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A BRIEF HISTORY OF TIME
IN CHEMISTRY
Gregory S. YablonskyParks College of Engineering, Aviation and Technology,
Saint Louis University, St. Louis, Missouri, USA
•
• “The history of science is the only history
which can illustrate the progress of mankind”
• (George Sarton)
• “The only reason for time is so that
everything doesn’t happen at once”
• Albert Einstein
A. INITIAL STORY
• The first step.
• There were 500 bricks inside the airplane.
One brick was dropped.
How many bricks are remained inside the
airplane?
• Correct!
499!
• The second step.
How to put an elephant into the refrigerator?
Three-stage procedure:
(1) To open the refrigerator;
(2) To put the elephant into the refrigerator
(3) To close the refrigerator
• The third step.
How to put an reindeer into the refrigerator?
Four-stage procedure:
(1) To open the refrigerator;
(2) To take the elephant out of the refrigerator;
(3) To put a reindeer to the refrigerator ;
(4) To close the refrigerator
• The fourth step
A lion, the king of animals, has the birthday
party.
All animals came to this party except one.
Who is this one?
lio
• Certainly, the reindeer!
• The fifth step
An old lady crossed the African river with
crocodiles.
However she survived.
Why?
• Correct!
• All crocodiles attended the lion’s party!
• The sixth step, the final one.
Unfortunately this old lady died at the same
day.
Why?
• She was hit by the brick which was dropped
from the airplane.
• The level of complexity of this example is very correspondent to the complexity of chemical reaction.
It is the multi-stage process
It is the temporal process.
It is the cyclic process.
There are three conservation laws:
• (1) Conservation of the number of all animals
• (2) Conservation of the number of bricks
• (3) conservation of the space of refrigerator
• Also there is a catalyst, the brick.
EXAMPLE: 2H2 + O2 = 2H2O
B. Time and chemical complexity
Pre-history
• Many activities of human beings are complex chemical reactions which are occurred in time
(1) Combustion as a source of energy since Neanderthal times…(“500, 000 years of combustion technology”);
(2) Preparation of food and beverages (bier, wine);
(3) Preparation of materials: Bronze from Cu and Sncontaining ore (“Bronze age”); Iron using the ferrous metallurgy( “Iron Age”)
Etc…Etc…
Time and Complexity
• What is a meaning of chemical time?
• Is it just a scale for presenting the complex
reaction, i.e. complex sequence of chemical
events(transformation)?
• Or it is an exhibition (function) of complex
chemical transformations?
19
G.B. Marin & G.S. Yablonsky
(2011). Kinetics of Chemical
Reactions. Decoding
Complexity
Three Meanings of Time
1. “Clock” time t (or astronomic, or external time):
Change of chemical composition during ∆t
2. “Internal”, or “intrinsic” time:
Time scale at which a reaction occurs
3. Residence time:
“Transport time” as a measuring stick of the
chemical reaction(s)
C. Time in Chemistry: Starting Point
Discovery of Catalysis
Catalysis is the fundamental chemical phenomenon that underlies
Life90% of new chemical processes
CO2 conversion to roses Nontoxic auto-exhaust
Petroleum fuels
Ammonia fertilizerChateau Lafite Rothschild (1887)
NylonSulfuric acid
L-dopaHefty trash bags
Anti-freezeFuel cells
Plastic drain pipeAspartameRoundup
and on and on ……
"Virtually every chemical reaction that
occurs in living organisms is
catalyzed by a specific enzyme."
The Living Cell - C. deDuve Most important environmental
technologyG. Ertl's 2007 Nobel prize involved study
of this catalyticsystem
Chiral Rh complex creates a chiral
productW. Knowles shared 2001 Nobel prize for work on this system
Makes diet coke possible
Natural Catalytic Phenomena
ProductReactant
(O2, Carbohydrates)
Reactant(CO2)
Catalyst (enzyme)
Plant
Energy in (UV-Vis Light)
Reactant
ProductTissue, etc.
(CO2)
Transformation
Regeneration
Animal
Energy out work, heat
Reactant
Catalyst (enzyme)
Story I : Catalysis
(Germany: Johann – Wolfgang Doebereiner)
Catalysis discovery is more interesting than any
Hollywood movie.
Main characters of this historical movie are:
1. The chemist Johann-Wolfgang Doebereiner
(1780-1856).
2. The great German poet Johann-Wolfgang
Goethe (1749-1832), prime-minister of the
small Weimar dukedom.
3. August, Duke of the Weimar dukedom
4. Russian Tsar’s sister and Duke’s daughter –in-
law, Maria Pavlovna
Johann Wolfgang Goethe (1749- 1832)
Faust
• "Stop time, • thou art so beautiful!“• (“Faust”, Goethe)
Goethe, “Faust”
• “Werd ich zum Augenblicke sagen:
Verweile doch: du bist zu schoen
• Dann magst du mich in Fesseln schlagen,
• Dann will ich gern zugrude gehn”.
