Dr Arne Pommerening Lecturer in Experimental Silviculture
Transcription
Dr Arne Pommerening Lecturer in Experimental Silviculture
Dr Arne Pommerening Lecturer in Experimental Silviculture School of Agricultural & Forest Sciences University of Wales Bangor Bangor Gwynedd LL57 2UW, UK Survey Protocol for the Establishment of Growth Series with Permanent, Sample Plots in Planted and Semi-natural Forests of Wales1 1 Introduction The objectives of the establishment and measurement of permanent experimental plots as part of so-called growth series (Æ section 1.1) are to collect data on the site, stand, and tree characteristics, covering a range of stand ages. Data of this kind are used particularly for spatial analysis of stand structure to evaluate the effects of silvicultural practices and environmental change on stand structure and biodiversity to develop sampling designs for (uneven-aged) mixed forest stands to develop site dependent, distance dependent, individual tree growth models. This survey protocol has been developed with special attention to research in mixed and uneven-aged forests which are commonly the result of continuous cover forestry. 1.1 The growth series concept Data gathered over a tree’s or stand’s lifetime provide the best source of information for research into forest growth. However, where time is a limiting factor for data collection or when information is required quickly, this approach is not possible. This has led to the development of alternative methods one of the most common of which is the use of growth, or unreal, time series. In a growth series a number of plots are established in stands of varying age, the information from which is used to approximate the true chronological sequence of stand development. For example six plots may be established in stands of 20 to 120 years of age with 20 years between each stand. The plots of a growth series should be established on similar site types and be as close to each other as possible. Within the plots an enumeration of trees is carried out along with various increment measurements which enable the development of the trees between the specific plot ages to be interpolated. In this way we can obtain a steady picture of the change in the most important aspects of forest yield over time. 1 This survey protocol is based on a version developed by Professor Hans Pretzsch, Chair of Forest Yield Sciences and Forest Systems Analysis, Technical University of Munich, for the survey of the growth dynamics of Bavarian mixed forest stands with the help of a network of growth series. It was extended and adapted to Welsh conditions by Arne Pommerening, Francis Gwyn Jones, Jens Haufe, Steve Murphy, Owen Davies and Mark Rogowski, SAFS, Bangor. 2 In the past both time series and growth series, have proved successful in monitoring sum and mean values of forest stands for the derivation of yield tables. Both concepts now have to be adapted to the specific needs of modelling the growth of individual trees in pure even-aged forest stands and for well-structured uneven aged and mixed stands. The main focus of this approach is the individual tree, not the forest stand. Information is collected on the increment of individual trees dependent on tree properties, parameters of the immediate vicinity of each tree, stand properties and treatment effects. For a wide age range the change in diameter, height and crown width, the shift of the base of the live crown, and mortality (or survival probability) of individual trees has to be measured in different competition and neighbourhood situations for every tree species. Therefore it is desirable to have a good number of trees, which have grown under extreme neighbourhood circumstances with an exceptionally high or low competition pressure. These extreme conditions are very productive for modelling the reaction of individual trees dependent on growth and competition constellation. To survey the competition and neighbourhood effects among the different tree species there should be a wide range of mixtures and homogeneous forest stands should be avoided. The individual tree, rather than the forest stand, is the unit of information. Although the focus is mainly on individual tree variables, square or rectangular plots with an extent of 0.6 - 1 hectare are desirable, because it is easier and cheaper to survey and measure control trees in a defined area. 1.2 Terms plot time series growth series 2 permanent experimental site data from one plot covering a certain period through repeated measurements data from a series of plots with stands or trees of different