initiatives Related to
Coal Combustion By-products (CCBs) |
5 |
| Walker |
Todd |
The Effects of Fly Ash and Portland Cement on Long Term
Excavatability of Flowable Fill |
30 |
| Walker |
H.W. |
Mine Three Years After Placement of Flue Gas Desulfurization
By-Product |
54 |
| Walker |
H.W. |
Short and Long Term Variability of Flue Gas Desulfurization By-Product |
73 |
| Wandell |
Tracy |
New Products from Coal Combustion Ash: Selective Extraction
of Particles with Density < 2 |
44 |
| Weavers |
L.K. |
Short and Long Term Variability of Flue Gas Desulfurization By-Product |
73 |
| Whitlatch |
E. |
Mine Three Years After Placement of Flue Gas Desulfurization
By-Product |
54 |
| Wieckowska |
J. |
Fly Ash as Carrier of Catalysts in the Claus Process |
43 |
| Wilhelm |
Matthias |
A New Approach to the Production of Bricks Made of 100% Fly
Ash |
84 |
| Wilson |
Charles |
Trace Elements in Flyash by rf-Source Glow Discharge Mass
Spectrometry |
17 |
| Winkel |
Henk te |
Field Leaching of Bricks and Concrete Containing Coal Fly Ash |
97 |
| Winkel |
Henk te |
Health aspects of coal fly ash |
21 |
| Wolfe |
William E. |
Long-Term Monitoring of a Full-Scale FGD-Lined Pond Facility |
74 |
| Wolfe |
William E. |
Utilization of Ohio Coal Combustion Products |
75 |
| Wolfe |
W. E. |
Swell Potential in Fluidized Bed Combustion Ash |
78 |
| Wolfe< |