Johann-Wolfgang Dobereiner (1780-1849)
CATALYSISDoebereiner never graduated from any university.
Despite that Goethe hired him as a court apothecary.
Doebereiner enthusiastically studied the reaction of
hydrogen oxidation and found an amazing jump of
the reaction rate (“an explosion”) in the presence of
platinum
Unfortunately, he had no platinum enough because
of wars in South America.
Grand Duchess Maria Pavlovna (1786-1859)
Introducing the concept time
• Catalysis = dramatic change in time
• A special ‘catalytic force’, Berzelius (Sweden)
• Discovery of catalysis promoted introducing
the concept of time into chemistry.
• However catalysis as a phenomenon was
remaining mysterious until 1880s
D. INTRODUCING TIME (1851)
Time is introduced into chemistry
• Chemical kinetics was born
•
1851, Williamson and Wilhelmi
• 1851, Williamson (USA), ‘’Some considerations on chemistry dynamics exemplified by the etherification theory”
• Williamson seems to have been the first to use the term ‘dynamics’ regarding the non-steady state chemical processes.
• “There are many evidences that chemical processes need time, but this commonly accepted fact is not taken into account in treating various phenomena” (Williamson)
1851, Williamson and Wilhelmi
• 1851, Wilhelmi (Germany): the first kinetic quantitative relationship in studies of acids on the cane sugar
• -(dZ/dT) = MZS,
• where Z and S are the amounts of sugar and acid catalyst, respectively; T is the reaction time, and M is the mean amount of sugar which has undergone conversion during an infinitesimal period of time under the effect of unit concentration of the catalyzing agent
(Wilhelm )Ostwald about Wilhelmi
• “We must consider Wilhelmi as an inventor of the concept of the chemical reaction rate”…
• “Wilhelmi’s study had remained absolutely ignored though it has been published in a rather widespread Annals of Physics by Poggendorf… It remained unknown for the later researchers working on similar problems…Only after this field of science had already been so developed that some people began to think about its history, the basic Wilhelmi’s study came to light”…
Wilhelm Ostwald (1853-1932)
Ostwald’s conceptual breakthrough
(1880s-1890s)
• Ostwald gave the first essential interpretation of catalysis.
• What is catalysis as a phenomenon?
• Ostwald’s answer:
“CATALYSIS IS JUST KINETICS”
Ostwald (1895):“A catalyst accelerates a chemical reaction without affecting the position of the equilibrium.”
E. The main law of chemical kinetics
The Mass-Action-Law (1860s – 1880s)
• The Guldberg-Waage-van’t Hoff’s case story
• Guldberg-Waage (Norway)
van’t Hoff (Netherlands)
Cato Maximilian Guldberg (1836-1902)
Peter Waage (1833-1900)
Jacobus Henricus van 't Hoff (1852-1911)
The Hidden History of Chemical Kinetics, I
Gul’dberg and Waage , Norway, 1862-1867
Mass-Action-Law( M.A.L.)
Equilibrium formulation
“ In chemistry like in mechanics the most natural
methods will be to determine forces in the
equilibrium states”.
Kpq = Kp'q', where p,q,p'q' are the " action masses"
Initially, Guldberg and Waage used an expression
Kpαqβ = K(p')α (q')β
The Hidden History of Chemical Kinetics, II
Gul’dberg and Waage, 1879
Dynamic Formulation of the Mass-Action-Law
(M.A.L.)
R = K pααααqββββrγγγγ
The Hidden History of Chemical Kinetics, III
Van’t Hoff, Netherlands, the first winner of
the Nobel award (1901) on chemistry
1884, “Essays on chemical kinetics”
Idea of normal transformation
“The process of chemical transformations is characterized
solely by the number of molecules whose interaction provides this transformation” (A⇔⇔⇔⇔B; 2A⇔⇔⇔⇔ B; A+B ⇔⇔⇔⇔ C; 2A+B ⇔⇔⇔⇔ C)
Strong discussion with Gul’dberg and Waage:
“As a theoretical foundation I have accepted not the concept of mass action ( I had to leave this concept in the course of my experiment)”. Van’t Hoff tried to eliminate mechanics from chemistry.
The Hidden History of
Chemical Kinetics, IV
Van’t Hoff believed that he found
the chemical (not mechanical)
LAW OF CHEMICAL KINETICS
However, his normal transformation dependences
did not fit many real experimental data,
e.g. hydrogen oxidation data
46
G.B. Marin & G.S. Yablonsky
(2011). Kinetics of Chemical
Reactions. Decoding
Complexity
Van ‘t Hoff’s Revolution
Contradictions
Van ‘t Hoff introduced the “natural” classification, but at the
same time was of the opinion that “normal transformations”
occur very rarely
He considered the effect of the reaction medium, “disturbing
factors”, to be the reason for this
Semenov about Van ‘t Hoff’s “Essays”:
“…when one is reading this book, one feels as if the author was very
interested in the reasons for the abnormal course of reactions and the
disturbing factors rather than in further extending his knowledge on
normal processes, as he treated them as virtually evident… Van ‘t Hoff’s
considerations on the abnormal behavior of reactions is three times as
much.”