age, but on the same site type Establishing a new growth series The first step is the identification of a suitable area (with uniform site conditions, target tree species, range of age class, etc.); this should be undertaken by SAFS staff members in cooperation with the relevant Forest District Office (FDO). Before further steps to select the appropriate areas are taken, the FDO should be informed and asked for comment, permission and any support they may be able to offer. An initial field reconnaissance should be carried out to select suitable sites. Together with members of the FDO, sites should be selected, which contain suitable mixed stands; the selection should have 4 - 5 stands and take into account the required age- and height-range. If a stand seems to be suitable during an on-site inspection: The plot boundaries should be marked roughly (flagging tape); approximately 100 m x 100 m as standard size. The total plot size of 0.6 to 1.0 ha is applicable to young stands, however for these different survey instructions apply. The stands should be described (Æ appendix 1); sample height measurements are very important (with 5 plots per growth series there has to be 4 m to 5 m of height difference, which corresponds with bigger age differences in older-age stands); at 3 least three height measurements have to be taken per tree species; the mean diameter of each species must also be estimated. The proportion of differing tree species should be small; differing tree species are those which are not a typical element of the growth series; e.g. Sitka spruce is not usual in a stand of oak and ash; but rowan or birch would be acceptable in a stand of oak and ash. All the tree species which are relevant for the particular growth series should be found in the canopy layer, preferably in even proportions; heterogeneous stand-structures, i.e. alternating dense and open areas are advantageous. After a pre-selection of 4 to 5 stands (stand description and sample height measurements will be available at this point), the areas should be inspected for a second time by the SAFS survey team. After this second inspection confirmation of the suitability of the plots will take place in conjunction with the FDO. 3 Plot establishment and recording Plots should be square or rectangular 0.6 – 1.0 ha in size and consist of a core, outer area and buffer zone (Æ appendix 2). All trees should be given a unique reference number before any measurements are taken and this must be used throughout the survey. There should be no measurements without tree numbers being used. It is essential to obtain extracts of the relevant subcompartment database and as many records as possible that are available about the past stand development and treatment for all the plots from the FDO. It is important to document and record all work activity carried out, particularly if this deviates from the standard protocol. This record should include number of staff and hours worked and the equipment used. With this information it should be possible to plan future work from a reasonably good foundation. 3.1 Plot establishment 3.1.1 Angle trenches and boundary posts Plot corners (and, if necessary, plot edges) should be marked with wooden posts. We have used CCA treated posts and marked each with its station number (e.g. stn1, stn2,…). We have also considered using buried metal with a view to using a metal detector in the future. The corners of the core area should be marked as well. Internal survey points may be established within the plot boundary as necessary and should be marked in the same way. It is very important that all the boundary posts and internal survey points (e.g. sti1, sti2,…) are marked as permanently as possible. Boundary posts may be complemented by angle trenches. These should be dug, if possible, at every post (30 cm wide, 20 cm deep and in each direction 100 cm long). If required and if available stones could be used to replace or supplement the trenches. The arms of the trenches should point directly either way to the next posts. 