The geology of Hong Kong is dominated by volcanic and intrusive
rocks that belong to an extensive Mesozoic magmatic
province along the continental margin of southeastern
China. Volcanic rocks alone account for approximately
50% of Hong Kong's surface area (Figure
5.1), and form most of its mountainous ground. They
comprise thick successions of tuff (pyroclastic rocks)
with generally more minor lava flows. The volcanic rocks
can be related in terms of their age, chemistry, petrography
and structural control of distribution, to the subvolcanic
plutonic (mainly granitic) rocks (Chapter
6). Interbedded sedimentary rocks of widely ranging
grain size vary from dominantly volcaniclastic to epiclastic
origin.
The intermediate to silicic character of this magmatism has resulted
in a particularly complex volcanic–plutonic stratigraphy.
In order to establish the sequence of magmatic events,
it has been necessary to combine the results of field
mapping with whole-rock geochemistry, precise radiometric
dating and detailed petrographic studies. These studies
have enabled a comprehensive revision of the volcanic–plutonic
rock nomenclature for Hong Kong, which is summarized
in Table
5.1.
The volcanic products were erupted in distinct phases during the
Middle and Late Jurassic, and Early Cretaceous. The peak of volcanic
activity occurred during the Late Jurassic and Early Cretaceous
when several large volume eruptions took place within Hong Kong,
mainly from east- and eastnortheast-trending, and to a lesser extent
from northwest-trending fissures. This resulted in the formation
of complex overlapping calderas.
The stratigraphic nomenclature for the volcanic rocks of Hong
Kong has evolved considerably in recent years and these
changes are summarized in Table
5.2. The latest groupings are based largely on high
precision radiometric dating and whole-rock geochemistry
which were not available at the time of earlier surveys,
including that at 1:20 000 scale by the Hong Kong Geological
Survey.
In terms of their physical characteristics, the tuffs
of Hong Kong are classified according to the recommendations
for pyroclastic rocks of the International Union of
Geological Sciences (Schmid,
1981; Le
Maitre, 1989) (Figures
5.2 & 5.3).
However, their compositional classification is based
on whole-rock chemistry, since these rocks commonly
contain extremely fine-grained matrix components (e.g.
fine ash comprising devitrified glass and crystals)
preventing accurate determination of their modal mineralogy.
Whole-rock chemical compositions are determined according to the
widely used total alkali versus silica diagram (Na2O+K2O
vs SiO2) of Le
Maitre (1989) (Figure
5.4).
The volcanic formations comprise lavas, tuffs (pyroclastic rocks),
tuffites (reworked or secondary, mixed pyroclastic and epiclastic
rocks) and sedimentary (epiclastic) rocks.
Lavas
Lavas of various compositions, including andesites, trachydacites,
dacites and rhyolites, make up approximately 15% of the volcanic
succession. Most individual lava flows are typically thick, and
of limited lateral extent, suggesting that they were very viscous.
These characteristics are consistent with the relatively high silica
contents (>65 wt% SiO2) of the lavas.
Rhyolite lavas
Rhyolite lava is the most common lava-type in the volcanic sequences.
Rhyolite lavas have been described in the Shing Mun,
Lai Chi Chong, Ngo Mei Chau, Mang Kung Uk and Clear
Water Bay formations, and within the Lantau Volcanic
Group. They are typically flow banded (Plate
5.1), often flow folded, and locally autobrecciated.
However, some of the units that have been previously
interpreted as rhyolite lavas, are likely to be sills
that were probably intruded relatively near to the surface
at the time of their emplacement, and possibly within
fine-grained sediments that were comparatively unconsolidated.
The most convincing evidence for a sill of this type
is the Sham Chung Rhyolite (Chapter
6). Other possible rhyolite sills occur within the
Lantau Volcanic Group. As much work remains to be done
on differentiating rhyolite lavas from near-surface
sills in Hong Kong, the following description encompasses
both.
The Shing Mun Formation on the south side of Tolo Channel and
the Lai Chi Chong Formation include 35 m-thick flow-banded rhyolites
that are dark grey with an aphanitic matrix and abundant euhedral
quartz (c.2 mm with individual megacrysts up to 7 mm), alkali feldspar
and plagioclase crystals (up to 3 mm). Although generally parallel
to stratification, these thick rhyolites are locally transgressive
and therefore are strongly suspected to be sills rather than lavas.
Rhyolites within the Lantau Volcanic Group are light to dark grey
and typically contain white, euhedral, perthitic, alkali
feldspar (1–5 mm, rarely to 25 mm) and quartz
(1–7 mm) phenocrysts. Recrystallization of feldspar
phenocrysts to quartz–sericite microcrystalline
aggregates is typical and spherulites sometimes occur.
On the flanks of Nei Lak Shan, the rhyolites are unusual
in exhibiting very planar ‘flow’ banding
(Plate
5.2), which is atypical of that in highly viscous
lavas of this composition. Also, the presence of some
shattered crystals is more typical of pyroclastic rocks
than lava flows. There is some doubt therefore that
these outcrops are true lavas. They could instead have
been reconstituted from a hot, welded pyroclastic deposit.
Alternatively, the outcrops may comprise highly silicified,
bedded volcaniclastic rocks. Another notable feature
of several rhyolites shown on the 1:20 000-scale geological
maps is their occurrence, sandwiched between relatively
thin siltstone or fine-grained sandstone units. Examples
on Lantau Island include rhyolites on the southern and
eastern flanks of Sunset Peak, Yi Tung Shan and Lin
Fa Shan. This mode of occurrence may indicate that the
rhyolites are sills rather than lavas, and that they
were intruded preferentially within unconsolidated sedimentary
units.
Autobrecciated, flow-banded spherulitic rhyolite lava occurs in
the Mang Kung Uk Formation. The unit is thickest near Tai Mong Tsai, Clear Water Bay, and thins northwards for c.1.5 km.
The lava flow is thought to have originated from the east-trending,
Tin Ha Shan Fault and vent complex (see below, and Chapter
7).
Autobrecciated rhyolite lava is common in the Clear
Water Bay Formation (Plate
5.3), particularly towards the base of the formation
northeast of Sai Kung. Here, the rhyolite lava sequence
is up to 400 m thick. The unit as a whole can be traced
laterally for up to c.10 km from south to north.