The new idea: “chemical mechanism”(Ostwald? Shoenbein? Christiansen?)
It has an obvious “mechanical origin”Maxwell’s metaphor: BELL and MANY ROPES
In 1879, a vivid interpretation of complex systems as mechanical systems was
given by Maxwell. “In an ordinary chime every bell has a rope that is drawn
through a hole in the floor into the bell-ringer room. But let us imagine that every
rope instead of putting into motion one bell participates in the motion of many
parts of the mechanism and that the motion of every bell is determined not only
by the motions of its own rope but the motions of several ropes; then let us
assume that all this mechanism is hidden and absolutely unknown for the people
standing near the ropes and capable of seeing only the holes ceiling above them”.
The Hidden History of Chemical Kinetics, V
Chemical kinetics of the XX century is a ‘centaurus’ which parts are different.
1. The ‘law’ related to the ‘natural classification’ belongs to van’tHoff.
2. The name ‘mass-action-law’ is coined by Guldbergand Waage.3. The idea of ‘mechanism’ belongs to ‘unknown parents’ (Ostwald?
Schoenbein? Chrisitiansen?)
Christiansen compared the problem of elucidating the complex reaction mechanism with solving the crossword puzzles.
• F. Three types of Chemical Kinetics
50
G.B. Marin & G.S. Yablonsky
(2011). Kinetics of Chemical
Reactions. Decoding
Complexity
Three Types of Chemical Kinetics
1. Applied kinetics
2. Detailed kinetics
3. Mathematical kinetics
51
G.B. Marin & G.S. Yablonsky
(2011). Kinetics of Chemical
Reactions. Decoding
Complexity
Applied Kinetics
• Used for obtaining kinetic dependences for
reactor and process design(synthesis of ammonia,
• oxidation of ammonia, oxidation of SO2 etc)
• Kinetic model
→ model of catalyst pellet
→ model of catalyst bed
→ model of reactor
• Combinatorial catalysis
r = f(T, p, c)
52
G.B. Marin & G.S. Yablonsky
(2011). Kinetics of Chemical
Reactions. Decoding
Complexity
Detailed Kinetics
• Aimed at reconstructing the detailed mechanism
• Based kinetic and non-kinetic data
Detailed mechanism:
Set of elementary steps
Each elementary step consists of a forward and a reverse elementary reaction
Kinetic dependence is governed by the mass-action law
1890-1920ies
• Introducing the idea of “mechanism” of chemical reaction (“detailed mechanism” of the complex reaction)
Cyclic mechanisms via intermediates
• A. Cyclic mechanism of the catalytic reaction via different intermediates (surface or liquid phase intermediates)
• B. Cyclic mechanism of the gas or liquid chain reaction via radicals
• C. Cyclic mechanism of the enzyme reaction (Michaelis-Menten mechanism)
Nikolay Semyonov (1896-1986)
Cyril Hinshelwood (1897 – 1967)
Irving Langmuir (1881 – 1957)
57
G.B. Marin & G.S. Yablonsky
(2011). Kinetics of Chemical
Reactions. Decoding
Complexity
Mathematical Kinetics
• Deals with the analysis of mathematical models
• Deterministic models are a set of algebraic, ordinary differential or partially differential equations
• Stochastic models are based on Monte-Carlo methods
• Direct and inverse kinetic problems
Kinetic parameters
are known
Estimation of kinetic
parameters
temporal change of transport change due to
amount of component change reaction
= +
G.B. Marin & G.S. Yablonsky (2011).
Kinetics of Chemical Reactions. Decoding
Complexity
59
Non-Steady-State Models
( ),d
fdt
=cc k
describes the temporal evolution of a chemical reaction mixture from an initial state to a
final state
• closed system: equilibrium
• open system: steady state
Three methods for studying non-steady-state behavior:
• change in time t: change in dynamic space (c,t)
• change of parameters k: change in parametric space (c,k)
• change of a concentration with respect to others: change in phase space
Rutherford Aris (1929 – 2005)
• G. Experimental Devices of Chemical Kinetics
Typical Requirements to Kinetic
Experiments:
• Isothermicity
• Intensive heat exchange with surroundings
• Dilution of reactive medium
• Rapid recirculation
• Uniformity of the chemical composition
• Intensive mixing
G.B. Marin & G.S. Yablonsky (2011).
Kinetics of Chemical Reactions. Decoding
Complexity
63
Reactors for Kinetic Experiments
feed product feed product
recycle
feed product feed product
catalyst zone
Batch reactor CSTR Continuous-flow reactor with
recirculation
PFR Differential PFR
G.B. Marin & G.S. Yablonsky (2011).
