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Swapsol ushers in solution to clean up landfill gas?

Friday, November 13th, 2009

Laboratory studies show the SWAP drives a Sulfur Cycle which enables the user to generate H2S from most hydrocarbon wastes.  This of course is important because the SWAP uses H2S to convert CO2 into harmless compounds.

Landfill Methane flare

Landfill Methane flare

Landfills in particular, may benefit from the SWAP as they emit Methane.  These landfills can also become a source for raw materials.

The SWAP, which converts CO2 by rearranging its atomic components, may be used to create carbon-sulfur molecules called Carsuls, which may find application as carbon fiber-like materials in construction, aerospace, manufacturing and electronics.

It could very well be that as the SWAP is more widely adopted in areas such as waste management, sour gas and crude oil refining, among others, that we may begin to see the dawn of a new energy economy as we usher in a new era of literally profiting through environmental stewardship.

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How to reduce global warming and improve the bottom line

Tuesday, November 10th, 2009

What does that mean?  That means Ray Stenger and Jim Wasas turned heads recently by announcing they have discovered how to convert CO2 and H2S, two “bad actors,” into harmless compounds in a self-sustaining process.

“The SWAP is a process that can eliminate CO2 by recycling waste, produce a negative carbon footprint and improve the bottom line…” was the message executives at the Houston Global Refining Strategies Summit (www.refiningna.com) heard for three days.

“SWAPSOL earned the biggest buzz I’ve ever seen at one of our shows,” said John Mackenzie, business development manager for World Trade Group, a leader in event production for the energy sector. “From Big Blue on down, it appeared company executives had to get in line to speak with these gentlemen about the science.”

The Stenger-Wasas Process (SWAP) www.swapsol.com is not about capturing and storing CO2 underground (CCS).  The SWAP converts and breaks CO2 into its parts – parts that can be cycled back into the reaction to convert more CO2.

Wolf Koch, Swapsol Director; Jim Wasas and Ray Stenger

Wolf Koch, Swapsol Director; Jim Wasas and Ray Stenger

Federal legislation to force lower emissions in the oil and gas sector and increase taxes for those who do emit CO2 has industry executives deeply concerned.  They say it’s a fundamental question of survival with some gas leaders saying thousands of jobs will be lost.  Executives at SWAPSOL said they were thankful to be part of the discussion moving forward.

“Congress setting tough rules on carbon emissions in some way is inevitable,” said Evan Howell, SWAPSOL Corp. executive vice president for marketing and communications.  “As we build our company around the science, we’re talking with potential partners to develop what we see are a wide variety of commercial applications both in and outside the petroleum industry.”

Keynote speakers in Houston called for the industry to take a greater role in shaping legislation and make a greater commitment to investing in new and innovative technologies.

SWAPSOL is scheduled to present at the Global Refining Strategies Summit May 18-19, 2010, in Rotterdam where they will present the SWAP to industry executives from Europe, China and the Middle East.

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DISCOVERY TO REDUCE HUMAN IMPACT ON GLOBAL WARMING

Monday, October 26th, 2009

CO2 conversion eliminates industry liability opens door to new energy economy

HOUSTON (Oct. 28, 2009) – Two New Jersey scientists have discovered a simple chemical process to break down carbon dioxide (CO2) and eliminate nuisance pollutants, such as hydrogen sulfide (H2S) in refining operations. Their discovery could redefine how science looks at energy. SWAPSOL Corp. will present to industry on Oct. 28, “Carbon Focus Day,” at the Global Refining Strategies Summit in Houston.

The invention changes preconceived notions about energy and chemistry. Raymond Stenger, environmental engineer, and James Wasas, an entrepreneurial chemist, developed the Stenger-Wasas Process (SWAP) based on a previously unknown exothermic interaction between H2S and CO2 that eliminates both. The SWAP is independently verified by standard analytical instruments to convert CO2 by more than 99 percent into carbon-sulfur polymers (Carsuls), water and sulfur in the presence of H2S over an abundant and inexpensive catalyst. The SWAP can also recycle waste hydrocarbons (compounds containing carbon and hydrogen) and break down CO2 in a self-sustaining cycle.

“We are building our company around the chemistry,” said Wolf Koch, Ph.D., Director of SWAPSOL Corp. “We are now detailing processes under which we will review potential business relationships with interested parties with intent to launch initial steps next year.”

Thermodynamic and chemical kinetics studies indicate that the SWAP is exothermic, and the heat liberated can be managed and controlled. Independently conducted gas chromatography studies (GC) verified H2S reduction to below 4 ppb.