3.1.2 Additional plot identification In an ambit of 15 m around the plot a number of trees, that are likely to be permanent, should be marked with a contrasting colour to that used in the main plot. Yellow has been found to be satisfactory for this purpose. Marking should encircle these trees at a height of 1.5 m using a band width of approximately 5 cm. Not every tree need be 4 marked and a distance of 8 – 10 m between marked trees should suffice to safeguard the plot. 3.1.3 Experiment number On one of the boundary trees the number of the experiment as well as the number of the plot should be painted, so as to be visible from the inside of the plot. 3.1.4 Enumeration All trees with a DBH greater than 5 cm should be numbered and a line painted at DBH; It is probably best to number the trees at the same time as marking the DBH point. The tree number and DBH line should be close to each other and at the same side of the tree. On a sloping site DBH is normally established on the uphill side of the tree and it is on this side that the number should be painted unless there is reason for not doing so. A variety of marking methods have been tried and where possible exterior grade white paint (e.g. Williamson’s Titanium Tree Paint) should be used. DBH marks and numbers should be checked annually and repainted if necessary. Prior to painting the bark should be cleaned. The methods will depend on species and may range from using a rag on smooth and thin barked species to partially removing bark with a billhook or a slasher on thick-barked species such as pine; this preparation has a strong effect on the durability of the marks but should not be done so as to damage the tree. The bark should be dry prior to painting and also should not be done in frosty weather. Where trees are too small to be painted numbered aluminium discs should be attached to a branch of the tree using strong, clear sticky tape. It has been found advantageous to divide the plot into strips of approximately 3 to 5 m (older forest stands 10m) and to number the trees in the strips in sequence; it will be found that doing this will facilitate later data collection and recognition. There should be no difference in the range of numbers in the core area and the outer area. Numbers and marks should be discrete, e.g. not visible from foot paths and roads so as not to draw undue attention. Dead, but standing trees, should only be numbered if they have obviously died in the last two years. 3.1.5 DBH-line The DBH-line should be applied at 1.3 m above ground level (on a slope this should be on the uphill side). This measurement should be from where the soil covers the base of the tree. Care should be taken with older trees, e.g. pine, because a thick humus cover at the base caused by e.g. detached bark pieces could cause the measuring point to be higher than it ought. The figure on the right might help to identify the DBH of trees in critical situations. 5 3.1.6 Boundary trees Boundary trees are trees which have their coordinates on the plot boundaries or outside the plot, but whose crowns reach into the area of the sample plot. The boundary trees are marked with numbers >900. If the number of trees in the plot is greater than 900, the marking of the boundary trees starts with numbers >9000. The marking of the boundary trees should be on the side facing into the plot. They should be recorded in the same way as any other tree in the plot (see section 3.2). 3.1.7 Stumps, other deadwood and corners Stumps from previous fellings and windblows are given a number greater than 5000. Standing deadwood can be surveyed in a similar way to the living trees. Lying deadwood should be recorded using two coordinates, one at the base the other at the tip. The corners and intermediate boundary posts are numbered sequentially, e.g. stn1, stn2 etc. 3.2 Survey protocol for all numbered trees All information is collected on a field computer. The following characteristics are recorded. 3.2.1 Tree species Tree species should be identified using scientific names as they are pre-installed in the PenMap software in this way. A list of species names is attached (Æ appendix 3) 3.2.2 Crown class Dominant (D) Supressed (S) Crowns above level of main canopy. Receive light from above, plus some from the side (code 1). Main canopy trees. Receive light from above but not from the side (code 2). Crowns extended into main canopy. Only the tops receive light (code 3). Crowns completely overtopped (code 4). Dead code 5 Co-dominant (CD) Sub-dominant (SD) 6 3.2.3 DBH DBH to nearest 0.1 cm (e.g. d = 16.7 cm, girth measurement, crosswise calliper measurement if required). For the position of the DBH refer to section 3.1.5. 3.2.4 Particularities Forked trees, crown snap, squirrel damage, beetle damage, extraction damage, overall health etc.; encoding in accordance to instructions and PenMap pre-installation. The preliminary site inspection will indicate anything out of the ordinary which may have to be taken into account in customising the PenMap software. 