John Harrison Tec Eco Mag Min2010g

John Harrison, TecEco Pty. Ltd., Tasmania, Australia





Huge markets for magnesia in concretes and other

cementitious composites









Presentation downloadable from www.tececo.com

New Uses = New Markets

 Demand in this industry has been static for some years. New markets can change all that.

 Demand for Caustic Calcined and Less Reactive Grades through growth in the production and use of “MgO”

boards

 Based on magnesium oxychloride/sulfate cements + or – Mg phosphate cements

 Reinforced with natural and synthetic fibres.

 Huge potential demand for cements using reactive MgO

 Discovery that reactive MgO could be blended with other hydraulic binders such as Portland cement + or

– pozzolans. (Patented TecEco -Harrison)

 A powerful and useful new tool in cement chemistry affecting all properties including rheology,

bleeding, dimensional stability and durability to name but a few.

 Rekindled interest in environmentally friendly magnesium carbonate cements.

 Eco-Cements with a high proportion of reactive MgO (Patented TecEco - Harrison)

 Reactive MgO 95 – 5% Hydraulic cement e.g. PC 5 - 95%.

 Pure reactive MgO cements (Cambidge Uni Group. Old technology revisited)

 Magnesium oxy chloro carbonate cements. (Imperial College Novacem. Old technology with a new

spin?)





June 2010

Presentation downloadable from www.tececo.com

New Demand for New Forms of MgO

 Reactive Magnesia

L

 MgO calcined below say about 750 oC

and fine ground Focus on a R

to say Hydration energy Mg++



3795 kJ/mol-1 > 1926 kJ/mol-1



In solution in the first hydration shell six water

Periclase has a high lattice energy molecules are held tightly in place by electrostatic

and both cations and anions are in interactions between the two positive charges on

octahedral (6) coordination. the Mg++ ion and the partial negative charge on

the oxygen molecule of each water. This structure

The specific surface electrostatically propagates outward many layers

area of MgO is a deep.

Rapid formation of

proxy for lattice Rapid hydrated

energy and the formation of magnesium

lower the Brucite carbonates.

temperature of

calcination the e.g Tec-Cements e.g Eco-cements

more reactive the

MgO. See: Reactive Magnesia The Importance of the Temperature of

Calcination at

http://www.tececo.com/technical.reactive_magnesia.php



June 2010

Presentation downloadable from www.tececo.com

Deployment of new Cements

 Quality issues

 A narrower bell curve of properties such as reactivity and particle size is

required









 Price challenges

 Reactive magnesia must compete with Portland cement



 Environmental & bureaucratic challenges

 Carbon caps or taxes will apply to emissions from the production of

MgO

After inventing our Tec, Eco and Enviro cements TecEco set out to figure out new ways of

making reactive MgO and design a kiln that could solve the environmental sustainability

challenge and in the process we have solved the environmental, carbon, quality and price

issues as well



June 2010

Presentation downloadable from www.tececo.com

Making Cheaper Better Reactive MgO

Step Process Conditions Upsides Downsides

MgCO3=>MgO +↑CO2 600-750 OC Known Emissions, fossil fuel

technology energy. Blight on

landscapes.

Step 1 of Mg Silicate + ↓CO2 => Mg 180oC/150bar Sequestration Fossil fuel energy?

2 Carbonate step

Step 2 Mg Carbonate => MgO + 650-750 OC Calcination Process energy + re

↑CO2 step release CO2

Optional Mg Silicate => Mg Salt Various Known acid Expensive As acid

Step (MgCl2) extraction corrosive. Carbon

before neutral

Step 1 of Mg Salt + ↓CO2 => Mg Room temp. Use waste.

2 Carbonate (Nequehonite?) Carbon TecEco

credits.

Pref –

Step 2 of Mg Carbonate => MgO + 650-750 OC Calcination Process energy + re

2 ↑CO2 step release CO2

erred



We have to ask ourselves why we are still digging holes in the ground. The industry would

encounter far less bureaucratic blocking, make more money and go a long way towards solving

global warming using the last option in black with a light green background.

