1-4 Years Out For those 1-4 years after receipt of PhD at the time of each survey since 1973, the SDR data (not reproduced here) show that unemployment rates and part-time employment rates have been low in all fields. Overall, the percentage of u nemployed (defined as not working and looking for work) has varied between 1.2% and 1.6%. It was 1.5% in 1991 among those getting PhDs in 1987-1990. This trend, or lack of a trend, holds for each field. It does not rule out, however, substantial increa ses in unemployment since 1991.
The percentage not employed for all reasons (e.g., not looking, retired, or unemployed) has also been low and steady since 1973, about 3%.
The proportion of new PhDs employed part-time has increased by about 50%-from 2% in 1973 to 3.1% in 1991 (totaling about 1,100 of 58,000 in 1973 and 2,000 of 63,000 in 1991). This trend was shown in all science fields, except that part-time employment t ripled among new social scientists, from 2% to 6%. Part-time employment did not increase among new engineering PhDs (it has been about 1% since 1973).
The category with the most significant change has been the proportion of recent doctorates employed in postdoctoral appointments. Just 8% of the 1969-1972 PhDs were postdoctorates in 1973, a percentage that increased steadily to 19% of the 1985-1988 PhD s in 1989 (the 1991 survey was delayed six months, so the postdoctorate percentage is lower--14%). Most postdoctorates were among new biology PhDs (2,000 in 1973 and 6,300 in 1989), and most of the rest were in physics/astronomy and chemistry (1,900 in 1 973 and 2,800 in 1989).
5-8 Years Out For those 5-8 years out at the time of each survey, the pattern is similar except that few are in postdoctoral appointments. The percentage of unemployed is generally lower than for those 1-4 years out-between 0.7% and 1.3%-but it i ncreased to 1.9% in 1991. The percentage not employed for other reasons was up a little in 1991, but 97% were still employed. The proportion employed part-time doubled to 3.2% in 1991 but was still low.
Conclusion If there are major employment changes or problems, they have arisen mostly since 1991. The employment statistics are all relatively good, but some were slightly worse in 1991 than in 1987 or 1989. Even that is difficult to interpret, because the survey procedures were changed in 1991 and the response rate was much higher.[1]
Figure C-1 shows where all science and engineering PhDs were employed 1-4 years after receiving their doctorates, and Figure C-2 shows w
here they were 4 years later (5-8 years after receiving their doctorates.); Tables C-1 and C-2 give the numbers and percentages on which th
e figures are based. Figure C-1 confirms the steadily growing proportion going into postdoctoral positions during the 1970s and 1980s (8% in 1973 and 19% in 1989, as noted above)[
2] as well as the growing proportion going into business and industry (22% in 1973 and 29% in 1991). A smaller proportion went directly into academic employment (49% in 1973 and 40% in 1991)(presumably, some were going into postdoctoral positions ins
tead).
Figure C-2 shows where science and engineering are 5-8 years after receiving their doctorates. Not surprisingly, few are in postdoctoral appointments, although the percentage increased from 2%
to 3% over the period (but it increased from 4.8% in 1973 to 9.2% in 1989 among biologists 5-8 years out). The proportion employed in academe fell. More than half the 1969-1972 PhDs were employed in academe 5-8 years later, compared with 45% of the 198
3-1986 graduates in 1991. This trend is the basis of a major conclusion of the report-that most new PhDs are employed outside academe.
Another way of looking at the trend is to compare the same "class" 1-4 years and 5-8 years out (Figures C-3 to C-5). Over the period, there is an increasing falloff from the number of those on postdoctorates a
nd employed in academe in the first 1-4 years to the number employed in academe plus postdoctorates after 5-8 years (this is true, although to different degrees, across fields).
The growth sector was business and industry. After 5-8 years, 26% of science and engineering PhDs were employed in business and industry as of 1973, a proportion that grew to about 45% in 1991 (Figures C-3 to C-5<
/A>).
The employment patterns differ from field to field (see Figures C-6 through C-18 for those 1-4 years out and Figures C-19 through C-31 for those 5-8 years out). So
me fields such as chemistry and engineering, have long had a high percentage of PhDs working in industry; others have had high percentages working in academe. Within the sciences, however, the trends have been similar--a smaller proportion going into aca
deme and the federal government, and a greater proportion going into business and industry (there was also noticeable growth in nonprofit employment among social scientists). Engineering is one field in which the percentage working in academe after 5-8 y
ears, although relatively low, has increased (from 29% in 1979 to 32% most recently), as has the percentage working in business and industry (from 50% to 58%). The federal government was the big loser, going from 13% (1,600 of the class of 1969-1972 in 19
77) to 5% (about 500 of the class of 1983-1986 in 1991).
Table C-2 has some interesting data on trends in tenure and tenure status within academe among those 5-8 years after receiving the PhD. The number of academics with tenure fell both absolutely an
d relatively over the period. In 1979, for example, 20% of all those who had received their PhDs 5-8 years before (1971-1974) had tenure, and another 14% had tenure-track positions. The percentage with tenure after 5-8 years fell steadily to 12% in 1989
, while the percentage in tenure-track positions grew to 17%. In absolute terms, the number with tenure after 5-8 years fell from 12,000 in 1979 to 6,500 in 1989, while the number in tenure-track positions went from 8,000 to 9,000. (The 1991 survey incre
ased the percentage with tenure to at least 14%; the extent to which the change in survey methods contributed to this change needs to be explored.)