Eliminating carbon liabilities for industry

By eliminating greenhouse gases, refiners and other carbon-emitters may profit by not polluting and by avoiding carbon penalties. Wasas, SWAPSOL’s chief science officer, predicts the SWAP could also earn carbon credits for those who implement the technology.

Hydrogen sulfide is the oil and gas industry’s enemy No. 1,” Wasas said. “Tremendous money and energy is required to get rid of H2S, and traditional methods create more hazardous waste, increasing costs and further polluting the environment.”

Hydrogen production, landfill waste potential

The SWAP can be used to purify gas inside landfills prior to combustion, thereby eliminating the harmful release of pollutants into the air. The SWAP-driven sulfur cycle also allows for related reactions that can produce hydrogen from hydrogen sulfide. For refiners this may be a cost-effective solution to recover hydrogen while it may find other applications for fuel cells.

“I can’t tell you how proud we are of the work Jim and I have been able to accomplish,” said Stenger, SWAPSOL’s president. “To be able to make a contribution like this to the world is something I’ve dreamed about for years.”

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SWAPSOL TO ANNOUNCE BREAKTHROUGH DURING NATIONAL CHEMISTRY WEEK

Monday, October 5th, 2009

Chemical reaction verified to convert carbon dioxide (CO2) and hydrogen sulfide (H2S) to form harmless compounds, contribute to climate change fight

MONMOUTH JUNCTION, N.J. (October 5, 2009) – Two New Jersey scientists at SWAPSOL Corp. (www.swapsol.com ) have discovered a chemical process that reacts hydrogen sulfide (H2S) with carbon dioxide (CO2), eliminating both. SWAPSOL will hold a seminar on the science and potential industrial applications during National Chemistry Week on Oct. 21, 2009, on the Rutgers University Cook Campus in New Brunswick, N.J. http://www.swapsol.com/events

The discovery may shatter preconceived notions about energy and chemistry and play a role in the fight against climate change and global warming.  Unlike a carbon capture process, the Stenger-Wasas Process or SWAP is a carbon conversion process, verified in the laboratory to break down CO2 into its inert compounds.

Ray Stenger and Jim Wasas discovered the SWAP, a suite of hydrocarbon reactions based on the previously unknown reaction between CO2 and H2S. The SWAP was verified in the laboratory to reduce H2S below detectable levels (below 4 ppb) by gas chromatography while converting proportionate amounts of CO2 into innocuous compounds such as water.  Sour gas processors and high-sulfur crude oil refiners may be the first to benefit from the SWAP which could substantially reduce operating costs and mitigate CO2 emissions.  The SWAP may also have potential applications in other sectors where H2S is present, such as landfills, tanneries and coke ovens.

Thermodynamic and chemical kinetics studies indicate that the SWAP is exothermic and the heat liberated can be easily managed and controlled.

The quantitative thermodynamic and kinetic information was verified by an independent firm, which also determined the kinetic and thermodynamic parameters of the process.

Gas chromatography (GC) was independently conducted by Gene Hall, Ph.D., professor of analytical chemistry at Rutgers University.  He found the SWAP reaction reduced H2S to below 4 ppb.

“My GC studies demonstrated the SWAP has strong potential for dramatic H2S reduction,” said Hall, adding the SWAP discovery was extremely important. “It appears they may have something very special indeed.”

To learn more about the seminar and the SWAP, visit www.swapsol.com/events

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SWAPSOL Corp. Names Wolf Koch, Robert Cohen to Board of Directors

Monday, September 21st, 2009

New additions to bring chemical, financial expertise to N.J.-based R&D Firm

MONMOUTH JUNCTION, N.J. (Sept. 17, 2009) – Wolf Koch, Ph.D., founder and president of Technology International Resources, Inc. (Sterling, Ill.) and Robert Cohen, Managing Partner of Benson Oak Capital (Prague, CZ) have recently been named to the New Jersey-based SWAPSOL Corp (www.swapsol.com) board of directors.

“We couldn’t be more proud to add Wolf and Robert to the SWAPSOL family,” said Raymond Stenger, president of SWAPSOL Corp. “Together, their engineering and business savvy are enormous assets to our company as we move forward.”

Dr. Wolf Koch

Dr. Wolf Koch

Koch will consult with the board on scientific and technology verification surrounding the Stenger-Wasas Process (SWAP) and advise on licensing negotiations with the commercial sector.  Cohen will lead financing negotiations and help develop strategic partnerships with industry.

Koch has managed technology development programs for more than three decades, including petrochemical and petroleum processing technology development for Amoco Oil.  He is the inventor or co-inventor on 26 patents and has authored more than 40 publications, covering topics in biomedical engineering, catalysis, environmental engineering and intellectual property.  He holds a Ph.D. and bachelor’s degree in chemical engineering and a master’s degree in biomedical engineering.