June 2010

Presentation downloadable from www.tececo.com

The TecEco Tec-Kiln - Changing the Way we Make Magnesia

 The Tec-Kiln is a top secret kiln being developed for low temperature

calcination of alkali metal carbonates and the pyro processing and

simultaneous grinding of other minerals such as clays.

 The TecEco Tec-Kiln makes no releases and is an essential part of

TecEco's plan to sequester massive amounts of CO2 as man made

carbonate in the built environment.

 The TecEco Tec-Kiln has the following features:

 Operates in a closed system and therefore does not release CO2 or other volatiles substances to the

atmosphere

 Can be powered by various potentially cheaper non fossil sources of energy such as intermittent solar or

wind energy.

 Grinds and calcines at the same time thereby running 25% to 30% more efficiently.

 Produces more precisely definable product. (Secret as disclosure would give away the design)

MgO

 The CO2 produced can be sold or re-used.

 Cement made with the Tec-Kiln will be eligible for carbon offsets. MgCO3

CO2

Tec-Kiln = Problems Solved = Way Forward

June 2010

Presentation downloadable from www.tececo.com

Gaia Engineering







Mg

Carbonates TecEco Tec-Kiln

Industrial CO2

MgO

Aggregates

Bitterns TecEco TecEco

MgCl2

or Eco- Tec-

Process Cements Cements

Brines





Building

Concretes and

waste

Other Composites

Other waste Built Environment

June 2010

Presentation downloadable from www.tececo.com

New Players re CO2 Capture = > Building Materials

 13th July 2002 – Fred Pearce in New Scientist about TecEco technology:

“THERE is a way to make our city streets as green as the Amazon rainforest. Almost

every aspect of the built environment, from bridges to factories to tower blocks, and from

roads to sea walls, could be turned into structures that soak up carbon dioxide- the main

greenhouse gas behind global warming. All we need to do is change the way we make

cement.

 2008 - Calera Corporation

 Brett Constance backed by Vinod Khoshla and others

 Attracting considerable criticism from scientists as upsets pH balance resulting in reduced inability of

oceans to absorb H2O (Ken Caldiera and others)

 Has so far produced the most expensive carbonate in the world



 2008 - Greensols Process (Cuff and Blake)

 A fundamentally good idea stalled by lack of finance



 2009 - Newcastle Group (Eric Kennedy and Others)

 Secretive







June 2010

Presentation downloadable from www.tececo.com

The Kyoto Process – A Political and Economic Dilemma

CO2 is CO2 is

adversely Action adversely Action

affecting affecting

climate Yes No climate Yes No



Cost $ Economic Profit $ Economic

Global Political Political

True Recession Social True Social

Environmental Environmental

Survival Catastrophe Catastrophe

Cost $ Money Profit $

Global Profit $

False Saved $

Recession False

Survival









The Current Situation The TecEco Alternative

A problem that’s never been easy to

come to grips with and that our By solving problems like global

national and international political warming profitably there is no

systems were not designed to handle dilemma and the world can move

forward



June 2010

Presentation downloadable from www.tececo.com

The Global Warming Problem



Global Carbon Flows

After: David Schimel and Lisa Dilling, National

Centre for Atmospheric Research 2003



The global CO2 budget is the balance of CO2

transfers to and from the atmosphere. The

transfers shown below represent the CO2

budget after removing the large natural

transfers (shown to the right) which are

thought to have been nearly in balance

before human influence.



Woods Hole Carbon Equation (In billions of metric tonnes)

Atmosp = Emissions from + Net emissions - Oceanic - Missing

heric fossil fuels from changes in uptake carbon

increase land use sink



3.2 (±0.2) 6.3 (±0.4) 2.2 (±0.8) 2.4 (±0.7) 2.9 (±1.1)

From: Haughton, R., Understanding the Global Carbon Cycle. 2009, Woods Hole Institute at http://www.whrc.org/carbon/index.htm



June 2010

Presentation downloadable from www.tececo.com

Net Atmospheric Increase in Terms of Billion Tonnes CO2

Using the Figures from Woods Hole on the Previous Slide

Atmospheric = Emissions from + Net emissions from - Oceanic - Missing

increase fossil fuels changes in land use uptake carbon sink



3.2 (±0.2) 6.3 (±0.4) 2.2 (±0.8) 2.4 (±0.7) 2.9 (±1.1)





Converting to tonnes CO2 in the same units by multiplying by

44.01/12.01, the ratio of the respective molecular weights.

