1. Descriptive background

Older workers, defined as those who are aged 55 or above, represent a rapidly growing segment of the workforce. In 2000 older workers accounted for 12% of all employees; by 2019 their share had increased to 22%. Over the same period, the share of younger workers (16–29) held roughly constant in the 26–27% range whereas the share of middle-aged workers (30–54) fell from 60% to 52%. The drop in the share of middle-aged workers largely reflects the aging of the baby boomer population.

Before turning to the distribution of older workers by industry, it is instructive to take a quick look at how worker and job characteristics have changed over the last 20 years for this age group. Appendix Table A1 reports data on older workers from the American Community Survey public use files for 2001 and 2019. As the older cohorts exit from the labor market and are replaced by younger cohorts, older employees in 2019 have more years of schooling than their counterparts in 2001. The occupational mix adjusted as well, with more managerial and professional jobs and fewer positions in sales, support, and production occupations. The overwhelming majority of older employees work 35 or more hours per week. The shape of the age distribution of older employees changed between 2001 and 2019, with a shrinking percentage in the 55–59 bracket and a growing percentage in the 60 and over bracket. This reflects both cohort aging and longer careers.

Average hourly earnings of older workers rose by 66.6% ($20.89–34.80) between 2001 and 2019. As a benchmark the annual personal consumption expenditure deflator rose by 38.0% over this period. It should be kept in mind that the composition of the older workforce changed considerably over this period, with higher levels of education and a larger percentage of professional workers as noted above. Over the same period, average hourly earnings increased by 55.4% for 16- to 29-year-olds ($12.14–18.88) and by 58.7% for 30- to 54-year-olds ($20.00–31.76). On the surface this might infer that demand for older workers increased over this period in that they gained in terms of both employment share and relative earnings. It also is possible that educational attainment among older workers increased more for older workers during this period than it did for middle-aged or younger workers.

Labor mobility, or lack thereof, is a critical driver of any changes to be observed in the age distribution of older workers across industries. Allen (Reference Allen2023) demonstrated two notable trends over the last 20 years. First, job tenure for older workers increased for those 65 and over. Among women the percentage who have been with their employer for 20 or more years increased from 23% to 26% between 2000 and 2020. The same share for 65 and older men increased from 28% to 34% between 2000 and 2008. It then dropped to 30% in 2010 as a consequence of the Great Recession and essentially stayed at that level through 2020. There are also slight increases in long-term job holding for men (30.6–31.4 years) and women (24.3–24.6) in the 55–64 age bracket.

Second, the odds that an older worker is in a new job have decreased substantially. Among men, 11.2% of those aged 55–64 and 14.4% of those 65 and over were in new jobs in 2000. By 2020, these percentages dropped to 9.8% and 9.7%. The percentage of women with a new employer declined as well, from 11.3% to 9.5% for the 55–64 age group and from 11.5% to 8.2% for the 65 and over group. The main driver for any changes in the age distribution of workers in an industry will be workers staying in their jobs longer as opposed to a rising share of older workers pursuing new work opportunities.

The percentage of workers aged 55 and above in an industry is an intuitive measure at a given point in time of how intensively older workers are employed in that industry. A key question in this paper is how and why this percentage varies across industries and within industries over time. Figure 1 displays a scatterplot of this percentage for 60 industries in 2001 and 2019; the raw data are reported in Table A2. It shows that there is a very wide range in the share of older workers across industries in both years. It also displays a strong positive correlation between the percentage of older workers in a given industry in 2001 and 2019; nearly 40% of the variation in the 2019 values can be explained by the 2001 values in a simple ordinary least squares (OLS) regression.

Figure 1. Percentage of older workers by industry, 2001 to 2019 American Community Survey.