Its northern limit coincides with an easterly-, varying
to northeasterly-trending subvertical, fault-bounded
zone. This zone is nearly 1 km wide and is infilled
with intrusive, flow-banded rhyolites (Plate
5.4) which are similar to the rhyolites within the
Clear Water Bay Formation. The zone extends for more
than 4 km from northeast of Pyramid Hill to Shek Nga
Shan. Beyond there, to the southwest, individual rhyolite
dykes can be traced along the same trend for a further
1.5 km. The fault-bounded zone is interpreted as a major
fissure from which the Clear Water Bay Formation rhyolites
were erupted. The rhyolites within the zone are considered,
therefore, to be the infilling of a wide, fissure-like
vent. They are very fine-grained with few phenocrysts
that are mostly of flow-aligned euhedral feldspars (up
to 3 mm). The matrix is recrystallized to a microlitic
fabric and spherulites are locally developed.
Dacite and trachydacite lavas
Dacite lava has only been mapped in the Sai Lau Kong Formation.
Dacites are also shown on the 1:20 000-scale geological map west
of Tai Mo Shan, within the Yim Tin Tsai and Shing Mun formations.
However, it is almost certain that these are intrusive rocks and
are fine-grained variants of the Tai Po Granodiorite (see Chapter
6).
Trachydacite, transitional to rhyolite lava, occurs in the basal
part of the Pan Long Wan Formation (formerly the Tai Miu Wan Member
of the Clear Water Bay Formation) around Tai Miu Wan on the
Clear Water Bay Peninsula. The unit is up to 150 m thick
and can be traced northwards, gradually diminishing in thickness
towards the coast at Bayside Beach (Pik Sha Wan). It is
bluish grey when fresh, and comprises abundant, characteristically
twinned, plagioclase and alkali feldspar phenocrysts (c.2 mm), and
scattered small quartz phenocrysts, set in a very fine-grained matrix.
Occasional, large, microperthite megacrysts (up to 7 mm) occur,
as do magnetite and pyrite accessory minerals, and secondary chlorite,
sericite and calcite. Finely laminated flow banding is typical and
there is some complex flow folding. The upper parts of the formation
comprise more trachydacite and rhyolite lavas of broadly similar
characteristics. These are interbedded with fine ash tuff of similar
composition. The thickness variations, especially of the basal flow
unit, suggest that the lavas were derived from an easterly-trending
fissure just to the south of Tai Miu Wan. This fissure was one of
the most important and repeatedly reactivated fault controls of
volcanism in the southern part of Hong Kong.
Andesite lava
Andesites are relatively common in the upper part of the Tuen
Mun Formation. The andesites are interpreted as lava flows that
are interbedded with crystal tuff and volcaniclastic sedimentary
rocks. They are dark grey or greenish grey, massive, and are variably
altered and commonly epidotized. The andesite lavas contain abundant
plagioclase phenocrysts (1–3 mm), set in an aphanitic matrix.
Scattered, altered, mafic phenocrysts, probably originally of clinopyroxene
and possibly of hornblende, also occur. The geometry and lateral
extent of individual andesite flows are not readily indentifiable.
This is mainly due to the limited exposure in the vicinity of Tuen
Mun. However, some interbedded lithic-bearing ash crystal tuffs
are observed, particularly in boreholes in the area. A possible
vent source for the formation has been inferred to the north of
Tuen Mun (Langford
et al., 1989).
Pyroclastic rocks
The pyroclastic nature of Hong Kong's volcanic rocks
is evident from a number of field and petrographic features.
The most significant of these is the common occurrence
of welding fabrics (Plate
5.5). These result from the fusing and attenuation
of originally hot glassy fragments (shards and pumice),
manifested by eutaxitic foliation. The foliation is
often emphasised by fiamme (collapsed and commonly altered
pumice; Plate
5.6), and parataxitic foliation (extreme attenuation
of fused pyroclastic debris; Plate
5.7). Other pyroclastic characteristics include:
very high crystal contents, up to and exceeding the
limits (c.55% by volume) at which a magma could
flow (Plate
5.8); fragmentation (during eruption and emplacement)
on a wide range of scales (fine ash to blocks (Plate
5.9), and especially the presence of common angular
broken crystals (Plate
5.10); and poor sorting of the deposits.
Most primary pyroclastic rocks in Hong Kong were probably deposited
from pyroclastic flows, some of which were generated by eruptions
of vast proportions. For example, the High Island Formation alone
comprises >60 km3 of preserved pyroclastic rocks, implying a
considerably greater original eruption volume. Fall deposits are
often suspected but are harder to confirm. Surge deposits have not
yet been confirmed, although some are suspected (see below).
Pyroclastic flow deposits
In Hong Kong, primary pyroclastic flow emplacement of ash deposits
was probably commonplace, but the limitations of exposure make it
difficult to identify complete flow units (especially upper and
lower contact regions). Similarly, there appears to be limited preservation
of the fine ash tuffs that would normally characterise the uppermost
parts of flow units. Pyroclastic flow deposits laid down further
from their source are poorly represented.
Most of the large volume pyroclastic flow deposits are rhyolitic
in composition, but rhyodacites and dacites also occur. These compositional
differences appear to make little difference to the form of the
individual pyroclastic flow deposits.
The most readily defined pyroclastic flow units are generally
eutaxitic, i.e. are welded pyroclastic deposits. Numerous
individual eutaxites, some with unwelded bases and tops,
have been mapped, or are recognisable on a local basis,
within the Lantau Volcanic Group, and the Shing Mun,
Ap Lei Chau, Mount Davis, Mang Kung Uk, Ngo Mei Chau,
Pan Long Wan and High Island formations. Virtually continuous,
widespread eutaxitic sequences, comprising several units
in succession, occur within parts of the Ap Lei Chau,
Che Kwu Shan and High Island formations. Other indications
of the hot emplacement of these rocks include columnar
cooling joints (Plate
5.11), and devitrification features such as perlitic
fracturing and spherulitic recrystallisation. Welding
is known to occur elsewhere in the world within both
pyroclastic flow and fall deposits. However, known examples
of welded airfall deposits are generally no more than
a few metres thick and they extend less than c.5
km from their eruptive source (e.g. Cas
& Wright, 1987 and references therein).