Atmospheric = Emissions from + Net emissions from - Oceanic - Missing

increase fossil fuels changes in land use uptake carbon sink



11.72 (±0.2) 23.08 (±0.4) 8.016 (±0.8) 8.79 (±0.7) 10.62 (±1.1)





From the above the annual atmospheric increase of CO2 is in the

order of 12 billion metric tonnes.

June 2010

Presentation downloadable from www.tececo.com

How Much Man Made Carbonate to Solve Global Warming?

 If a proportion of the built environment were man made carbonate, how

much would we need to reverse global warming?

MgO + H2O => Mg(OH)2 + CO2 + 2H2O => MgCO3.3H2O

40.31 + 18(l) => 58.31 + 44.01(g) + 2 X 18(l) => 138.368 molar masses.

44.01 parts by mass of CO2 ~= 138.368 parts by mass MgCO3.3H2O

1 ~= 138.368/44.01= 3.144

12 billion tonnes CO2 ~= 37.728 billion tonnes of nesquehonite

or

MgO + H2O => Mg(OH)2 + CO2 + 2H2O => MgCO3

40.31 + 18(l) => 58.31 + 44.01(g) + 2 X 18(l) => 84.32 molar masses.

CO2 ~= MgCO3

44.01 parts by mass of CO2 ~= 84.32 parts by mass MgCO3

1 ~= 84.32/44.01= 1.9159

12 billion tonnes CO2 ~= 22.99 billion tonnes magnesite





June 2010

Presentation downloadable from www.tececo.com

So How Much Magnesia Would be Sold?



2E+10



1.8E+10



1.6E+10



1.4E+10



1.2E+10

Tonnes









1E+10



8E+09



Not enough 6E+09

to show on

graph 4E+09



2E+09



Magnesite Production 0

World Production Cement

Magnesia in Cement

Source Cement Data: USGS Minerals Yearbooks.

Portland Cement in Cement

Assume Concrete Includes 15% Cement

World Production Concrete



How Much Money = How Much Magnesia X Price + Value Carbon Credits – Costs Production



June 2010

Presentation downloadable from www.tececo.com

Natural Sinks for Carbon



This industry could

profitably be involved in

modifying the carbon

cycle by facilitating a new

man made carbon sink in

the built environment.

The need for a new and

very large sink can be

appreciated by

considering the balance

sheet of global carbon in

the crust after Ziock, H. J.

and D. P. Harrison

depicted.





Modified from Figure 2 Ziock, H. J. and D. P. Harrison. "Zero Emission Coal Power, a New Concept." from

http://www.netl.doe.gov/publications/proceedings/01/carbon_seq/2b2.pdf by the inclusion of a bar

to represent sedimentary sinks



June 2010

Presentation downloadable from www.tececo.com

Carbon Capture = Carbon Credits









June 2010

Presentation downloadable from www.tececo.com

Understanding Magnesium Compounds including Nano Composites



At http://www.tececo.com/technical.nanocomposites.php we discuss

the amazing ability of magnesium hydroxide to form complex layered

double hydroxide (LDH) compounds with many other substances

including water and CO2. This property is important because it is

why for example magnesium hydroxide hydrates can prevent

autogenous shrinkage of concrete and why magnesia is so useful for

locking up wastes. It is also related to how it can bond so easily with

other substances.









After: D’Souza, N. A., P. Braterman, et al. "Flame

retardant nano composites with layer double

hydroxides." Retrieved 15 October 2006, 2006.