3.2.5 Diameter at stump height/ ground diameter The diameter at stump height has to be measured on at least 30 standing trees per tree species and over the entire diameter range. Stump height should be considered in the preliminary site inspection and will be above the point of root buttressing (usually at 30 cm above ground level). 3.2.6 Tree height and base of crown At least 40 height and base of crownmeasurements per tree species should be taken in m and measures to the nearest 0.1 m (e.g. h = 12.4 m). Crown base per definition is defined by the first living branch that is contiguous with the crown; on a slope (≥10°), the crown base is measured once from uphill and once from downhill side establishing an average. As many measurements as possible are taken from the core area (at least 25 trees per species). Height measurements should cover the whole diameter range. These measurements will serve to calculate a height curve typical for the stand. If the stand is clearly divided into different layers, e.g. understorey of beech in a stand of mature oak/beech; at least 40 heights in each layer have to be collected. 3.2.7 Tree locations Tree locations should be surveyed, incl. stumps and boundary points using x-, y-, zcoordinates (cartesian coordinates). 3.2.8 Stump assessment Stump assessment should take place during the survey of tree positions. Numbers ≥5000 Tree species, if no identification possible state whether coniferous/ broadleaved tree Diameter in cm (girth tape or calliper) to nearest 0.1 cm; estimation of original diameter over bark may be necessary in case of decomposition If stumps are in good enough conditions, disks may be sampled for increment analysis. If no disk is taken record age in grades - 1: <5 years; 2: 5-10 years; 3: 10-20 years; 4: >20 years); if necessary the available records may have to be used. For stumps that obviously belong to the previous rotation the age grade 5 is to be given instead of 4. 7 For every stump the reason for death should be specified if possible: 1 thinning, 2 dead standing, 3 dead lying, 4 broken, 5 windblow, 6 unknown, 7 dead hanging 3.2.9 Crown survey Using a ‘crown window’ device (Hussein et al., 2000), two crown shape images should be produced for a sample of trees covering the whole DBH range. The crown window is a transparent device superimposed by grid squares and mounted on a tripod through which the tree can be viewed. An acetate is used to draw the shape of the crown that can be seen through the transparent device. The following steps need to be undertaken: 1. Select appropriate position from where you can clearly see a representative outline of the desired tree crown, distance to stem foot should be at least equal to the tree height. 2. Set up tripod with attached crown window, gridlines have to be parallel to stem axis and window should be vertical. 3. Get bearing and distance to tree, tree height and height of crown base (Vertex). 4. Draw carefully outer shape of crown from base to top, use head stabilizer to maintain firm distance from your eye to the window, don’t move, or do anything that could change the perspective … assign tree number for identification, mark stem axis. 5. Additional drawings should be taken from positions shifted by ± 90° at a time. ArcView GIS software is used to produce a series of co-ordinates tracing the outline of each crown shape, scaled according to the measured crown length. For a form for the survey of crown shapes Æ appendix 4. Reference Hussein, K. A., Albert, M. and Gadow, K. v. (2000) The Crown Window – a simple device for measuring tree crowns. Forstw. Cbl. 119, 43-50. 3.3 Survey protocol restricted to core area 3.3.1 Estimation of crown radii 8 radii (N, NE, E etc...) should be taken. Although a crown mirror or a spherical densiometer may be used it has been found that that the “look up method” is perfectly satisfactory. The results of this method, however, should be checked or calibrated against one of the above measuring devices. Overall the crowns of at least 200 trees per plot (if that number is available) should be measured. The main tree species of the plot should be represented. These trees should be standing in a contiguous part of the core area. Therefore it is often necessary in older stands to measure the crown radii of the complete core area or perhaps even the total area. 8 In younger stands with tree numbers >200 in the core area, only a part of the area need be recorded. However, this area need not be marked, but it should be rectangular or square, e.g. 30m x 30m. Where the tree is leaning the centre of gravity of the crown will not lie directly over the tree's position. It is, then, necessary to determine the projection of the centre of gravity onto the ground and mark this with a ranging rod. The crown radii are then taken from this point. The position of the ranging rod, in relation to tree position (distance and angle), should be meausured and noted. 