In another way of looking at the data, the total number in the tenure system of those 5-8 years after receiving the PhD fell from 20,000 in the 1979 survey to about 16,000-17,000 in the 1989-1991 survey, and the proportion with tenure decreased relative
to those still in tenure-track jobs.
Meanwhile, a fairly steady number and percentage of PhDs 5-8 years out had non-tenure system positions over the period (about 7,000, or 12% of all PhDs 5-8 years out).
The figures differ from field to field, although the general trends hold. Biology is interesting because the percentage with tenure, low in 1979 at 18% fell to 7% in 1989, while those in tenure-track positions or not in the tenure system stayed about th
e same. Presumably, that reflects the high and growing proportion of postdoctorates and the lengthening time before biology PhDs enter faculty positions and begin their quest for tenure. In fact, as noted above, more than 9% of biologists were still in
postdoctoral positions 5-8 years after receiving their PhDs. That in turn might be part of the explanation for the low and falling percentage of principal investigators under 35 years of age applying for National Institutes of Health research project gra
nts, as reported in the recent National Research Council study of funding of young investigators (NRC, 1994a).
The new data presented here on science and engineering 1-4 and 5-8 years after receiving their doctorates give a sense of the career-related flow of new PhDs. The flows also have an impact on the overall stock of PhDs. More than 14,000 new doctorates w
ere added each year to the total stock of PhDs working in the United States, and small shifts in employment patterns have a cumulative impact over time on the whole. Table C-3 presents data on the
employment of all US PhDs at the time of each survey.
As a result of the steady output of doctoral science and engineering, the overall number of people with science and engineering PhDs from U.S. universities working in the United States has nearly doubled since 1973. Academe has absorbed a large number
, 70,000, or about 3,900 a year. Business and industry have absorbed another 104,000, or 5,800 a year. The latter has been the growth sector for PhD employment, and is likely to remain so for future PhDs.
The National Science Foundation conducts biennial surveys of recent recipients of master's and bachelor's degrees in various science or engineering fields. The latest published data are from the survey administered in the spring of 1990 to a sample who
received science and engineering degrees during the 1987-1988 (1988) and 1988-1989 (1989) academic years (NSF, 1992a). Surveys conducted in 1982 (NSF, 1984), 1984 (NSF, 1986), 1986 (NSF, 1987), and 1988 (NSF, 1990a) are also reported here. A more recent
survey was fielded in 1993 and is scheduled to be published shortly.
The NSF survey of recent college graduates and master's-degree recipients collects information on demographic and education characteristics and on early career-development experiences, such as employment status, reasons for unemployment, and attributes o
f employment including occupational classification, major activity, and salary. The survey is based on a nationally representative sample and is used to derive national estimates of the numbers and demographic, education, and employment characteristics o
f recent graduates in science and engineering.
The number of new science and engineering master's-degree recipients in 1989 continuing as full-time students in 1990 was 16,200, or about 23% of the estimated 70,400 who received master's degrees in 1989 (another 4,900, or 7%, were part-time students)(<
A NAME="t4">Table C-4). The comparable percentage and number of continuing students among new master's-degree recipients in the 1980s surveys were about 21% and 10,000 - 13,000.
The tendency to continue graduate studies full-time varies across fields but has increased in most fields since 1982. Barely 7% of those receiving master's degrees in computer science in 1989 were full-time students the next year, compared with 60% of th
ose with new physics/astronomy master's degrees (Table C-5). The proportion of new master's-degree recipients going to graduate school part-time also varies from field to field but has gone down s
ince 1982. The ratio of full-time to part-time graduate students a year after receipt of master's degrees also varies by field. In fields where the master's degree is usually considered the working degree, the ratio is more nearly equal (e.g., 2.2:1 in
engineering and 1:1 in computer science and technology) than in fields where the PhD is considered the minimal professional credential (e.g., 3.6:1 in physics/astronomy, 22.6:1 in biology, and apparently higher in chemistry).
Unemployment rates among recent science and engineering master's-degree recipients in the labor force are low. In 1990, among those awarded master's degrees in 1988 and 1989, unemployment was 1.8% overall, ranging from a low of 1.1% of mathematicians and
statisticians to a high of 3.6% of psychologists (Table C-6). In most fields, the unemployment rate among recent master's-degree recipients was lower in 1990 than in 1982 and 1984 (in the afterma
th of the 1980-1982 recession), but slightly higher than in 1988.
Although unemployment rates are comparatively low for those with master's degrees, not all are working in the fields of their degrees or in other science and engineering occupations. Overall, in 1990, fewer than two-thirds of science and engineering mas
ter's-degree recipients were working in the same fields as their degrees, and fewer than one-fifth were working in other science and engineering occupations (Table C-7). Exactly 17% were not emplo
yed in science and engineering occupations. This split varied by field, however, with 7.5% of engineers and 8% of computer scientists working outside science and engineering, compared with 37% of social scientists and 46% of psychologists. Only one-four
th of physicists and astronomers were working in their fields (25% were working in computer science and "other physical sciences," and 25% in engineering occupations) (NSF, 1992b:Table B-39).
In the last decade, nearly 60% of employed new science and engineering master's-degree recipients were working in the private sector (Table C-8). Less than 20% were employed by educational institu
tions, split about evenly between four-year colleges and universities and other institutions (two-year colleges and elementary and secondary schools).
The tendency to work in industry or for other types of employers varies by field. In 1990, for example, more than three-quarters of computer scientists worked in the private sector, compared with less than a third of life scientists (Table C-9).
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