Many magnesium compounds are characterised by a mixture of Ionic and Polar Bonding

and this accounts for many of their properties



June 2010

Presentation downloadable from www.tececo.com

Understanding Magnesium Compounds including Nano Composites



Brucite.

Polar bound

Brucite

layers of

hydrates.

ionically

Polar bound

bound

layers of

atoms

ionically

bound

atoms









Strongly differentially charged surfaces

and polar bound water account for many

Cellulose of the properties of brcute





June 2010

Presentation downloadable from www.tececo.com

A Classification of Magnesium Cements - 1

1. Cements that rely on the chemical reaction of magnesia with another component.

1.1 Reactions causing the formation of magnesium oxychloride, magnesium oxysulfate or derivatives. (Excluded in claim 1)

1.1.1 As a base with chlorides or sulfates. E.g Aluminum, magnesium, calcium, zinc or copper chloride or sulfate. Novacem

1.1.2 As a base with acids. e.g. Sulfuric or hydrochloric acids

1.1.3. As a base with partially substituted acids or salts containing chloride or sulfates. e.g. Reaction with calcium aluminate trisulphate, a double salt, delivering

sulphate for the formation of magnesium oxy sulfate.

1.2 Chemical reaction or interaction with substances that cause carbonation.

1.2.1 As a base with organic substances delivering CO3--. e.g Carbonic acid. (See also 1.3.1)

1.2.2 As a base with inorganic substances delivering CO3--. e.g. Sodium carbonate and calcium carbonate, CO2 or a chemical that releases CO2. The CO2 which

then dissolves in water forming carbonic acid. (Carbonic acid will force rapid carbonation of magnesia whereby various magnesium carbonates are formed in

situ.)

1.3 Chemical reaction with acidifying agents.

1.3.1 Organic acidifying agents. E.g. Citric acid, acetic acid and other carboxylic or polycarboxylic acids. (Such organic acidifying agents may also deliver

carbonate (CO3--.) and thus fall into the category 1.2.1 above.)

1.3.2 Inorganic acidifying agents. Acidifying acids may assist the dissolution and reformation of carbonate or act as accelerators or retardants depending on the

mix.

1.3.3 Neutralization of acids e.g low molecular weight organic acids from the breakdown of pectin and lignin in wood prior to use of an ingredient such as in this

case wood

1.4 Cements that include an soluble or acid phosphate and result in chemical precipitation of insoluble magnesium phosphates.

1.5 Chemical reaction in the form of ion exchange. The use of magnesia for ion replacement in a more soluble substance rendering the substance less soluble.

1.5.1 The replacement of Na+ or K+ is waterglass. e.g the replacement of Na+ or K+ in sodium or potassium silicates resulting in an insoluble precipitate of

magnesium silicate.

1.6 Chemical reaction as a so called “activator” or “accelerator” (Note that Mg is not a network former in geopolymeric binders as claimed rather arbitrarily by

many.)

1.7 Cements that rely on prior addition of magnesia to another substance resulting in chemical and physical interaction sequentially prior to the addition of other

binder components

1.7.1 The interaction of magnesia with schist or the waste from coal washings prior to the addition of other binders such as Portland cement

1.7.2 The reaction of magnesia with low molecular weight compounds e.g. wood acids prior to further additions.

1.8 The reaction of substances in a binder prior to addition of the reactants to magnesia

1.9 Chemical interaction with other salts (e.g. borax)

1.10 Interaction with some other substance



June 2010

Presentation downloadable from www.tececo.com

A Classification of Magnesium Cements - 2

2. Cements in which the main role of magnesia is in electrostatic bonding reactions. Cements that rely on the strong non-ionic, non covalent bonding of

Mg++ to a negative region of a molecule. E.g. Mg++ to oxygen - similar to hydrogen bonding.

2.1 Bonding of Mg++ to oxygen in cellullosic compounds and oxygen in water.

2.2 Bonding and complexing with water. The hydration energy of Mg++ is very high (Note1) In solution Mg++ complexes with water more readily than

Ca++ forming ions of the general form [Mg(H2O)N]2+. Mg++ can also hydroxylate forming H3O+ and Mg+OH and hydrated forms of Mg+OH. These

complexes greatly affect the rheology of water particularly in the presence of substances displaying strong hydrogen bonding, wherein Mg++ is

attracted to the net negative charge on oxygen.