3.3.2 Height and base of crown measurements All the trees in which the crown radii have been measured should also be measured to establish their total height and the base of crown. These measurements may reduce the number of trees necessary for estimating height curves, however, they may not be representative of the whole area. Thus an extra 20 trees should be measured to create accurate height curves. 3.3.3 Inventory of regeneration Regeneration, i.e. young trees that have not been given individual co-ordinates (DBH less than 5 cm) should be surveyed in a 10 m x 10 m grid system. To facilitate this the grid will have to be permanently marked out with posts. Around each grid point a sample quadrat with 4 m x 4 m is established so that the grid point is its centre. An accurate sketch of this area and the numbers given to the nodes (posts) should be drawn. In each sample quadrat The species and number of the regenerating trees should be noted in the following 50cm-height-classes (height-class: 0=seedling; approximately less than 10 cm in height and less than one year old, 1=10-50 cm, 2=50-100 cm, 3=100-150 cm,...). The growth extension of the previous 5 years should be measured in the three tallest trees per tree species and if these have reached 1.3 m height the DBH should be measured in mm and additionally a diameter at 10 cm above ground level. It is the apical shoot length that should be measured, not the height increment. This is important especially for young trees which often have curved shoots and stems, e.g. beech. 3.3.4 Stem analysis inside the experimental plot Windblows, thinnings, etc. inside the plot should be used to carry out stem analysis. If there are none of the latter, selected trees may even be felled for that reason. On standing trees, North should be marked on the stem before felling. Measurement of annual shoot growth should be carried out as far backwards as possible and snedding has to be done in a way that does not complicate this. The stem should then be marked for disk sampling. Disks should be taken at 2 m intervals, starting at 1.3 m height (i.e. at 3.3, 5.3, 7.3 m etc.). Additional disks should be taken at 0.3 m and at 30% of total tree height. North should be marked at each disk before cutting the disks off. Disks are to be labelled with plot number, tree number, and disk position. The use of an electric planer has proved to facilitate further analysis; small disks may be planed on a lathe. Analysis or scanning of the disks should be done not later than 48 hours after sampling. 3.3.5 Soil survey On each experimental plot a soil pit should be dug in the approximate centre of the plot. The pit should be large enough to allow adequate description and sampling, and be constructed in such a way to allow easy entrance and exit and escape for small creatures. The headwall of the pit should be at least two thirds the crown radius away from any 9 tree. The soil should be described using standard soil survey procedures and identified using FC nomenclature. If permission is obtained the pit should be left open for teaching and demonstration purposes. In this case it should be fenced to avoid any forest visitor falling into it. Soil heterogeneity should be checked over the whole plot and any major variations described and sampled if necessary. 3.4 Survey protocol restricted to the outer area 3.4.1 Increment boring Increment cores should be taken from a sample of trees, which should cover the whole DBH range. On every tree of the outer area with a DBH ≥ 40cm two increment cores should be taken, one from the NE, one from the SW preferably at a height of 1.1m (boring height should be recorded). The increment core of old trees should reach at least 40 years into the past. The use of 8mm borers is preferable. Broadleaved trees: DBH ≥ 12cm boring once from NE; DBH ≥ 20cm both from NE and SW. Conifers: DBH ≥ 10cm drilling once from NE; DBH ≥ 15cm both from NE and SW. 3.4.2 Tree diameter at 1.1m height If increment boring is performed at a height of 1.1 m and not at 1.3 m above ground level, the diameter at 1.1 m (boring height) of at least 30 standing trees per species should be measured; this should cover the complete diameter range. 