Kinetics of Chemical Reactions. Decoding
Complexity
64
Reactors for Kinetic Experiments
catalyst zone
inert
zone
Convectional pulse
reactor
Diffusional pulse
reactor / TAP reactor
Thin-zone TAP
reactor
65
G.B. Marin & G.S. Yablonsky
(2011). Kinetics of Chemical
Reactions. Decoding
Complexity
Types of Temporal Evolution − Relaxation
c
t
c
t
c
t
slowintermediate
fast
Simple exponential relaxation Relaxation with induction period
Relaxation of different components at different time scales
66
G.B. Marin & G.S. Yablonsky
(2011). Kinetics of Chemical
Reactions. Decoding
Complexity
Types of Temporal Evolution − Relaxation
c
t
3
2
1
Relaxation with “overshoots” (1) & (3) and start in “wrong” direction (2)
67
G.B. Marin & G.S. Yablonsky
(2011). Kinetics of Chemical
Reactions. Decoding
Complexity
Types of Temporal Evolution − Relaxation
c
t
I
II
c
t
Relaxation with different steady states
Damped oscillations
Belousov-Zhabotinsky reaction
69
G.B. Marin & G.S. Yablonsky
(2011). Kinetics of Chemical
Reactions. Decoding
Complexity
Types of Temporal Evolution − Relaxation
c
t
c
t
Regular oscillations around a
steady state
Chaotic oscillations
Anatoly Zhabotinsky (1938 – 2008)
Gerhard Ertl (1936 - )
Progress in time resolution
for 150 years
• From second to femptoseconds (10 -15 sec)
Time and Complexity
• What is a meaning of chemical time?
• Is it just a scale for presenting the complex
reaction, i.e. complex sequence of chemical
events(transformation)?
• Or it is an exhibition (function) of complex
chemical transformations?
• (H) ELIMINATING TIME.• CONSIDERING CONSTRAINTS.
Chemical evolution
Two main statements
(1) EVERYTHING IS CHANGING.
HOWEVER THE FINAL POINT IS KNOWN.
IT IS AN EQUILIBRIUM
(2) EVERYTHING IS CHANGING.
HOWEVER SOMETHING IS CONSTANT.
SOME CHANGES ARE VERY DETERMINED.
What is that?
• Closed chemical system
• (1) Conservation of the total mass of every chemical element
• (2) Conservation of the energy –in accordance with the first law of thermodynamics
• (3) The entropy has to be increased in time (or the free Gibbs energy has to be decreased in time) – in accordance with the second law of thermodynamics
Equilibrium as the final point.Principle of detailed equilibrium.
Under equilibrium conditions,
the principle of detailed equilibrium
(Onsager, 1931; Nobel prize of 1968) is valid.
This principle determines relationships
between parameters. They are valid at any
moment of time, not only under equilibrium
conditions.
Equilibrium as the final point
• The equilibrium dependence of the complex chemical composition is known in advance based on the thermodynamics. It is very different from the kinetic dependence. The last one is unknown in advance.
• An equilibrium thermodynamics is our ‘solid foundation’.
•
Reduction of complex model: relationships between concentrations; partial eliminating of time
• Different assumptions on temporal behavior:
• -limiting character of some step (some steps
are the slowest ones)
• Partial equilibrium of some steps (some steps
are the fastest ones)
• Pseudo-steady-state approximation =
‘eliminating time’ for some substances
‘Eliminating time’
for some substances
• Pseudo-Steady-State hypothesis (PSSH)
• Two-stage ‘scientific trick’
• (1) Introduce ‘fast’ intermediates
• (2) Eliminate time for these
intermediates
The Hidden History of Chemical Kinetics, VI
“Reaction is not a single act drama” (Schoenbein)
There are many intermediates (X)
According to the Pseudo-Steady-State Hypothesis (P.S.S.H.),
Rate of intermediate generation = Rate of intermediate consumption
Ri.gen (X, C) = Ri.cons(X, C)
Then, X = F(C)
and Reaction Rate R(X, C)=R (C, F(C))=R(C)
P.S.S.H, or Bodenstein’s Principle
A paradox of PSSH.
Reflecting complexity, we are introducing new unobserved substances (intermediates).
At the same time, we are eliminating intermediates searching for simplicity.
“The first who applied this theory was S. Chapman and half the year later Bodenstein referred to it in the paper devoted to the hydrogen reaction with clorine. His efforts to confirm his view point were so energetic that this
theory is quite naturally associated with his name” (Christiansen)
Max Bodenstein (1871 – 1942)
P.S.S.H. has been applied in many areas of
chemical kinetics:
Reactions in gaseous phase
Heterogeneous catalytic reactions
Enzyme reactions
Etc.