In addition, they exhibit mantling bedforms (see below)
draping pre-existing topography. Many of the eutaxites
in Hong Kong appear too thick (tens of metres) and,
or, too laterally extensive (up to 10 km or more) to
have formed during airfall deposition. Furthermore,
mantling bedforms have not been identified. The eutaxites
are interpreted, therefore, as the products of pyroclastic
flows. In the case of very thick successions of welded
pyroclastic flow deposits, such as comprise the High
Island Formation, the sequence probably represents several
flow units deposited within a sufficiently short time
in order for the whole sequence to have behaved as a
single cooling unit.
Possible unwelded pyroclastic flow units occur within the Lai
Chi Chong Formation. Other examples, typically of coarse
ash crystal tuffs varying to fine ash vitric tuffs,
occur within the Yim Tin Tsai, Shing Mun, Tai Mo Shan,
Long Harbour and Mount Davis formations. The units within
the Lai Chi Chong Formation have been mapped as coarse
ash tuffs, but include block-bearing and lapilli-rich
units, often with abundant locally derived sedimentary
rock clasts (Plate
5.12). These demonstrate many features of rapid
emplacement, including loading at the bases of flow
units, flame structures, and complex soft sediment deformation
of the substrate. Normal grading and capping with fine
ash tuff are also typical. However, all of these features
could equally occur within a sediment gravity flow deposit
mainly comprising volcaniclastic debris that has been
redistributed. In the absence of evidence for emplacement
while the volcaniclastic debris was still hot, the primary
pyroclastic nature of such units remains uncertain.
Block-rich megabreccias, with blocks up to several metres or more
across, and with pyroclastic matrices, are seen locally, within
the Shing Mun, Lai Chi Chong, Long Harbour, Ap Lei Chau, Mount Davis,
Che Kwu Shan, Mang Kung Uk and Pan Long Wan formations. These represent
proximal pyroclastic facies, in some instances ponded within structurally
discordant vent structures.
Other features typical of both welded and unwelded pyroclastic
flow deposits in Hong Kong, but seen more sporadically, include:
preferred concentrations of lithics, crystals, and blocks towards
the bases of units due to sorting during flow; indistinct and discontinuous
bedding within flow units related to subflow units or internal shearing
within flows; fine ash accumulation towards the tops of units reflecting
fallout of ash; and coarse tuff breccias with variably developed
normal grading of blocks contained within a volcaniclastic matrix.
Some breccias of this type may be the infillings of vents, but stratified
tuff breccias occur within the Lantau Volcanic Group, and the Shing
Mun, Tai Mo Shan, Ap Lei Chau, Mount Davis, Long Harbour, Che Kwu
Shan, Mang Kung Uk and Pan Long Wan formations.
Pyroclastic fall deposits
Identifying pyroclastic fall deposits in volcanic rock sequences
depends to a large degree on establishing a laterally continuous,
mantling style of geometry. This requires very good exposure over
a wide area. As a result, it is generally difficult to identify
pyroclastic fall deposits in ancient volcanic sequences. In subaerial
volcanic environments, preservation of pyroclastic fall deposits
is generally poor because the deposits are easily eroded. However,
in subaqueous environments, particularly within well stratified
lacustrine and alluvial sequences, these deposits have a much greater
likelihood of preservation.
In Hong Kong, possible pyroclastic fall deposits include
finely laminated, white to light grey and orangish brown,
very fine to fine ash vitric tuffs with variable crystal
components. Their thickness lies on a scale of millimetres
to hundreds of millimetres. Pyroclastic fall deposits
have been interpreted in many formations in Hong Kong,
and most commonly within the Shing Mun, Lai Chi Chong,
and Mang Kung Uk formations (Plate
5.13). Within the Pak Kok Member of the Lantau Volcanic
Group, and in the Lai Chi Chong Formation, the tuffs
are interbedded with fossiliferous grey to dark grey
epiclastic sandstones, siltstones and mudstones, indicating
repeated deposition of tuffs in a lacustrine environment.
However, some of these could have been deposited from
turbidites or have formed in other ways. A further possible
indication of airfall deposition is the preservation
of accretionary lapilli, for example in the Shing Mun
Formation (formerly the lower part of the Lai Chi Chong
Formation) on the south side of Tolo Channel (Strange
et al., 1990). However, accretionary
lapilli (Plate
5.14) can also form in pyroclastic surge deposits
and their association with cross-bedded tuffaceous sandstones
could be consistent with this. Accretionary lapilli
have also been observed locally in the Mang Kung Uk
Formation on the east side of Junk Bay.
Secondary volcaniclastic rocks
The distinction between volcaniclastic rocks that are primary, i.e
were laid down directly following a volcanic eruption, and secondary,
i.e. comprise volcaniclastic material that has been reworked by
sedimentary processes, is often difficult, even in recent volcanic
environments. In many rocks there are no absolutely diagnostic criteria
of the emplacement process. This is particularly the case where
there are no indications of emplacement of hot pyroclasts. Therefore,
many of the tuff sequences are likely to include secondary volcaniclastic
deposits, emplaced by mass flow, mass wasting, and fluvial and alluvial
processes. This is especially the case in mixed volcaniclastic and
epiclastic sequences such as in the Shing Mun, Lai Chi Chong, and
Mang Kung Uk formations. Where there are substantial mixtures of
volcaniclastic and epiclastic debris, (>25% of both) the rocks
are termed tuffites. These have been identified and mapped locally.
Where there is less than 25% of volcaniclastic material, the rocks
are regarded as being essentially sedimentary, i.e. epiclastic,
in origin. Rocks of this type occur in a wide range of grain sizes,
including boulder- and cobble-bearing conglomerates and breccias,
conglomerates, sandstones, siltstones and mudstones.
Textural characteristics of pyroclasts
Glass and pumice fragments
The vitric component of the tuffs comprises two main size ranges:
fine ash, varying to very fine ash and to a lesser extent coarse
ash, and lapilli- varying to block-sized fragments. Vitroclastic
forms are often evident in the finer fraction. Originally, these
would have been shards of volcanic glass resulting from rapid chilling
and extreme fragmentation of an originally highly vesiculose magma.
Commonly, the shards became fused together and attenuated (drawn
out during welding) as a result of compaction after deposition.