As a benchmark, the average industry had 13% older workers in 2001 and 23% in 2019, a 10-point increase. Table A3 shows that it increased at a slightly higher rate in the 17 industries with the highest average share of older workers (11.0 points) as opposed to the 14 with the lowest (8.2 points). Among the industries that have the highest share of older workers, the increase in their share ranges from as low as 2 percentage points (railroads) to as much as 15 points (paper, utilities). Looking at the industries that have the lowest share of older workers, the change ranges from a low 3 points in motion pictures and restaurants to a high of 13 points in rental and leasing services. The change in the age mix of employees is far from a uniform process across industries.

A simple shift-share analysis shows that changes in the distribution of all workers across industries has had no impact on the overall change in the percentage of workers who are 55 or older. Using 2001 employment weights, the mean percentage of older workers in ACS is 12.6%. Continuing to use the 2001 values of the percentage of older workers but shifting to 2019 employment weights, the mean percentage of older workers is 12.5%. This indicates that we need to focus on within industry changes, not shifts in the mix of industries.

With the percentage of older workers growing in every industry, the percentage of workers younger than 55 must fall correspondingly. One issue of concern is whether the rising share of older workers has made it more difficult for younger workers to get hired. Such displacement could take place in organizations if older workers delay retirement and the establishment's headcount remains constant. This is a modern twist on the lump of labor argument and does not consider (1) overall economic growth and (2) births and deaths of establishments. Alternatively, the rising share of older workers could merely reflect the aging of baby boomers. Appendix Figures A1 and A2 display the raw data for the changes in the percentages of younger (16–29), middle-aged (30–54), and older workers by industry. There is no correlation in Figure A1 between the growth in the percentage of older workers and the change in the percentage of younger workers across industries. This casts initial doubt concerning the issue of potential displacement of younger cohorts by older generations. By necessity, this leaves us with an inverse relationship between the growth in the percentage of older workers and the change in the percentage of middle-aged workers in an industry, as displayed in Figure A2. This most likely reflects the aging patterns within each industry; most middle-aged workers in 2001 fall into the 55-plus category by 2019.

2. What determines an industry's age mix?

This study starts with the basic premise of labor demand: firms select optimal combinations of different types of labor and capital based on their relative productivity and cost, while also considering which combinations work best and the adjustment costs associated with changing the mix of inputs. The age-mix of any company or establishment hinges upon a wide range of considerations, including decisions about organizational boundaries, job design, hiring, training, and compensation.Footnote ⁵ The age structure of an industry reflects at an aggregated level the hierarchies and organizational structures of the establishments in that industry. Keep in mind that the mix of firms within each industry changes over time. Facebook and Tesla are not part of the data sets in the early 2000s whereas Enron and Lehman Brothers are not there in the 2010s.

Here we will consider younger, middle-aged, and older workers as separate inputs into a production function. This function also includes multiple types of capital, including specific types of equipment, structures, and intellectual property as inputs. The age-mix of the workforce reflects these considerations:

The productivity and cost of different types of labor: In the simplest production function framework, firms adjust the mix of age groups just as they would any set of inputs so that the ratio of marginal product to the cost of each input is equalized. Suppose initially that workers of all ages are doing the same jobs. Theory and evidence summarized in Allen (Reference Allen2023) both indicate an upward sloping age–earnings profile, albeit with some flattening around age 62. Non-wage labor costs associated with DB pensions, health insurance, and paid time off also increase with age. If there are not corresponding increases in productivity, a firm will use relatively more younger workers. The evidence on age and productivity, summarized in Allen (Reference Allen2023), does not indicate that there is a corresponding upward sloping age–productivity profile.

Complements or substitutes: In most organizations there is a hierarchy of jobs, and within that hierarchy there is a sorting by age group into the various positions. If the hierarchy has multiple levels and the knowledge and skills needed vary across these levels, then older and younger workers would serve complementary roles. For instance, younger workers might have a relative advantage in production tasks whereas older workers might have an advantage in managing customer or supplier relationships. Even within a job category, Bersin and Chamorro-Premuzic (Reference Bersin and Chamorro-Premuzic2019) argue that a mix of older and younger workers leads to increased cognitive diversity and improved performance. In situations where jobs are homogeneous, younger and older workers would be substitutes.