New type of eliminating time:
Invariances in dual experiments
• Comparing the temporal trajectories which
are started from the very different initial
conditions (mostly from the symmetrical
ones), there was found a simple
thermodynamic relationship between them at
any moment of time, not only at the final
point.
Reversible reactions
Batch reactor, �
��
���
�
• �� � , �� � from (1,0)
• �� � , �� � from 0,1
Remarkably, ��(�)
��(�)=
��
���= ��� is constant!
ℒ�� � =��
�� + �� + ��� �ℒ�� � =
���
�� + �� + ��� �
Yablonsky, G.S., Constales, D., Marin, G.B. Equilibrium relationships for non-equilibrium chemical dependencies. Chem. Eng. Sci. 66 (1) 111-114 (2011).
I. STOP TIME !
Founders of infinitesimal calculus:
Newton and Leibnitz
Calculus’ foundation: Cavalieri is a
precursor of infinitesimal calculus
In Europe, the foundational work was a
treatise due to Bonaventura Cavalieri, who
argued that volumes and areas should be
computed as the sums of the volumes and
areas of infinitesimal thin cross-sections
Isaac Newton (1642-1727)
Gottfried Wilhelm Leibnitz (1646-1716)
‘Drop-by-drop’: titration,
determination of the equivalent point
The origins of volumetric analysis are in late-
18th-century French chemistry. Francois
Antoine Henri Descroizilles developed the first
burette (which looked more like a graduated
cylinder) in 1791. Joseph Louis Gay-Lussac
developed an improved version of the burette
that included a side arm, and coined the terms
"pipette" and "burette" in an 1824 paper on
the standardization of indigo solutions
Manfred Eigen (1927):
Chemical relaxation, but not calculus
Experimental calculus in chemistry:
John T. Gleaves
• Temporal Analysis of Products (TAP),
a vacuum transient response experiment
performed by injecting a small number of gas
molecules into an evacuated reactor
containing a solid sample, which provides
precise kinetic characterization of gas- solid
interactions with submillisecond time
resolution (developed by J.T. Gleaves in 1988)
96
G.B. Marin & G.S. Yablonsky
(2011). Kinetics of Chemical
Reactions. Decoding
Complexity
Non-Steady-State Kinetic Screening
TAP: Temporal Analysis of Products
• Series of pulses of very small intensity
• Change of catalyst composition in controlled manner
• Sequence of infinitesimal steps produces a finite change → “chemical calculus”
TC
Pulse valve
Microreactor
Mass spectrometer
Catalyst
Vacuum (10-8 torr)
Reactantmixture
0.0 time (s) 0.5
Exi
t fl
ow
(F A
)
Inert
Reactant
Product
Continuous flow valve
TAP Reactor System-Overview
Thin-zone and Single Particle Reactor
Configurations
Thin-zone
Single-particle
Small number of pulses
Insignificant change
0.0
State-defining Experiment
State-Defining & State-Altering Experiment
Inert Reactant Product
Large number of pulses0.0
State-altering Experiment
TAP Multipulse Experiment Combines
Principles of the TAP-experiment
• 3 principles:
• (1) Insignificant change of catalyst composition during the single pulse
• (2) Controlled change of catalyst composition during the series of pulses
• (3) Uniformity of the active zone regarding the composition
=========
And… Transport is well-defined: Knudsen diffusion
• Interrogative kinetics, a systematic approach
combining small stepwise changes in catalyst
surface composition with precise kinetic
characterization after each change to
elucidate the evolution of catalyst properties
and provide information on the relationship
between surface composition and kinetic
properties. (developed by J.T. Gleaves and G.
Yablonsky in 1997)
The main idea is to combine two types of experiments:
Was firstly introduced in the paper:
Gleaves, J.T., Yablonskii, G.S., Phanawadee, Ph., Schuurman, Y. “TAP-2: An Interrogative Kinetics Approach” Appl. Catal., A: General, 160 (1997) 55.
A state-defining experiment in which the catalyst composition and structure change insignificantly during a kinetic test
A state-altering experiment in which the catalyst composition is changed in a controlled manner
Interrogative Kinetics (IK) Approach
ER+OAP
Step 2: Decision tree in determining mechanisms
for oxygen pre-covered surface
Testing rates
Legend:
ER - Eley-Rideal
LH - Langmuir-Hinshelwood
OAP -Oxygen Additional Process
Buffer - spectator CO
Testing parameters
TAP-results
• About 20 machines working in the world
• About 10 research groups
US-St. Louis, Houston
Europe – Belgium, Ghent;
Netherlands, Delft ; N. Ireland, UK, Belfast;
Germany – Ulm, Rostock, Bohum;
France –Lyon; Spain; Switzerland –Zuerich;
Asia- Japan – Tokyo, Toyota City;
Thailand – Bangkok.