Pumice, ranging up to block size, formed from fragments of highly
vesiculose magma, chilled to glass. The pumice contains a variable
component of crystals, formed prior to the eruption. The pumice
fragments commonly collapsed during compactional welding to form
fiamme. Subsequently, however, all of the glass has undergone devitrification
and recrystallization leaving microcrystalline mosaics of quartz
and feldspar and their alteration products. Textural features associated
with early stages of devitrification include perlitic fractures
and spherulites.
Crystals
Crystals vary in size from fine ash to lapilli. They may comprise
up to c.80% of some tuffs, but typically are
c.30% by volume. Most crystals are either isolated
pyroclasts separated from the parent magma during eruption
and emplacement, or are compounded within larger, variably
vesiculose clasts of the parental magma (i.e. cognate
lithics). Crystals can also occur within accidental
or accessory lithic clasts (see below). In many tuffs,
the isolated crystal pyroclasts have been physically
broken before incorporation into the rock. Disintegration
probably occurred during explosive eruption, and only
to a limited extent during pyroclastic flow. Resorption
of crystals is shown by their embayed margins and hollow
forms (Plate
5.15). This was caused by disequilibrium between
the crystals in their host magma as a result of the
change in physical and chemical conditions as the magma
ascended rapidly through the crust before and during
eruption.
Lithic fragments
Lithic fragments are very variable in size, ranging from ash to
very large blocks. They are a relatively minor component in many
of the tuffs but lithic tuffs are not uncommon. Cognate, accessory
and accidental lithic fragments are represented.
Cognate lithics are primary fragments of the erupted magmas and
include variably vesiculose (pumiceous) to non-vesiculose
(magmatic) fragments of parental rhyolite, rhyodacite
and dacite magma in most rocks. However, in classifying
tuffs (Figure
5.2), pumice fragments are regarded as a glass component
rather than a lithic component.
Accessory lithics, torn from the country rock in the
sides of the vents during eruption, vary from common
to sporadic in most pyroclastic units. The best examples
of accessory lithics are blocks, up to 200 mm in size,
comprising coarse ash tuffs, eutaxites and occasionally
granites within tuff breccias in the Shing Mun and Che
Kwu Shan formations and the Lantau Volcanic Group. Marble
clasts are an important and locally abundant accessory
lithic component in the Tuen Mun Formation. This suggests
that marble is more widespread at depth beneath the
New Territories than is apparent from the local areas
of marble subcrop proven to date (see Chapter
3). Marble clasts also occur in the Shing Mun Formation.
Accidental lithics, incorporated during emplacement of pyroclastic
deposits, include siltstone and mudstone especially towards the
bases of coarse ash tuffs in the Lai Chi Chong Formation.
Matrix
The volcanic matrices typically comprise microcrystalline aggregates
of quartz, feldspar, sericite, chlorite, Fe-oxides and calcite.
They represent the devitrified and variably recrystallized very
fine ash component of eruptions. Where the matrix was originally
a compact glass, perlitic fracturing and spherulites can be seen.
Welding is the most commonly observed fabric within
the volcanic rocks. It is manifested by fused, attenuated,
and consequently aligned shards. They were originally
glass in composition, but subsequently they became devitrified
and recrystallized. Typically, the welding fabric is
referred to as eutaxitic foliation (Plate
5.6), but in extreme examples of attenuation, as
in the Tai Tun Member of the Clear Water Bay Formation,
the fabric is described as parataxitic foliation (Plate
5.7). Eutaxitic fabrics are visible in hand specimen,
especially in weathered rock, as well as in thin section.
Fiamme are usually the most obvious indication of welding
in natural exposures. They are variably pumiceous (vesiculose)
fragments of coarse ash to block size that have collapsed
or have been flattened and attenuated parallel to the
welding fabric. The fiamme are often preferentially
chloritized, in which case their dark green colour contrasts
strongly with the grey tones of the host rock. In other
instances they may be extensively kaolinized, carbonatized
or preferentially silicified. In the former two cases
they weather preferentially to form depressions on exposed
surfaces, whereas in the lattermost case they resist
erosion and stand proud on weathered surfaces. Well-exposed
examples of fiamme occur in the Shing Mun, Ngo Mei Chau,
Ap Lei Chau, Long Harbour, Che Kwu Shan, Clear Water
Bay and High Island formations. Discrete units of welded
tuff with fiamme are classified as eutaxite. Absence
of fiamme, however, does not preclude welding of a pyroclastic
unit. Although fine-scale welding fabrics may be determined
in hand specimen, they are best confirmed in thin section
(Plates
5.5 & 5.15).
Remobilisation, or continued movement during emplacement of the
welded tuffs has sometimes resulted in locally complex
secondary flow structures, including disharmonic folds
and thrusts (Plate
5.16). These are categorized under the general heading
of rheomorphism. Although rheomorphic structures can
be used to infer the topography at the time of emplacement
of the tuff, no such studies have been carried out in
Hong Kong.
Deformational fabrics
Deformation fabrics occur sporadically in most volcanic formations.
These are generally restricted to discrete and narrow zones of shearing
that caused broadly parallel alignment of clay minerals, mainly
chlorite and sericite, and of tabular crystals, including feldspars
and biotite. In northwestern parts of Hong Kong, however, these
deformation zones can be tens and even hundreds of metres wide,
and are sufficiently distinct to be shown on the 1:20 000-scale
geological maps. Care must be taken in distinguishing between primary
compactional fabrics in tuffs, and secondary tectonic deformational
features.
Detailed accounts of the lithological characteristics of individual
formations at specific locations are contained in the
six memoirs, which accompany the 1:20 000-scale geological
maps, and these need not be repeated here. However,
general descriptions are given below for all lithostratigraphic
units. Emphasis is placed on synthesising the available
information into a coherent geological model. Generalized
vertical sections of the volcanic stratigraphy exposed
in various parts of Hong Kong are given in Figure
5.5.