Hiring costs and human capital: There are fixed costs associated with bringing a new worker into an organization and training that person. These costs vary across and within organizations. In cases where it is easy to find new workers and there are negligible training costs, then we would expect firms to be indifferent about their age mix as long as wage rates are being held constant. Firms faced with sizable up-front investments in new hires have a retention incentive that should result in more older workers on the payroll. Firms that make significant investments in firm-specific human capital will be especially more interested in hiring young workers and retaining older workers.

Customer demand: Although they must be mindful of age discrimination issues, some employers consider customer preferences when making staffing decisions about customer-facing jobs, especially in youth-oriented industries such as entertainment and hospitality. There is a flip side. Customer preferences help explain why shoe repair, retail florists, religious organizations, and funeral homes are among the industries with the highest percentages of older workers.Footnote ⁶

Technology: Whether based on perceptions or reality, the adaptability of workers to changes in technology influences employer decisions about age mix. Younger persons have more recent training, as well as a longer time horizon to benefit from investments in new knowledge and skills, than older workers. In contrast, older workers have more perspective from their experience and will accurately realize in some cases that the latest new way of doing things need not be the most appropriate.

In light of these considerations, what would we expect age distributions to actually look like? The age distribution would be flat in situations where the firm stays the same size, hires at the entry level, emphasizes training and promotion from within, and sets new hires equal to retirements. In firms that hire at multiple levels of the age distribution, there would still be a flat distribution if hires equal separations within each age group. The age structure should tilt heavily toward young workers if human capital investments are modest or if there is an inverted-pyramid hierarchy with few opportunities to advance. Such a tilt also would be observed in growing firms if most new hires come from the lower tail of the age distribution. A tilt toward older workers would take place in situations where there has been little hiring for a decade or more, where wage differentials by age are less than the productivity differentials, or where customer preferences dictate a tilt toward older workers.

3. Empirical framework

The central question to be examined in this research is what factors have determined why the share of older workers has risen significantly in some industries between 2001 and 2019 and relatively little in others. A natural choice for a dependent variable is the change in the percentage of older workers in an industry. The appeal of this measure is that it provides information about which sectors are adding or retaining more older workers relative to younger workers. A challenge is that it is difficult to interpret directly as an index of labor demand. An industry could have a rising percentage of older workers simply by having markedly fewer younger or middle-aged workers. This can happen if there are employment reductions and seniority is the key element in retention decisions. It also can happen if an industry stops growing and stops hiring.

Another way to examine the determinants of the changing age mix of employment by industry is to examine reduced form models of changes in employment by age group. To be specific, suppose that the change in employment for each age group a (where y = young, m = middle-aged, and o = old) in industry j can be expressed as

(1)$$dL_{aj} = \theta _aX_j + \gamma _aK_j + \delta _aw_{aj} + \varepsilon _{aj}, \;$$

where dL indicates change in log employment for age group a in industry j, X is a vector of control variables reflecting industry characteristics, K is the capital–labor ratio, and w is the log wage rate. All right-hand variables are measured at the start of the sample period. Taking first differences of (1) between the demand for older workers and the demand for young and middle-aged workers respectively, we have the estimating equations:

(2a)$$dL_{oj}- dL_{yj} = ( \theta _o- \theta _y) X_j + ( \gamma _o- \gamma _y) K_j + ( \delta _ow_{oj}-\delta _yw_{yj}) + ( \varepsilon _{oj}-\varepsilon _{aj}) $$

(2b)$$dL_{oj}- dL_{mj} = ( \theta _o- \theta _m) X_j + ( \gamma _o- \gamma _m) K_j + ( \delta _ow_{oj}-\delta _mw_{mj}) + ( \varepsilon _{oj}-\varepsilon _{mj}) $$

An underlying assumption in this framework is that the wage coefficient varies for each age group. If instead δ_o = δ_m = δ_y, then we have a simpler framework:

