and Co(III) Complexes on Synthetic Birnessite: Surface Characterization

24 Interaction of Co(II) and Co(III) Complexes on Synthetic Birnessite: Surface Characterization John G. Dillard and Catherine V. Schenck

Downloaded by UNIV OF ARIZONA on December 20, 2012 | http://pubs.acs.org Publication Date: November 13, 1987 | doi: 10.1021/bk-1987-0323.ch024

Department of Chemistry, Virginia Polytechnic Institute and State University, Blacksburg, VA 24061 2+

The interaction of Co(HO) and Co(III) complexes;Co(NH ) Co(en) ,(en= NHCHCHNH)withsynthetic birnessite has been studied as a function of pH. The chemical nature of the birnessite sample surface was characterized using X-ray photoelectron spectroscopy (XPS) and secondary ion mass spectrometry (SIMS). Sorption of Co(HO) on birnessite in the pH range 4-7 2

3+

3 6

2

2

2

6

3+

3

2

2+

2

6

results in the oxidation of Co(II) to Co(III) as shown by XPS results. Interaction of the Co(III) complexes with the birnessite surface occurs by loss of coordinated ligand, yielding Co(II) and Co(III) species from Co(NH ) , while Co(III) is the dominant cobalt state following the reaction of Co(en) with birnessite. 3+

3

6

3+

3

The i n t e r a c t i o n and sorption of metal ions with metal oxide and clay surfaces has occupied the attention of chemists, s o i l s c i e n t i s t s , and geochemists for decades ( 1 - 4 ) . T r a n s i t i o n metal oxides receiving particular emphasis have included various oxides of manganese and iron (5). Interest i n sorption phenomena i s promoted by the desire to better understand incorporation of metals into minerals, especially marine deposits (5), the removal of trace metal pollutants and radionuclides from r i v e r s and streams, v i a sorption and/or p r e c i p i t a t i o n phenomena (1,6), and the deposition of metals on s o l i d substrates i n the preparation of catalysts (7,8). An important and s i g n i f i c a n t task i n sorption studies i s the e f f o r t to i d e n t i f y the chemical form(s) of the sorbed metal ion. 0097-6156/86/0323-0503S06.00/0 © 1986 American Chemical Society

In Geochemical Processes at Mineral Surfaces; Davis, J., et al.; ACS Symposium Series; American Chemical Society: Washington, DC, 1987.

504

G E O C H E M I C A L PROCESSES AT M I N E R A L SURFACES

Among the

the

questions

metal

present

conditions

of

was

present, to

what

importance

that

(13).

published

(14,15).

formed

that

of

with

that

at

of

at

the

of

a

of

similar

it

was

the

about

reasoned oxide

studied

result

by

that

attributed

of

of

cobalt that

studied

cobalt(II)

surface

and of

thermodynamic In

the

(19).

was

the

for

study

birnessite

following

of

cobalt(II)

and

pH

has

spectroscopic

techniques,

and

i o n mass

secondary

contribution

that

such

information

obtained

metal

and

within

oxide about

the

surface

of

two

X-ray

an

metal

50 Â

of

the

all

methyl

dioxide

of

the of

indicated

anoxic

the

birnessite

illustrate the

rates

of as

the

state

the

or

importance.

birnessite

aqueous

complexes

In

birnessite

under

with

a

and

solutions

function

of

sensitive

(SIMS). can

chemical

material

the

was

geochemical

oxide/metal the

of

in

methyl

was

results

chemistry

investigation

the

been

form

nature

on

surface

on

has

oxidation

photoelectron

spectrometry

regarding

the

top

amine

using

the

of

yield

Fe(III)

ions

on

studies

interaction

cobalt(III)

investigated

ions

influencing

reactions

the the

These

to

dioxide

yield

Co(II)

present

the The

intermediates.

cobalt(III)

in

on

on manganese

and

by

(17).

process

these

tin

it by

thermodynamically,

Sn(IV)

analysis

was

surfaces

of

been

to

found

importance the

the

sheets.

Mn(II)

the

of

In (16),

sites.

manganese

surface

Surface

Mn(III)

stability

present

of

the

was

to

and

methyl

solution on

active

tin(IV)

Sn(II)

reaction.

mineral

of

diminished

oxidized

surface

following

importance

in

chemistry

pH

controlled

oxidized

of

Sn(II)

of

of

presumably

favored

role

adsorption

dissolved

surface

were

the

not

is

state

(hausmanite)

processes

was

oxide

reduced

particular

of

solid

0 ^

3

function

rate

production

formation

n

experiments.

surface

was

that

M

been

MnO^ o c t a h e d r a l

methyl

Of

adsorption

oxygen

conditions

found

the

of

the

kinetics

and

decreased

investigation

role

tin(II)

the

a

slower

The

The

prevented

manganese

the

slow.

initial

the

of

have

oxidation

of

on

concentrating

strategic

was

oxidation

in a

As(III)

manganese d i o x i d e to

of

oxidation

that

was

from

processes

the

as

Mn(IV)

transfer.

3

of

compound

of

in

and

Mn(II)

manganese(IV)

an

too

It CH

species.

which an

(17)

are

(18).

ions

tin

such

is

complex?

part

variety role

further

at

the

conditions

methylation

tin

with

19% o f

Although

Fe(III)

that

FeOOH p r e c i p i t a t e

As(III)

Under

or

vacancies

formation with

sorbed in

conditions

of

rate

pH>4 p r o c e e d e d

reaction

a

formation of

birnessite

at

oxide.

the

conditions

Reactions

As(V)

the

economic

noted

pH