2.3 Electrostatic and sorption bonding to activated carbon

3 Cements that use dead burned rather than reactive magnesia.

3.1 Cements that use dead burned rather than reactive magnesia to deliberately induce expansion.

4. Cements that rely on the physical properties of magnesia rather than reaction. E.g. Cements that use dead burned rather than reactive magnesia to

increase fire retarding properties

5. Cements that have a high proportion of calcium carbonate in them. (May also fall into 1.2.2 above)

5.1 Cements that include magnesia sourced from dolomite or

5.2 Cements that have been blended to include calcium carbonate. (excluded as we teach this is obviously not desirable)

6. Cements that do not include another hydraulic cement. Cements that may include magnesia but do not include a hydraulic cement like Portland cement.

7. Citations in which the use of magnesia is incidental and unnecessary

8. Citations that are nothing whatsoever to do with the TecEco patent or for which insufficient information has been provided

9. Complex mechano or nano composites.

Note 1 Mg++ has a hydration energy of 1926 kJ/mol compared to 1579 kJ/mol for Ca++ [1,2]. Six water molecules in octahedral coordination surround

the Mg2+ ion in a rigid first solvent shell [3]. For comparison, the exchange rate of water in the hydration shell of Ca2+ ions is ~1000-fold faster

than for Mg2+ ions [4].

Ref 1 Slaughter M, Hill RJ: The influence of organic matter in organogenic dolomitization. J Sed Petrol 1991, 61:296-303.

Ref 2 Wright DT, Wacey D: Precipitation of dolomite using sulphate-reducing bacteria from the Coorong Region, South Australia: Significance

and implications. Sedimentology 2005, 52:987-1008. Publisher Full Text

Ref 3 Kluge S, Weston J: Can a hydroxide ligand trigger a change in the coordination number of magnesium ions in biological systems.

Biochemistry 2005, 44:4877-4885. PubMed Abstract | Publisher Full Text

Ref 4 Fenter P, Zhang Z, Park C, Sturchio NC, Hu XM, Higgins SR: Structure and reactivity of dolomite (104)-water interface: New insights into

th dolomite problem. Geochim Cosmochim Acta 2007, 71:566-579. Publisher Full Text



June 2010

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Why MgO in Hydraulic Binder Systems?

 Mg in solution is

 strongly kosmotrophic => profound effects on rheology

 increased surface tension reduces bleeding and thus early age plastic shrinkage.

 Long term shrinkage eliminated.

 Replaces free lime (Portlandite Ca(OH)2) in concretes

 Free lime (Portlandite, Ca(OH)2) in concretes is too reactive.

 In Tec-Cement binders free lime is encouraged to react with pozzolans forming more

calcium silicate hydrates. It is replaced by brucite and brucite hydrates which take on the

major function of long term pH control and eliminate autogenous shrinkage.

 Dramatically improves durability

 Lower solubility and reactivity (Eh & pH conditions) of Brucite

 Expansive carbonation resulting in very tight surfaces preventing entry of aggressive ions.









June 2010

Presentation downloadable from www.tececo.com

Magnesium Compounds

Mineral (or Formula Partial Ph Hard Habit

Product) Pressures ness



Brucite Mg(OH)2 10.2 2.5 - Blocky pseudo

3 hexagonal chrystals.

Brucite Hydrates Mg(OH)2.nH2O Not much known!