Evidence of what is thought to be the earliest Jurassic volcanism
is preserved only in northwestern parts of Hong Kong
and comprises andesitic lavas and tuffs of the Tuen
Mun Formation. With the exception of this formation,
all other volcanic formations are now assigned to one
of four revised and newly defined volcanic groups (Campbell
& Sewell, 1998). These are based on the
ages and chemical compositions of the different volcanic
phases (Table
5.3) in addition to their broad lithological characteristics
and stratigraphy. Collectively, these groups record
predominantly pyroclastic volcanism during the Middle
Jurassic to Early Cretaceous. Each of the volcanic groups
has an equivalent intrusive granitoid suite of similar
age and composition (see below).
Stratigraphic correlation based on geochemistry
Many workers have cautioned against regarding the bulk composition
of pyroclastic rocks, especially those in ancient sequences, as
an indication of their parental magma composition (Ui,
1971; Walker,
1972; Cas
& Wright, 1987) because several factors may affect
the bulk chemistry. These include the potential for a large accidental
lithic component, the common effects of alteration after deposition
(e.g. vapour phase crystallization, fumarolic activity, ground water
leaching). Sorting during eruption, transport and deposition of
the volcaniclastic fragments also typically results in differential
concentrations and depletions of crystals and glass in volcanic
deposits. Under certain circumstances, however, bulk rock chemistry
may be of value in correlating pyroclastic rocks if used in conjunction
with detailed mapping and petrographic observations (e.g. Howells
et al., 1991). In such studies, pyroclastic
units forming thick sequences of homogenous tuff within calderas
have been shown to have relatively consistent geochemical signatures
(e.g. certain major and trace element ratios). Laterally extensive
fine ash vitric tuffs, and tuffs lacking a significant lithic component,
may also exhibit similar geochemical coherence. To limit the influence
of alteration processes affecting bulk rock chemistry, greater reliance
can be placed on those elements that are relatively immobile under
many conditions of alteration.
During the ten-year period of the 1:20 000-scale geological mapping
of Hong Kong, the need for modifications to the lithostratigraphy
became apparent. Some of these changes were incorporated
in later published 1:20 000-scale maps in the series
while others have been included in the 1:100 000-scale
geological map accompanying the Pre-Quaternary Geology
of Hong Kong (Sewell
et al., 2000). In part, these stratigraphic
refinements have been based on analysis of a comprehensive
whole-rock geochemical database. This became available
only after most of the 1:20 000-scale maps had been
published. The most significant adjustments have resulted
from the ability to discriminate geochemically between
some of the coarse ash crystal tuffs, which otherwise
lack diagnostic lithological characteristics. The most
useful geochemical signatures in this regard have proved
to be those based on ratios of relatively immobile elements,
most notably Ti (expressed conveniently as wt% TiO2)
and Zr (Figure
5.6). Similar geochemical characterisation of coeval
plutons is also possible (see below).
Geochronology
Chandy and Snelling (in Allen
& Stephens, 1971) reported the first radiometric
dating of a volcanic rock in Hong Kong. They obtained a K–Ar
biotite mineral age of 154 ± 4 Ma from a coarse ash crystal
tuff, now assigned to the Shing Mun Formation. Darbyshire (1990)
obtained Rb–Sr whole-rock isochron ages of 140 ± 2
Ma for a vitric tuff from the Ap Lei Chau Formation and 135 ±
8 Ma for vitric tuff of the High Island Formation. Subsequently,
Darbyshire (1993) also reported a Rb–Sr whole-rock age of
144 ± 2 Ma for a rhyolite from the Lantau Volcanic Group.
New U–Pb age data derived from analyses of single
zircon crystals in several volcanic formations (Table
5.3) have enabled further refinement of the ages
of the volcanic rocks. Together with whole-rock geochemistry
(Sewell
& Campbell, 1997), they have confirmed
that volcanism occurred in at least four distinct episodes
(Davis
et al., 1997). In addition, one
compositionally distinct andesitic unit is thought to
pre-date the main period of Middle Jurassic to Early
Cretaceous volcanic activity (see below). A significant
aspect of the U–Pb age results is the comparatively
short duration of the volcanic episodes. These lasted
1 to 4 million years, while the intervening periods
of relative quiescence lasted 2 to 12 million years.
Significant unconformities separate the episodes. This
has been used as further grounds for subdividing the
volcanic sequence into four groups (Campbell
& Sewell, 1998) (Table
5.3). These encompass all of the volcanic formations
except for the Tuen Mun Formation.
It should be emphasized that the volcanic stratigraphy of Hong Kong
continues to evolve as new data and new techniques become available.
Further refinements are inevitable. In addition, the heirarchy of
formations and groups may require modification as correlation with
the vast Mesozoic volcanic hinterland of Guangdong and neighbouring
provinces is improved. For example, units regarded as formations
and groups in Hong Kong may equate more to those of member and formation
status respectively in Guangdong Province. However, until
geological maps of Guangdong Province become generally available
at the same scale and level of stratigraphical subdivision as has
been achieved in Hong Kong on the 1:20 000-scale geological maps,
the issue of detailed regional correlation must remain unresolved.
Details of the volcanic formations in Hong Kong and their more general
stratigraphic relationships are given below.
The Tsuen Wan Volcanic Group (Table
5.4) represents the earliest phase of the mainly
intermediate–silicic Middle Jurassic to Early
Cretaceous volcanism. The group comprises four formations,
the Yim Tin Tsai, Shing Mun, Tai Mo Shan and Sai Lau
Kong formations. Coarse ash crystal tuffs are dominant
within the group and these rocks typically weather to
an orange to brown saprolitic soil with large corestones.
The main area of outcrop of the group is in the northeast
and northwest New Territories, but the group extends
to western Lantau Island, Lamma Island and southern
Hong Kong Island (Figure
5.7).
The Lantau Volcanic Group (Table
5.5) represents the second phase of Middle Jurassic
to Early Cretaceous volcanism (Figure
5.13). The group includes the revised Lai Chi Chong
Formation in the northeast of the New Territories. The
group has not yet been divided into constituent formations
in its main area of outcrop on Lantau Island although
one member, the Pak Kok Member (Langford
et al., 1995), has been mapped there.
The group is associated with at least one major caldera-forming
event.
The Repulse Bay Volcanic Group (Table
5.6) represents the third phase of Middle Jurassic
to Early Cretaceous volcanism (Figure
5.16). The group is of earliest Cretaceous age and
comprises ‘Rhyolitic’ and ‘Trachytic’
subgroups, established on the basis of whole-rock geochemistry
(Campbell
& Sewell, 1998). The subgroups interdigitate,
suggesting they are of similar ages, but were erupted
from separate volcanic sources of different composition.