Many catalytic reactions: oxidation of simple molecules, many reactions of complete and selective oxidation of hydrocarbons
105
G.B. Marin & G.S. Yablonsky
(2011). Kinetics of Chemical
Reactions. Decoding
Complexity
• Automotive catalytic processes
• Reverse-flow processes
• Oxidation-reduction processes for selective hydrocarbon oxidation
• Circulating fluidized-bed reactors
• Chemical looping combustion (CLC)
(total oxidation of hydrocarbons by metal oxides)
Non-Steady-State Catalytic Processes
Difference from the Faust’s strategy
In chemical time studies, we would like to stop any moment of time, not just the beautiful one.
• J. Temporal Patterns of Complex Mechanisms
G.B. Marin & G.S. Yablonsky (2011).
Kinetics of Chemical Reactions. Decoding
Complexity
108
Parallel versus Consecutive Reactions
time t
con
cen
tra
tio
ns
cA cB
cC
con
cen
tra
tio
ns
time t
cA
cB
cC
A B C
k1 k2A
B
C
k1
k2
cB,max
tmax
• Non-linear phenomena:
• Ignition, Extinction, Oscillations, Chaos
110
G.B. Marin & G.S. Yablonsky
(2011). Kinetics of Chemical
Reactions. Decoding
Complexity
Relaxation Characteristics
Critical slowing down causes a dramatic increase in the time to
achieve steady state:
pB (Pa)
τss (s)
111
G.B. Marin & G.S. Yablonsky
(2011). Kinetics of Chemical
Reactions. Decoding
Complexity
Other Catalytic Oscillators
Mechanism for CO oxidation by Vishnevskii and Savchenko
states of metal surface
A B C
A B
C
t (h)
bursts
• In catalysis, all these phenomena are
explained using mechanism of competition
• between different species, in particular
different species adsorbed over the catalyst
K. Time of Events.
Events and Coincidences in
Chemical Kinetics
What are events in history and social
life ?
• The Berlin Wall comes down
• Abdication of the Spanish King
• Annexation of Crimea by Russia
• Prince William marries Kate Middleton
What are events in chemical kinetics?
• Concentration peak
• Rate peak
• Intersection of concentration dependences
• Ignition or extinction
• Oscillations
• Etc…Etc…
Coincidences: two or more events at the same time (D.Constales, G. Yablonsky, G. Marin, 2010-2013)
• Surprising properties of the simple kinetic
models; in particular, A->B->C.
Coincidences (cont’d)
• Solutions
Coincidences (cont’d)
• Acme, k2=k1/2
Coincidences (cont’d)
• Triple Intersection: Lambert point,
k2=1.1739… k1
Coincidences (cont’d)
• Inspecting the peculiarities of the
experimental data, we may immediately infer
the domain of the parameters.
• Intersections, extrema and their ordering are
an important source of as yet unexploited
information.
Concidences and Events for two-step consective reaction
(Constales, Yablonsky, Marin, Chem. Eng. Sci., 2012)
Felix de Boeck, Abstract Composition
(1919)
• M . History of Chemical Time
124
G.B. Marin & G.S. Yablonsky (2011). Kinetics of Chemical
Reactions. Decoding Complexity
History of Chemical Kinetics
1810s –1820s
Catalysis discovered DöbereinerDavy
1830s Catalysis distinguished as a special phenomenon
Berzelius
1860s Mass-action law Guldberg & Waage
1880s –1890s
Natural classification of reactionsCatalysis is purely kinetic phenomenonPrinciple of independence of reactionsConcept of reaction mechanism
Van ‘t HoffOstwald
OstwaldSchönbein
125
G.B. Marin & G.S. Yablonsky (2011). Kinetics of Chemical
Reactions. Decoding Complexity
History of Chemical Kinetics
1900s –1910s
“Wegscheider’s paradox”
Discovery of chain reactions
Catalytic cycle
Quasi-steady-state hypothesis
Catalysis occurs on surface
Wegscheider
Bodenstein
Christiansen
Chapman Bodenstein
Langmuir
1920s –1930s
Discovery of branching chain reactions
Concept of active catalyst sites
Discoveries in enzyme adaptation and bacterial genetics
Theory of absolute reaction rates
Onsager reciprocal relationships
Semenov Hinshelwood
Taylor
Monod
Eyring, Evans, Polyani
Onsager
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Reactions. Decoding Complexity
• Precise characterization of catalyst activity
through kinetic experiments
• Development of theory that allows
decoding the chemical complexity
– Heterogeneous catalysis: Horiuti, Boreskov,
Temkin
– Enzyme catalysis: King & Altman, Volkenstein &
Goldstein
Trends in Chemical Kinetics (> 1940s)
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Reactions. Decoding Complexity
History of Chemical Kinetics
1950s –1960s
Analysis of multi-step catalytic reactionsDiscovery of oscillating reactions
Christiansen
Belousov Zhabatinsky
1970s –1980s
Concept of turnover frequencyModels for thermodynamics of irreversible processes
BoudartPrigogine
1980s –1990s
Novel observation techniques in kinetic studiesDensity functional theory
Ertl
Kohn
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G.B. Marin & G.S. Yablonsky (2011). Kinetics of Chemical
Reactions. Decoding Complexity
NOBEL AWARDS IN KINETICS
Van ‘t Hoff (1901), Chemistry
Arrhenius (1903), Chemistry
Ostwald (1909), Chemistry
Langmuir (1932), Chemistry
Hinshelwood & Semenov (1956)
Monod (1965), Physiology or Medicine
Eigen (1967), Chemistry
“Kinetic Nobel Prize Winners”
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Reactions. Decoding Complexity
Onsager (1968), Chemistry
Prigogine (1977), Chemistry
Herschbach, Lee & Polanyi (1986), Chemistry
Ertl (2007), Chemistry
Karplus, Lewitt & Warshel (2013), Chemistry
“Kinetic Nobel Prize Winners”
L. Revisited list of different meanings
of chemical time
1. “Clock” time t , or astronomic time, or ‘external’ time.