Koch said after doing extensive research and testing on the SWAP, he gladly accepted the opportunity to become part of the company’s activities.

Robert Cohen

Robert Cohen

“I was impressed with the sound science and work behind SWAPSOL’s breakthrough,” Koch said.  “I look forward to being a part of the team as it advances and playing a solid role in bringing the company to the next level.”

Cohen has 15 years of experience in private equity, investment banking and financial advisory activities and currently manages the operations of Benson Oak Capital, based in Prague, Czech Republic.  His worldwide investments include those in the chemical sector and online security.  Cohen has a master’s degree in international affairs from the Johns Hopkins School of Advanced International Studies (SAIS) and a bachelor’s degree from the University of Pennsylvania’s Wharton School of Business.

“This technology has enormous potential and could quickly meet the needs of the oil and gas industry,” Cohen said. “And given that market potential, expert negotiations with future partners and customers are critical.”

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Will EPA move hurt business in effort to stop global warming?

Sunday, September 6th, 2009

The head of the Environmental Protection Agency (EPA) in April quietly dropped a bombshell on business  – carbon dioxide will soon be declared a dangerous pollutant.

In a move that could have momentous implications for environmental and energy policy, EPA Administrator Lisa Jackson recently told reporters that a formal “endangerment finding,” triggering federal regulations on greenhouse gas emissions, would probably “happen in the next months.” (SF Chronicle 9/1)

EPA Administrator Lisa Jackson

EPA Administrator Lisa Jackson

According to EPA scientists, greenhouse gases contribute to global warming by trapping heat in the Earth’s atmosphere. By declaring CO2 a dangerous pollutant, the EPA would have the ability to weigh heavily on Congress to move ahead with climate legislation.

A formal endangerment finding would enable the agency to regulate greenhouse gas pollution under the Clean Air Act – even if Congress doesn’t pass a final climate change bill.

Energy industry leaders have acknowledged the need for CO2 regulation, but decried the current U.S. Climate Bill as a dramatic blow to the petroleum industry itself.  Even so, they have largely favored Congressional action over EPA-imposed limits.

Valero Energy Corp. has said that the U.S. Climate Bill in its current form would cost the company $7 billion annually. The House of Representatives narrowly passed the bill in June.

“How would we be able to operate?” asked Jim Greenwood, vice president for governmental affairs at Valero, quoted in a recent news article. “I don’t know. If they can make some breakthroughs, especially with carbon capture and sequestration, you can halve carbon emissions.” (Reuters 8/28)

So, what’s the bottom line? Carbon legislation is coming, and it is, once again, imperative that American enterprise rise to meet the challenge of finding ways to maintain productivity and profitability while adapting to imminent energy policy.

www.swapsol.com

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National Chemistry Week Seminar : Can a chemical reaction help fight global warming?

Tuesday, September 1st, 2009

Wednesday, October 21, 2009

Could a Sour Natural Gas Process Convert Carbon Dioxide (CO2) and Hydrogen Sulfide (H2S) into harmless compounds?

Attend discussion on if an exothermic chemical reaction could contribute in the fight against global warming and climate change.

WHAT:

The Stenger Wasas Process (SWAP): A suite of hydrocarbon refining solutions that, in the laboratory, has been verified to rapidly reduce H2S to below detectable limits by gas chromatography (under 4ppb) and may be able to convert CO2 into carbon, water and sulfur industrially.  Discoverers of the SWAP invite academicians and experts to discuss the science and its potential contributions to the global warming solution.

WHERE:

Philip Alampi Auditorium, Rutgers University Cook Campus
School of Environmental and Biological Sciences
71 Dudley Road (corner of College Farm and Dudley Rd.)
New Brunswick, NJ

WHEN: Wed., Oct. 21

2:30 p.m. – 4:30 p.m.

RSVP:             www.swapsol.com/events.php

Open Admission      Q & A Following

WHO:

Raymond Stenger and James Wasas invite members of the academic and professional communities on Wednesday, Oct. 21, 2009, to learn about the Stenger-Wasas Process (SWAP), proposing that a reaction between carbon dioxide (CO2) and hydrogen sulfide (H2S) eliminates both (2H2S + CO2 => 2H2O + 2S + C) in a mildly exothermic reaction and could alter the course of global warming and impact escalating energy costs.  Hear and discuss the science behind the SWAP and its potential impact on the hydrocarbon industry.