‘Rhyolitic’ Subgroup
The ‘Rhyolitic’ Subgroup includes the Long Harbour
and Mount Davis formations. Coarse ash crystal tuff
is the main lithology in the subgroup which crops out
in the south, east and northeast of Hong Kong (Figure
5.16).
The ‘Trachytic’ Subgroup comprises the Ngo Mei Chau,
Ap Lei Chau, Che Kwu Shan, Mang Kung Uk and Pan Long Wan formations.
These crop out in the south, east and northeast of Hong Kong. Fine
ash tuff and eutaxite characterise these formations.
The Kau Sai Chau Volcanic Group (Table
5.7) represents the fourth and final phase of Middle
Jurassic to Early Cretaceous volcanism. The group is
of Early Cretaceous age and comprises the Clear Water
Bay and High Island formations. These formations are
distributed mainly in the southeast and east of Hong
Kong (Figure
5.24). In addition, there is a small outlier of
the Kau Sai Chau Volcanic Group (undifferentiated) on
Lantau Island. The Clear Water Bay and High Island formations
are of trachydacite, rhyodacite and rhyolite compositions
and include fine ash vitric tuffs, eutaxites, lavas
and sedimentary rock intercalations. This final eruptive
phase was characterised by fissure-fed volcanism, which
culminated in a major caldera-forming event. Some of
the extrusive volcanic deposits can be traced directly
from their subvolcanic intrusive equivalents.
In order to identify eruptive sources, and reconstruct volcanic
environments in general, facies-based interpretation has been used.
This approach emphasizes distinctive associations of rock types
rather than their individual characteristics. Rock sequences are,
therefore, considered in terms of their lithology, geometry, sedimentary
structures, palaeo-movement indicators, distribution patterns and
fossil contents.
Facies analysis
The accuracy with which volcanic environments in Hong Kong can be
reconstructed using facies analysis is constrained by the varying
preservation of units and poor exposure in general. Many volcanic
deposits, especially pyroclastic deposits, are poorly consolidated
after their deposition and have little likelihood of being preserved
in the form in which they were laid down. Instead, they are commonly
reworked before final deposition and lithification, and may pass
through many such cycles of redistribution. Pyroclastic flow and
fall deposits on steep-sided volcanoes, and thin distal subaerial
volcaniclastic facies, in general, are particularly susceptible
to reworking and are poorly represented in the rock record compared
to their frequency of eruption. However, thick, volcanic deposits,
such as occur within calderas and other depressions, and subaqueous
(lacustrine and marine) volcanic deposits in general, are preferentially
preserved. It is the former type of caldera-related volcanic deposits
that appear to be best represented in Hong Kong.
Further complications arise in facies interpretation in Hong Kong
because of post-depositional changes to geometries. These are caused,
for example, by deformation associated with regional extension,
especially associated with the intrusion of dykes in large volumes,
regional strike-slip faulting, and pluton emplacement. Alteration,
including hydrothermal alteration and dynamic metamorphism, also
makes interpretation difficult as it has often obscured primary
features of the rocks.
Eruptive centres
Volcanic deposits near source are likely to be hotter, coarser and
thicker at the time of deposition, than their distal equivalents.
On the basis of several recurring features, it is clear that many
of the volcanic rocks in Hong Kong were deposited at, or near, their
eruptive sources (i.e. proximally). For example, some volcanic formations,
such as the Long Harbour and High Island formations, are hundreds
of metres or more thick, but lack significant variations in lithology
and are poorly stratified, suggesting rapid accumulation near source.
Many formations were clearly very hot when deposited. This is confirmed
by the presence of: welding (e.g. in the Lantau Volcanic Group (undifferentiated),
and the Ap Lei Chau, Long Harbour, Che Kwu Shan, Mang Kung Uk, Clear
Water Bay and High Island formations); columnar cooling joints (e.g.
in the Ap Lei Chau, Che Kwu Shan, Pan Long Wan, Clear Water Bay
and High Island formations); and diffuse margins of volcaniclasts
(e.g. in the Yim Tin Tsai Formation) suggesting thermal and chemical
disequilibrium.
There are several examples of spatial associations between outcrops
of volcanic formations and related subvolcanic intrusions. These
indicate eruptive centres that lie above or close to their magmatic
source region. For example, granodioritic intrusions commonly intrude
the Yim Tin Tsai Formation and other formations of the Tsuen Wan
Volcanic Group. Some intrusions are distributed along faults that
bound major volcanic outcrops, as is the case with the Long Harbour
Formation, whereas other dykes pervade the general terrain around
the outcrop as with the Lantau Volcanic Group. Rarely, fault-bounded
intrusions can be traced in outcrop continuity into extrusive equivalents,
as with rhyolites within the Clear Water Bay Formation.
Fault-bounding of outcrops suggests the possibility of a tectonic
constraint on the primary distribution of the volcanic deposits,
most notably with respect to the Lantau Volcanic Group, and the
Ap Lei Chau, and Long Harbour formations. However, care must be
taken in interpreting fault relationships in this way, as in some
cases the faulting substantially post-dates the volcanic rocks.
Locally thick, very coarse pyroclastic breccias and tuff-breccias
are present within the Shing Mun, Long Harbour, Che Kwu Shan, Mang
Kung Uk and Clear Water Bay formations. These deposits are likely
to have been erupted very close to their eruptive sources.
The common and widespread occurrences of coarse ash crystal tuff
may be an indication of proximity to source. As fine ash vitric
components are progressively sorted and transported further from
their source during eruption and emplacement (by pyroclastic fall,
flow or surge processes), greater concentrations of coarse ash crystals
are likely to characterise the environments closer to the volcanic
sources. However, crystal concentrations can also result from secondary
sedimentary processes. Coarse ash crystal tuffs dominate the Yim
Tin Tsai, Shing Mun, Tai Mo Shan, Mount Davis and Long Harbour formations.