2. “Transport time” as a measuring stick of the
chemical process
3. “Internal”, or “intrinsic” chemical time (s).
A. Intrinsic times of separate reactions.
B. ‘Cyclic’ time of the catalytic cycle.
4. Times of Events (Moments of Events)
New Trends
RATE–REACTIVITYMODEL
HOW TO PRECISELY CHARACTERIZE ACTIVITY
OF SOLID MATERIAL ?
• Using the Rate-Reactivity Model one can
characterize an ability of the solid material to
transform one substance into another
substance
Insignificant chemical perturbation of
the solid material
• Reaction Rate determines the ‘Future State’
• Instantaneous Gas Concentration determines
the ‘Present State’
• ‘Integral Gas Change’ (Uptake-Release)
estimates a Composition of Solid Material
which is determined by the ‘Past’ (History of
material)
Chemical time
• Rate =
function ( Instantaneous concentration,
Integral chemical change)
• Future = function (Present, Past)
N. Interdisciplinary influence
of ‘chemical time’ studies
• Radioactive decay
• From chemical chain reactions to chemical nuclear chain reactions
• Understanding bioprocesses based on models of chemical kinetics
• Ecological models, in particular Lotka-Volterra model
• Psychology
• Sex behavior
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G.B. Marin & G.S. Yablonsky
(2011). Kinetics of Chemical
Reactions. Decoding
Complexity
Oscillators
Lotka-Volterra or predator-prey equations
( )dxx y
dt= α − β
( )dyy x
dt= γ − δ
x is number of some prey (rabbits), y is
number of some predator (foxes), α, β, γand δ are parameters
Curious example
• Otto Weininger “Sex and Character, Principal Investigation” (6th edition, 1914):
• “The law of sexual affinity has many similarities with one known law of theoretical chemistry…It is close to the phenomena associated with the law of mass action”…His final conclusion is: “It is quite evident what I mean: sexual attraction of two individuals being together for a long time or saying it better, locked together, can evolve even when they first had an aversion to one another, which is similar to a chemical process that needs much time until it becomes observable”.”
Interesting questions from psychology
• Why fear and isolation can affect our
perception of the speed of time?
• Why time speeds up as you get older?
• Etc… Etc..
Prof. Hudson Hoagland, his wife and his student. I
• Hudson Hoagland (1899-1982) was a Professor of General Physiology and Chairman of the Biology Department of Clark University, 1931-1944.
• “In 1932… my wife fell ill with influenza and developed a temperature one afternoon of nearly 104 F (40.0 C) She had asked me to an errand something at the drugstore, and, although I was gone only twenty minutes, she insisted that I must have been away much longer. Since she is a patient lady, this immediately set me to thinking along the lines just indicated and then hurrying to find a stop watch. I then, without telling her why, asked my wife to count to sixty at a speed she believed to be one per second. As a trained musician, she had a good sense of short intervals”.
Prof. Hudson Hoagland, his wife and his student. II
• “She repeated this count 25 times in the course of her illness, her speed of counting was measured with a stop watch, and her temperature was recorded each time. She unknowingly counted faster at higher at lower temperatures” (“Voices of Time”, 1981)
• Prof. Hoagland found the corresponding temperature dependence (so called Arrhenius dependence) and determined – in style of chemical kinetics-
• Energy of activation = 24, 000 cal/mol• His explanation: it was caused by some group of cells in the brain
(‘chemical clock’). • Hoagland’s speculation:
chemical pacemaker involves oxidative metabolism
Prof. Hudson Hoagland, his wife and his student. III
“In the next experiment Hoagland convinced his student to submit diathermy – that is for his body to be wrapped tightly and then artificially raised to 38.8 C using an electric current. Bearing in mind that a body temperature of 40 C degrees would be considered potentially life-threatening emergency, the student was surprisingly rather anxious, which Hoagland remarked rendered his initial time estimations somewhat erratic. Once the student had managed to relax, his perception of time were altered in the same way they were for Hoagland’s wife” – in accordance with “Time Warped” by Claudia Hammond, 1982
Prof. Hudson Hoagland, his wife and his student. IV
Prof. Hoagland tested just two people , and the result was the same: Energy of activation was bigger than 20, 000 cal/molKeith Leidler said: “I f the energy barrier for a process is greater than about 5
kcal/mole it is almost certain that chemical processes,
involving the breaking of primary chemical bonds, are
involved. ..It is therefore extremely likely that all of the
processes mentioned above (creeping of ants, flashing offireflies,
chirping of tree crickets including the psychological ones), are
essentially chemical ones”.