(3a)$$dL_{oj}- dL_{yj} = ( \theta _o- \theta _y) X_j + ( \gamma _o- \gamma _y) K_j + \delta _o( {w_{oj}-w_{yj}} ) + ( \varepsilon _{oj}-\varepsilon _{aj}) $$

(3b)$$dL_{oj}- dL_{mj} = ( \theta _o- \theta _m) X_j + ( \gamma _o- \gamma _m) K_j + \delta _o( {w_{oj}-w_{mj}} ) + ( \varepsilon _{oj}-\varepsilon _{mj}) $$

A key aspect of this approach is that the change in employment is posited as a function of initial values of the right-hand variables. These models are designed to answer the question of what is likely to happen to the employment of older workers in the future based on what we know at a given point in time. These are by no means to be interpreted as structural models of labor demand. However, they should be informative about certain matters. For instance, did the employment of older workers relative to other groups increase, not change, or decrease in industries with high capital–labor ratios or those making intensive use of information technology? Similarly, how does the relative employment of different age groups vary by employer characteristics such as firm size, occupational mix, or pension coverage?

The model includes the overall capital–labor ratio along with interaction terms that allow the capital–labor coefficient to vary for types of capital associated with information technology, instrumentation, and intellectual property. One challenge in this framework is the issue of whether initial values of K can truly be considered exogenous. On the surface one could argue that, since many of the workers aged 55 and over in 2001 were hired in the 1970s and 1980s, their employers could not have foreseen when they were hired the changes in information technology that impacted the workplace in the 2000s and 2010s. However, there are industries where employers have long planning horizons and changes in employment, both overall and by age group, are intricately related to their investment decisions. Because the length of planning horizons and the pace and predictability of technical change varies across industries, it is very difficult to structurally model how investment decisions impact employment of workers in different age groups. The goal here is to observe whether there is a correlation between technology and the employment share of older workers. Because of the strong likelihood that future values of K are related to both (1) initial values of K and (2) changes in employment patterns in some sectors, it will not be possible to make a structural interpretation of the K coefficients.

Two things can be established by examining the impact of including the wage rate variable. First, the raw data show that older workers became a growing share of the labor force over the last 20 years. If the inter-industry correlations show a corresponding increase (decrease) in relative wages over that period, it would provide a signal as to whether a demand (supply) increase was an important factor. Second, it would be worthwhile to determine whether the results for other variables are robust to inclusion of w. The log ratio of average weekly earnings of older workers compared to younger workers (aged 16–29) measures w. To control for worker heterogeneity across industries, controls for worker education, occupation, and gender are included in the model.

Other variables are included in the model to capture market, worker, and workplace characteristics that would likely influence changes in the age structure. Previous studies have shown that the shift from DB to DC pensions has contributed to the rising employment–population ratio for older workers. In the context of this study, this calls not just for the inclusion of a measure of pension coverage, but also for consideration of how many workers are covered by which type of plan. There should be relatively few older workers in industries where DB plans dominate because of the incentives for early retirement often found in such plans. In contrast, DC plans rarely have provisions that spike pension wealth at specific ages or seniority dates, so we should expect a higher percentage of older workers in industries where most workers are covered by DC plans.

Union density is included because firms have fewer degrees of freedom to manage the age mix of employees when covered by a collective bargaining agreement. We also include controls for firm size and the percentage of workers with 20 or more years of tenure. Large firms are likely to provide more career opportunities and paths, so we might expect them to have a higher percentage of older workers. Some firms commit to long-lasting careers for their workers and there would be a higher percentage of older workers in such firms if these relationships are stable over time.

Lastly, we include the rate of output growth and its variance over the 10 years preceding the sample period in the model. Between 2001 and 2019, the log change in real value added ranged between 2.047 in data processing, internet publishing, and other information services and −0.8 in apparel and leather and allied products. During growth periods firms typically add proportionally more young and middle-aged employees than older employees, whereas during periods of industry decline most separations occur among younger workers. The variation in output growth has an independent effect on the age structure. Imagine two industries with the same average growth over a given period, one on a steady path and the other with repeated ups and downs. The latter industry will end up with a sizable contingent of older workers sheltered from the ups and downs, accompanied by fewer younger and middle-aged workers.