Calderas
Large volume rhyolitic and rhyodacitic pyroclastic deposits in the
geological record are almost always deposited from pyroclastic flows
and are commonly associated with the formation of calderas. Calderas
are structurally-bounded depressions that form during, and as a
direct consequence of, an eruption. Rapid evacuation of a near-surface
magma chamber during eruption and loading of the overlying crust
destabilize the crust, so much so that it can collapse into the
newly created cavity below. The process of collapse may continue
during the later phases of an eruption or may post-date it, depending
on the scale and duration of the eruption. If the collapse occurs
during eruption, as is often thought to be the case, the structurally-defined
surface depressions can trap thick sequences of pyroclastic flow
deposits (intracaldera deposits). They contrast with the much thinner
sequences of pyroclastic flow and fall deposits outside the caldera
These result from eruptions that occurred prior to caldera development,
as well as from later airfall events and pyroclastic flows that
escape the confines of the caldera (outflow deposits).
In Hong Kong, the approximate locations of large calderas
can be inferred in relation to several of the volcanic
formations (Figures
5.13 & 5.16).
Nearly complete, ellipsoidal to polygonal calderas are
interpreted as confining the Lantau Volcanic Group (undifferentiated)
and Long Harbour Formation, and possibly the Yim Tin
Tsai and Shing Mun formations together. Incomplete calderas
can be proposed for the Ap Lei Chau, Clear Water Bay
and High Island formations. These calderas are described
in greater detail in relation to individual eruptive
phases (see below).
The early and later parts of the Tsuen Wan Volcanic Group were dominated
by relatively continuous tuff accumulation, resulting in the deposition
of widespread, comparatively homogeneous, coarse ash crystal tuff
(Yim Tin Tsai and Tai Mo Shan formations). The intervening deposits
(Shing Mun Formation) reflect more sporadic volcanism with periods
of quiescence marked by the accumulation of fine-grained volcaniclastic
and epiclastic sediments.
The homogeneity of the Yim Tin Tsai and Tai Mo Shan formations
suggests rapid, largely uninterrupted eruption and deposition from
substantial pyroclastic flows fairly close to source. A principal
source of eruption is inferred to be in the vicinity of Tai Mo Shan. However, as this interpretation is based in part on the association
and spatial distribution of coeval intrusions, further discussion
is delayed until Chapter 7, which addresses
the synvolcanic structural environment.
No major uplift or submergence appears to have occurred during deposition
of the Shing Mun Formation, and this formation probably represents
a period of largely waning volcanism. Thick accumulations of debris
flow and laharic material (Shek Lung Kung Member), and pyroclastic
breccia, suggest degradation of an existing volcanic centre or centres,
interspersed with periods of renewed eruption.
The main outcrop of the Ngau Liu Member west of Tai Mo Shan may
also represent a near-source volcanic facies. The source, however,
of the Cheung Shan Member, whose thickest outcrop is on the northwest
side of Lantau Island, is unknown.
The dominance of comparatively viscous dacitic lavas within the
Sai Lau Kong Formation, suggests an eruptive centre, or centres,
in the northeastern New Territories. The outcrop pattern of the
Sai Lau Kong Formation is generally elongate in a northwesterly
direction, and bedding attitudes suggest a basin-like structure.
Sporadic accumulations of tuff-breccia and tuffaceous sediments
within the sequence, coupled with thick piles of dacitic lava, suggest
an extensional fissure in which lavas and other eruptive products
ponded. Similar volcanic deposits in the neighbouring Shenzhen Special
Economic Zone (Yang
et al., 1986) probably
mark the continuation of this fissure vent system yet further to
the north.
Lantau Volcanic Group Phase
The largely fault-bounded outcrop pattern of the Lantau Volcanic
Group on Lantau Island is interpreted as a caldera.
The entire structure developed within a narrow, elongate,
northeast-trending rift zone that extended to the northeast
and incorporated the outcrop of the Lai Chi Chong Formation
(Figure
5.27).
The internal structure of the caldera is markedly asymmetrical,
and appears to reflect the pattern of bounding faults. In contrast
to the northward-dipping, and disconformable succession in the south,
the internal structure in the north is more complex, although exposure
is poorer. This complexity is expressed by abrupt changes in bedding
orientation, lithology, the degree of hydrothermal alteration, folding,
local unconformities and faulting. These features are interpreted
as being largely primary and related to the evolution of the caldera,
rather than to any later event. The degree of complexity also suggests
the piecemeal creation and infilling (cf. Branney & Kokelaar,
1992) of an elongate, asymmetric, rift-like volcanotectonic depression
rather than the single collapse of a circular structure (cf. Smith
& Bailey, 1968).
The relative abundance of lavas as opposed to tuffs in the Lantau
Volcanic Group (excluding the Lai Chi Chong Formation) is unusual
for a rhyolitic volcanic centre. This could suggest the likely prevalence
of high temperature, low viscosity lava fountains extruding molten
rock in pulses, as opposed to slightly lower temperature ash columns
that collapsed and coalesced near the vent forming welded flows.
Quiescent phases were sometimes long enough for sediments to accumulate.
The abundant flora indicate a warm, wet palaeoclimate with swampy
basins on the flanks of the volcano. Thick, laterally extensive
tuffaceous units, representing mass flows, and including primary
lahars, redeposited tuffaceous material, causing rapid infilling
of small basins within the caldera. The sedimentary and tuffaceous
rocks, characterised by their restricted outcrop and rapid gradational
changes, accumulated as sediments in small basins that were filled
during flash floods and by debris flows. During quiescent periods,
graded silts were deposited. The grading may reflect seasonal fluctuations,
or local rainstorms redistributing poorly consolidated volcanic
deposits.
The Lai Chi Chong Formation represents sedimentation within a shallow,
non-marine, probably lacustrine environment. Periodic volcanism
within or adjacent to the lake caused frequent inundation of the
lake by primary volcanic and secondary volcaniclastic detritus transported
and deposited from mass flows. The secondary mass flows mainly included
low and high concentration turbidites with some debris flows also.
The primary volcanic deposits comprise possible surge and airfall
deposits and lavas. The presence of surge deposits implies the proximity
of maar or tuff ring volcanoes occurring as small islands within,
or close to the margin of, the lake. Instability associated with
the emplacement of the thicker deposits caused extensive downslope
disturbance of the partially dewatered substrate. This suggests
the relatively rapid accumulation of the sequence as a whole. At
Lai Chi Chong, the palaeoslope was inclined generally southwards.