3.4.3 Age cores If tree age is unknown, cores from the bases of 3-5 trees per species should be taken (boring height should be noted) in order to determine tree age; if the centre is not hit reboring should be limited to two more attempts. If a thinning is planned, these age cores become unnecessary as the annual rings can be counted on the fresh cut stumps (stump height should be noted). 3.4.4 Stem analysis outside the experimental plot If the analysed tree was located outside the plot, the tree itself as well as all neighbour trees affecting its growth space should be numbered (using a sub-range of numbers), and tree position, species, DBH, crown class, and height should be recorded. A sketch should 10 be drawn of this "sample circle" and its position in relation to the nearest experimental plot should be recorded with the total station. The tree that is to be analysed should be treated as in section 3.3.6 above. 3.4.5 Boundary trees See section 3.1.6. Arne Pommerening, Francis Gwyn Jones, Jens Haufe, Steve Murphy, Owen Davies and Mark Rogowski, October 2002 11 Appendix 1 Stand description Growth series: Compartment: Planting year: General stand description: Mixture distribution: Species mixture (in %): Crown density (% of sky - % of canopy): Mean diameter: Mean height: Height measurements: 1 2 3 4 5 6 tree species Reconstructable position sketch: height DBH 12 Appendix 2 Area layout for all age classes ( incl. young stands) total area = core section/inner area + outer section required size of the total area: 0.6 to 1.0 ha buffer: at least 10m wide for distances and areas horizontal projections should be used buffer zone outer area core area at least 30 m x 30 m >5m > 40 m > 10 m The outer area surrounds the core area to a width of at least 5m (e.g. total area 60m x 50m, core section 50m x 40m) Core and outer area have to be square or rectangular 13 Appendix 3 Forestry Commission Species Codings Common Name Scots pine Corsican pine Lodgepole pine Austrian pine Maritime pine Weymouth pine Mountain pine Bishop pine Monterey pine Ponderosa pine Macedonian pine Other pines Sitka spruce Norway spruce Omorika spruce Other spruces European larch Japanese larch Hybrid larch Douglas fir Western hemlock Western red cedar Lawson's cypress Leyland cypress Grand fir Noble fir Silver fir Other firs (Abies) Japanese cedar Coast redwood Wellingtonia Other conifers Mixed conifers Oak Pendunculate oak Sessile oak Red oak Beech Sycamore Norway maple Ash Birch Poplar Sweet chestnut Horse chestnut Alder Common alder Grey alder Red alder Sitka alder Green alder Lime Common lime Small-leaved lime Large-leaved lime Elm English elm Wych elm Smooth-leaved elm Wild cherry, Gean Bird cherry Hornbeam Roble Rauli Raoul Hazel Other broadleaves Mixed broadleaves Code SP CP LP AUP MAP WEP MOP BIP RAP PDP MCP XP SS NS OMS XS EL JL HL DF WH RC LC LEC GF NF ESF XF JCR RSQ WSQ XC MC OK POK SOK ROK BE SY NOM AH BI PO SC HCH AR CAR GAR RAR SAR VAR LI CLI SLI LLI EM EEM WEM SEM WCH BCH HBM OBN PRN RAN HAZ XB MB Botanical Name Pinus sylvestris L. Pinus nigra var. maritima (Alton) Melville Pinus contorta Douglas Pinus nigra var. nigra Harrison Pinus pinaster Ait. Pinus strobus L. Pinus uncinata Miller Pinus muricata D. Don Pinus radiata Pinus ponderosa Douglas Pinus peuce Griseb. Pinus spp. Picea sitchensis (Bong.) Carr. Picea abies(L.) Karst Picea omorika (Pancic) Purkyne Picea spp. Larix decidua Miller Larix kaempferi (Lambert) Carr. Larix eurolepsis Henry Pseudotsuga menziesii (Mirb) Franco Tsuga heterophylla (Raf.) Sarg. Thuja plicata D. Don Chamaecyparis lawsoniana (A. Murr.) Parl Cupressocyparis leylandii (Jacks. and Dallim) Dallimore Abies grandis Lindl. Abies procera Rehd. Abies alba Mill. Abies spp. Cryptomeria japonica (L.f.) Don Sequoia sempervirens (D.Don) Endl. Sequoiadendron giganteum (Lindl.) Buchholz Quercus spp. Quercus robur L. Quercus petraea (Matt.) Lieblein Quercus borealis Michx. f. Fagus sylvatica L. Acer pseudoplatanus L. Acer platanoides L. Fraxinus excelsior L. Betula spp. Populus spp. Castanea sativa Mill. Aesculus hippocastanum L. Alnus spp. Alnus glutinosa (L.) Gaertn Alnus incana (L.) Moench Alnus rubra Bong. Alnus sinuata Alnus viridis (Chaix) DC. Tilia spp. Tilia europaea L. Tilia cordata Miller Tilia platyphyllos Scop. Ulmus spp. Ulmus procera Salisb. Ulmus glabra Hudson Ulmus carpinifolia Gleditsch Prunus avium (L.) L. Prunus padus L. Carpinus betulus L. Nothofagus obliqua (Mirb.) Blume Nothofagus procera (Peopp. and Endl.) Nothofagus nervosa Corylus avellana L. SS SS SS SS SS SS Crown base ht 2 Height 2 Distance 2 Bearing 2 Crown base ht 1 Height 1 Distance 1 Bearing 1 Crown base height Height Dbh Tree no. Species 14 Appendix 4 Crown radius (to be measured with tape from stem surface at 1.3 m height, horizontally) E SE S SW W NW N NE