C

Dypingite Mg5(CO3)4(OH)2·5H2O Low CO2, High? ? Platy or rounded

H2O rosettes a

Hydromagnesite Mg5(CO3)4(OH)2·4H2O High? 3.5 Include acicular, r

Giorgiosite lathlike, platy and

rosette forms

b

Artinite Mg2(CO3)(OH)2•3(H2O) 2.5 Bright, white acicular o

sprays n

Magnesite MgCO3 3.9 Usually massive

a

Barringtonite MgCO3·2H2O 2.5 Glassy blocky crystals

t

Nesquehonite MgCO3·3H2O Presence Variable? 2.5 Acicular prismatic

H2O needles

e

Lansfordite MgCO3·5H2O 2.5 Glassy blocky crystals s

Note: Many other possible forms. Abiotic and biotic precipitation pathways

and a lack of thermodynamic optimisation data

June 2010

Presentation downloadable from www.tececo.com

Magnesium Carbonate Phases









June 2010

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Why Brucite in Dense Concretes?

 Brucite

 Improves rheology (see

http://www.tececo.com/technical.rheological_shrinkage.

php)

 Prevents shrinkage and cracking (see

http://www.tececo.com/technical.rheological_shrinkage.

php)

 Provides pH and eH control. Reduced corrosion.

Stabilises CSH with pozzolanic reaction (Encouraged)

Pourbaix diagram steel reinforcing

 Provides early setting even with added pozzolans

 Relinguishes polar bound water for more complete

hydration of PC (thereby preventing autogenous

shrinkage?)





Surface charge on magnesium oxide

MgO + H2O => Mg(OH)2

June 2010

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Why Nesquehonite in Carbonating Binder Systems?

 At 2.09% of the crust magnesium is the 8th most abundant element

 Nesquehonite

 Has an ideal shape that contributes strength to the microstructure of a

concrete

 Forms readily at moderate and high pH in the presence of CSH, our catalyst.

(Nucleation mechanism?)



 The hydration of PC => alkalinity dramatically increasing the

CO3-- levels that are essential for carbonation. Nesquehonite



 Significant molar volume

expansion.

 Captures more CO2 than Calcium







3H2O + CO3---- + Mg++ => MgCO3·3H2O

XRD Pattern Nesquehonite



 Ideal wet dry conditions are easily and cheaply provided. Forced

carbonation is not required (Cambridge uni and others)

June 2010

Presentation downloadable from www.tececo.com

TecEco Formulations

 Tec-Cements (5-20% MgO, 80-95% OPC)

 contain more Portland cement than reactive magnesia. Reactive magnesia hydrates in the

same rate order as Portland cement forming Brucite which uses up excess water reducing

the voids:paste ratio, increasing density and possibly raising the short term pH.

 Reactions with pozzolans are more affective. After much of the Portlandite has been

consumed Brucite tends to control the long term pH which is lower and due to it’s low

solubility, mobility and reactivity results in greater durability.

 Other benefits include improvements in density, strength and rheology, reduced

permeability and shrinkage and the use of a wider range of aggregates many of which are

potentially wastes without reaction problems.

 Eco-Cements (20-95% MgO, 80-5% OPC)

 contain more reactive magnesia than in Tec-Cements. Brucite in permeable materials

carbonates forming stronger fibrous mineral carbonates and therefore presenting huge

opportunities for waste utilisation and sequestration.

 Enviro-Cements (5-15% MgO, 85-95% OPC)

 contain similar ratios of MgO and PC to eco-cements but in non permeable concretes

brucite does not carbonate readily.

 Higher proportions of magnesia are most suited to toxic and hazardous waste

immobilisation and when durability is required. Strength is not developed quickly nor to the

same extent.

June 2010

Presentation downloadable from www.tececo.com

Conclusion



 To avoid carbon costs and other imposts maybe the industry should consider

making MgO in different way.

 The industry can gain a competitive advantage by being the first to produce product

without releases and utilising wastes .

 MgCl2 + CO2 => MgCO3.3H2O => MgO +CO2



 Magnesium oxide on hydration and/or carbonation becomes many different

minerals all of which should be considered as products with huge marketing

opportunities such as for carbon sequestration.

 There must be much more focussed research into this wide array of new products as

they are sold into technical markets.

 MgO of better quality and lower price is required to compete with Portland

cement.

 As in the cement industry the MgO industry should consider forming an

association which at an industry level carries out the basic research required to

move into new markets.

June 2010

Presentation downloadable from www.tececo.com