However, further south the formation also includes fluviatile conglomerates
that thicken southwards towards the Chek Keng Fault. This suggests
that there was uplift on the south side of the fault. These conflicting
slope orientations suggest that the basin was only a few kilometres
across.
Repulse Bay Volcanic Group ‘Rhyolitic’ Phase
Various features suggest that the Long Harbour Formation was deposited
relatively close to its eruptive source. Most notable among these
are the abundance of coarse accidental lithic clasts, the virtual
absence of sedimentary intercalations within a thick sequence with
limited lithological variation, and the evidence of hot emplacement
of the tuffs (e.g. columnar jointing). This evidence, taken in conjunction
with the largely fault-bounded nature of the outcrop, has been used
to argue (Strange et al., 1990;
Campbell
& Sewell, 1997) that the Long Harbour Formation to
the northeast of Sai Kung represents the infilling of a caldera
or similar volcanotectonic depression.
To the west of Sai Kung, a discrete ellipsoidal outcrop of the formation
is interpreted as another caldera. This contains two separate intracaldera
facies, one, in the southwest, that is rhyolite-rich, and the other
which is rhyolite-poor, cropping out mainly in the northeast. The
rhyolite-rich facies is probably the stratigraphically lower of
the two, but given the lack of stratigraphic control within the
Sai Kung Caldera, the relationship is uncertain.
The Long Harbour Formation west of Sai Kung and the Mount Davis
Formation are lithologically and geochemically very similar. They
also appear to occupy similar stratigraphic positions although they
outcrop in separate areas, or are separated by faulting. These relationships
suggest that the Long Harbour Formation west of Sai Kung is largely
an intra-caldera facies and that the Mount Davis Formation may be
its equivalent outflow facies. If this can be demonstrated with
greater confidence, it may prove necessary to rationalize the stratigraphy
so that the Mount Davis and Long Harbour formations are combined
into one formation only.
The presence of eutaxite units within the Mount Davis Formation,
which are more typical of the older Ap Lei Chau Formation, suggests
the possibility that the source of the Ap Lei Chau Formation continued
to erupt periodically during the early stages of accumulation of
the Mount Davis Formation.
Repulse Bay Volcanic Group ‘Trachytic’ Phase
The thick accumulation of welded pyroclastic deposits within the
Ap Lei Chau Formation suggests that they were deposited near to
their eruptive source. The formation is restricted to the area northeast
of the inferred northwest-trending ‘East Lamma Channel fault’
and southeast of the eastnortheast-trending Chek Keng Fault (see
Chapter 7). Both faults
may have been active during deposition of the formation (Campbell
& Sewell, 1997). Owing to the subsequent intrusion
of the Kowloon Granite (see Chapter
6) and related deformation, including annular folding, little
progress has yet been made in identifying eruptive sources for the
Ap Lei Chau Formation.
The restricted, partially fault-bounded, northwest-trending outcrop
of the Ngo Mei Chau Formation may be, at least in part, a primary
volcanic feature (Sewell
et al., 1998). In this case, the formation could
be interpreted as a proximal accumulation of pyroclastic deposits
within an elongate depression or vent controlled by a fissure. The
formation is approximately coeval with the lithologically and geochemically
similar Ap Lei Chau Formation.
Locally within the Che Kwu Shan Formation, there are coarse ash
tuffs within or close to vent. These indicate periodic reactivation
of sources that gave rise to the older Long Harbour and/or Mount
Davis formations. Hence, during deposition of the Che Kwu Shan Formation,
the area was characterised by broadly coeval eruptions from a trachytic
source (Che Kwu Shan Formation) and a rhyodacite to rhyolite source
(Long Harbour and Mount Davis formations).
The Mang Kung Uk Formation was deposited in an unstable environment,
with sediments and derived volcaniclastic detritus washed into a
shallow, possibly volcanotectonic, lacustrine basin. There are indications
of volcanic sources contributing to the Mang Kung Uk Formation both
from the north and from the south.
Near the Tin Ha Shan Fault, the pronounced thickness increase
of the Tai Miu Wan Member of the Pan Long Wan Formation has been
interpreted (Campbell
& Sewell, 1997) as indicating that the fault was
the feeder and eruptive source of the lava. An increase in thickness
of the fine ash tuff units within the formation towards the south
suggests a similar interpretation.
Kau Sai Chau Volcanic Group Phase
The lavas in the Clear Water Bay Formation are likely
to have been erupted locally since the travel distances
of rhyolite flows are unlikely to have exceeded c.10
km. The eastnortheast-trending, subvertical, fault-bounded
intrusive zone is interpreted as the main fissure-like
vent from which most of the rhyolite lavas were erupted
(Figure
5.28). The structure fed a subsiding zone bounded
to the north by an east-striking section of the Chek
Keng Fault with upthrow to the north. The easterly-dipping
extrusive flows therefore ponded along and to the south
of the fault, with maximum accumulation of the lavas
close to the fault. A further eruptive centre may have
developed at the eastern end of the Chek Keng Fault
in the vicinity of Sharp Peak. The subsiding ground
south of the fault was the first phase in the development
of a caldera that further evolved during eruption of
the High Island Formation. A further structure has been
inferred subparallel to, and to the south of, the Chek
Keng Fault (Figure
5.28). This structure may have limited the southerly
spread of the rhyolite lavas. The narrow outcrop of
the formation within the Tin Ha Shan Fault in the south
of the area, suggests that the fault acted as a second
fissure-like source of the lavas.
The High Island Formation was deposited within a caldera-like,
fault-bounded depression, bounded by the east-striking
Chek Keng Fault to the north and the Tin Ha Shan Fault
to the south. The same structure inferred to have limited
the southerly spread of the Clear Water Bay Formation
rhyolite lavas, may have acted as a collapse structure
during deposition of the High Island Formation. In this
instance, however, the greater collapse appears to have
occurred to the south of the structure (Figure
5.28).
Small-scale vents were identified by Strange et al., 1990, within
rocks now identified as Clear Water Bay Formation. These lie within
the Tin Ha Shan Fault and may represent feeders to the High Island
Formation.
Further interpretation of the magmatic evolution of Hong Kong,
especially with regard to the common structural controls of volcanism
and plutonism, is presented in Chapter 7.