• O. General Scientific, Philosophical and
Religious Aspects
Time and Relativity
• Newton and Einstein.
• Newton needed absolute time and absolute
space in order to express his laws.
Einshtein’s Time in Relativity
• “Before one can begin to understand the effect of relativity theory on our notions of time, it is necessary to realize that the theory is concerned solely with the relation between the times assigned to events at different places and with the variation of those times with a state of motion which the observer ascribes to himself and his measuring instruments. This disposes of number of mistaken ideas which have served, not only to make the theory appear unnecessary mysterious, but also to give it an entirely false aspect” (Herbert Dingle, president of the Royal Astronomic Society)
‘Time is gone’
• Nevertheless, some philosophers after Einstein tried to completely eliminate time from the scientific picture of the World.
• “We have learned that we live in four-dimensional and not a three-dimensional world, and that space and time –or, better, space-like separations and time-like separations – are just two aspects of a single four-dimensional continuum…Indeed, I don’t believe that there are any longer any philosophical problems about Time” (Henry Putnam, 1969)
Time is Regained
• See “Time is Reborn: From the Crisis in Physics
to the Future of the Universe” by the Lee
Smolin, Houghton Mifflin Harcourt, 2013
Chemical Time
• Specific features of traditional Chemical Time:
• (1) It is the LOCAL TIME
• (2) It is always a combination of the
• ‘PAST’, ‘PRESENT’ and ‘FUTURE’
Ecclesiastes.4 MEANINGS OF TIME
(1) CYCLIC TIME
“The sun rises and the sun sets,
and hurries back to where it rises.
The wind blows to the south
and turns to the north…
Whatever is has already been,
and what will be has been before”
ECCLISIASTES. 4 MEANINGS OF TIME.
(2) LINEAR TIME
• «All go to the same place»
• “…the day of death better than the day of
birth”
ECCLISUASTES. 4 MEANINGS OF TIME.
(3) MOMENT
• 7 Go, eat your food with gladness, and drink your
wine with a joyful heart, for God has already
approved what you do. 8 Always be clothed in white,
and always anoint your head with oil. 9 Enjoy life
with your wife, whom you love, all the days of this
meaningless life that God has given you under the
sun—all your meaningless days.
ECCLISIASTES. 4 MEANINGS OF TIME
(4) TIME OF EVENTS• 3 meanings of time
• There is a time for everything,and a season for every activity under the heavens:
• 2 a time to be born and a time to die,a time to plant and a time to uproot,3 a time to kill and a time to heal,a time to tear down and a time to build,4 a time to weep and a time to laugh,a time to mourn and a time to dance,5 a time to scatter stones and a time to gather them,a time to embrace and a time to refrain from embracing,6 a time to search and a time to give up,a time to keep and a time to throw away,7 a time to tear and a time to mend,a time to be silent and a time to speak,8 a time to love and a time to hate,a time for war and a time for peace.
• “The main mystery of the world is that it can
be comprehended”
Albert Einstein
• This comprehension gives us an ability to know:
• THE WORLD IS STILL A MYSTERY
Gregory S. Yablonsky
“It has seen further it is by standing on the
shoulders of giants”
(Isaac Newton,
Letter to Robert Hook, February 1676)
Acknowledgements
John Gleaves
Denis Constales
Guy Marin
Prof. John T. Gleaves
Prof. Guy B. Marin
Prof. Denis Constales
THANK YOU
FOR YOUR ATTENTIVE
PATIENCE !
References
(1) G. B. Marin, G. Yablonsky, “ Kinetics of Chemical Reactions. Decoding Complexity”.
Wiley-VCH, 2011
(2) G. Yablonskii, V. Bykov, A. Gorban, V. Elokhin,
“Kinetic Models of Catalytic Reactions”, Elsevier, 1991
(3) “Voices of Time, A Cooperative Survey of Man’s View of Time as Expressed by the Sciences and by the Humanities”, the second edition, editor J.T. Fraser, 1981
(4) C. Hammond, “Time Warped. Unlocking Mysteries of Time Perception”, 2012
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