PARTICIPANTS

  • Raymond Stenger (B.S.,WV University ‘57)
  • James Wasas (B.S., Rutgers ‘68)
  • Wolf Koch, Ph.D, Chemical Engineering, University of Cincinnati (B.S., Rutgers ‘68), President, Technology Resources International, Inc.
  • Gene Hall, Ph.D, Analytical Chemistry, Rutgers University (independent GC verification)
  • Randa Fahmy-Hudome, Former U.S. Associate Deputy Energy Secretary

Stenger and Wasas will discuss the catalytic and recombinant science behind the reaction.  Dr. Wolf Koch will discuss the potential commercial applications.  Q & A will follow: Dr. Hall will answer questions about his independent chemical and gas chromatography (GC) analysis; Executives will answer questions about findings and verifications of thermodynamic and chemical kinetic results showing scalability of the SWAP.

If you would like to attend, please visit: www.swapsol.com/events.php

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Can sulfur recovery breakthroughs reduce our environmental footprint?

Saturday, August 22nd, 2009

There has been a recent discovery of a previously unknown exothermic reaction between CO2 and H2S.  It’s a reaction that may fundamentally alter the hydrocarbon industry.  Work continues.  It’s called the Stenger-Wasas Process (SWAP) developed by Ray Stenger and Jim Wasas.  And it may make obsolete traditional petroleum methods, such as the Claus Process and its variants.

The SWAP: Unrefined sour natural gas is fed into the catalytic reactor, where the SWAP reaction occurs between CO2 and H2S. Refined gas flows past the separator. CO2 and H2S are converted into water, sulfur and carbon in the collector. In a reaction that can start in less than one second at very moderate temperatures, the result of the SWAP is refined natural gas.

Brief Overview

Sulfur contaminants such as hydrogen sulfide (H2S), carbonyl sulfide (COS), and mercaptans in gas streams can create unacceptable levels of sulfur emissions in power applications or poison catalysts used in chemical synthesis. Sulfur contaminants are usually reduced to less than 300 ppm for power generation and considerably lower (<1 ppm) for the synthesis of methanol, ammonia, and Fischer-Tropsch (FT) liquids.

Sulfur recovery unit (courtesty: C&I)

Sulfur recovery unit (courtesy: C&I)

Sulfur Recovery Processes

Removing sulfur from a natural gas or syngas process stream is only part of the story. The residual sulfur present in an acid gas stream must then be recovered to prevent environmental and safety harms, as well as meet operator permit requirements. Two main technologies have traditionally been used commercially to recover sulfur: the Claus process (partial combustion) for high levels of sulfur, and catalytic Redox processes, for relatively low levels of sulfur. In recent years, bio-chemical based technology, the Thiopaq Process, has been developed and commercially implemented. Other recent developments include the development of hybrid processes that combine Claus and Redox technology and are used for tailgas cleanup in Claus plants.

The SWAP has been verified by gas chromatography in the laboratory to reduce H2S to below the limit of detection (about 4ppb) in a single pass through the SWAP column.

The SWAP in the laboratory

The SWAP in the laboratory

Classified as hazardous waste by the EPA, H2S disposal requires expensive processing, i.e. the Claus Process. The SWAP may reduce related capital costs for the H2S disposal resulting from crude oil desulfurization, while simultaneously eliminating substantial amounts of CO2.

CLAUS PROCESS

Technology Description

In the Claus process, a high H2S concentration stream is the feedstock for recovery to elemental sulfur. Roughly 1/3 of the H2S is burnt (partial combustion) to form sulfur dioxide (SO2). The remaining H2S reacts with the synthesized SO2 over an alumina or bauxite catalyst to produce elemental sulfur. Depending on their concentrations, the unreacted components (tail gas), such as residual SO2, CO2, and H2S, are either emitted, thermally oxidized, or further treated in an additional recovery process.

(US Environmental Protection Agency, AP42, 5th Edition, “Compilation of AirPollutant Emissions Factors Volume 1: Stationary Point and Area Sources, 1995) The Claus process is thermodynamically limited to ~97 percent sulfur recovery, although additional treatment steps, such as tail gas sulfur recovery, can increase the recovery rate.

Commercial Manufacturers and Applications

The Claus process is the oldest commercial sulfur treatment process, with development dating back to the late 19th century. Today, Claus processes are the main step used for elemental sulfur production worldwide-in fact, 90 percent to 95 percent of the sulfur recovered in the United States was from the Claus process. Almost 40 companies operate over 1000 Claus processes in the United States, recovering nearly 9 million tons per year of sulfur. The petroleum and natural gas industries are the main users of the technology, with IGCC applications making up a small but growing segment of the user population.

With catalytic refining, environmental footprint and operational costs can be lowered. This and other breakthroughs may change the landscape of hydrocarbon refining.  www.swapsol.com

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A word on clean coal , Syngas and CO2 storage

Wednesday, August 19th, 2009

Much has been made of late about the benefits and/or viability of so-called clean coal technologies.  Indeed, in a national ad campaign the Reality Coalition has suggested that the aforementioned technology is an outright myth.  Yet depending on who you talk to,  the next decade may show these “clean coal” technologies will play a much larger role in electricity generation.

IGCC process (courtesy: Clean Coal Illinois)

IGCC process (courtesy: Clean Coal Illinois)

Among these  “clean” technologies is the production of synthesis gas (Syngas) through a relatively new process called Integrated Gasification Combined Cycle (IGCC).  In short, heating coal under pressure in an oxygen-restricted environment produces Syngas, a mixture of carbon monoxide (CO), hydrogen (H2), methane (CH4) and carbon dioxide (CO2).  With the notable exception of CO2, each of these products can be burned as fuel.  Methane is the chief component of natural gas.  Carbon monoxide and hydrogen can be burned in a gas turbine, or processed to produce liquid fuels through the Fischer-Tropsch process.

The scientific consensus on CO2 is that man-made carbon dioxide tops the list of global warming causes. Proponents of “clean coal” trumpet carbon capture and sequestration as a panacea; but it may be this line of thinking that has detractors and environmentalists up in arms.  While the science of Syngas technology is fairly well established, CO2 storage and sequestration is still an immerging technology, one we hope will gain ground given what we see as several notable obstacles.

CO2 capture and storage (courtesy: Total, S.A.)

CO2 capture & storage (courtesy: Total, S.A.)

But CO2 storage, potentially an attractive option, often hinges upon certain geological criteria.  If this option is to be taken seriously, we must identify compatible carbon sinks and depleted oilfields capable of permanently and safely housing large volumes of CO2. At an off shore undersea aquifer off Norway, for example, Statoil buries carbon dioxide extracted from natural gas to avoid paying pollution taxes to the Norwegian government.   And offshore storage, while effective, comes at a heavy cost both in terms of capital and energy efficiency.

What are the ways science can support these alternatives through supporting technologies?   Any working energy policy must be multi-tiered to be effective.  CO2 capture will certainly have its place in the new energy economy.  And with clean coal, we believe that cooperation across industries is the only answer.  When these companies begin to share new, tested and available technologies, we believe coal and its derivates may truly provide a substantial source of clean energy in the future. www.swapsol.com

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Evolving energy policy ignoring Hydrogen Sulfide in global warming causes

Monday, August 17th, 2009

Hydrogen Sulfide (H2S) isn’t the first thing you think about when you try and identify environmental enemies.  That is, of course, if you don’t live next to a landfill.  But it is attracting more and more attention in local communities, following reports of children feeling sick, public water being contaminated, and of course, the foul stench it creates when its gas emissions are released into the air.

Hydrogen Sulfide has been around for a long time.   In fact, some scholars theorize it was partly responsible for the “first mass extinction” millions of years before the dinosaurs met their demise.  They hypothesize this occurred during the Permian period, between 299 to 252.6 million years ago.  They think the Hydrogen Sulfide emitted from the oceans and elsewhere, such as “flood basalts,” turned the sky green, chocked off oxygen for plants, animals and marine life and killed 90 percent of species in the oceans and 70 percent of life on land.  That was a natural phenomenon.  But one expert thinks we’re on track for opening that door again.

Permian Period 291 - 251 million years ago (courtesty University of Michigan)

Permian Period 291 - 251 million years ago (courtesy University of Michigan)

“We’ve had these mass extinctions [from hydrogen sulfide] when carbon dioxide has hit 1,000 ppm. We have not hit that [level] for 100 million years,” said Peter Ward, professor of paleontology at University of Washington.  “But we are currently at 380 ppm — and climbing rapidly at 2 ppm a year and accelerating — and this is the highest CO2 I think in the last 40 million years. The only time [these extinctions] ever happened in the past is when these big flood basalts happened. But now we’re making it happen far faster than the flood basalts ever did. This is a unique event in the history of the planet.” (Wired Magazine 3/2008)

H2S should certainly be part of the discussion over global warming causes, but there of course remains the question of what to do with CO2.  Emit it or bury it (energy policy is driving carbon capture technologies still in the emerging stages of course.)  Like energy, you can’t destroy it. But what if you could turn it into something else?

But finally, what if you could turn H2S into something else as well?  www.swapsol.com

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