4. Data sources

Because the concern here is labor market trends rather than year-to-year fluctuations, the focus will be on three intervals: 2001–2007, 2007–2019, and 2001–2019. The choice of intervals controls for the business cycle; the initial and final year in each period is a business cycle peak.

The main data source for this study is the ACS for 2001 through 2019. ACS data are available for 2000 but the sample size is considerably smaller that year, resulting in noisy measures for smaller industries that become noisier still when first differenced over 19 years. Employees are defined as wage and salary workers; the self-employed and military are not included. The ACS was used to calculate total employment in each industry, along with its age breakdown into three groups (16–29, 30–54, and 55 and over). Average hourly earnings are estimated for each age group using continuous measures of wage and salary income, usual weekly hours, and weeks worked. Measures of percentage college graduates, percentage female, and percentage in managerial or professional occupations also were pulled from the ACS. These percentages are calculated across employees from all age groups combined.

Capital data come from the Bureau of Economic Analysis (BEA) of the US Census, which publishes Current-Cost Net Capital Stock of Private Non-residential Fixed Assets data for 62 industries and 96 categories of capital.Footnote ⁷ In the empirical analysis total capital is defined as the sum of equipment, structures, and intellectual property products (IPP). To determine whether the employment of older workers is impacted by advanced technology, the capital coefficient is allowed to vary with different types of capital associated with information technology, instrumentation, and intellectual property. The measure used in the first set of results reported here includes 14 types of computing, instruments, and office equipment along with five types of IPP. The robustness of the results to alternate definitions is examined below.

Real value added by industry as calculated by BEA was used to construct two control variables: output growth over the 10 years preceding the sample period and the variance of output growth over the same interval.Footnote ⁸

Industry measures of percentage covered by union contracts, percentage working in large firms, percentage covered by pensions, and percentage of employees with 20 or more years of service were pulled from the Current Population Survey. Lagged values from the 1990s were used to minimize issues related to reverse causation with the dependent variable. The union variable comes from the outgoing rotation groups in the merged 1992–93 CPS public use files. The firm size measure comes from the Annual Social and Economic Supplement (ASEC) for the same years. The years of service data come from the 1996 and 1998 Job Tenure and Occupational Mobility Supplements. The pension coverage data come from the 1999 CPS ASEC so that estimates of the percentage in DB and DC plans could be obtained from the public use files of Internal Revenue Service (IRS) Form 5500, using data on plan participants and plan characteristics. Public use files for Form 5500 are not available for download for years before 1999.

Industry definitions were established by matching North American Industry Classification System (NAICS) codes in the ACS with those used in BEA data sets on output and capital. Governments were not included as separate industries because the capital data pertain solely to the private sector. The empirical analysis is based on 60 industry categories which are listed in the data appendix.Footnote ⁹ The limiting factor for industry definitions was the 62 industry categories in the BEA capital data set. Two pairs of industries had to be combined. Securities, commodity contracts and investments (NAICS code 523) and funds, trusts, and other financial vehicles (NAICS code 525) have the same detailed industry code in the ACS. Hospitals (NAICS code 622) and nursing and residential care facilities (NAICS code 623) are combined in the pre-1997 data used for lagged GDP values.

5. Empirical results

Table 1 reports regressions of the first difference in the percentage of older workers for three different time periods: 2001–2007, 2007–2019, and 2001–2019. Two models are reported for each period: one excluding and one including the ratio of log wages of older workers to younger workers. The key results are as follows:

1. (1) Pension coverage is the strongest predictor of which industries had the largest growth in the share of older workers. The growth in the percentage of older workers in an industry is largest in those industries where most workers are covered by a pension plan. Compare two industries – one where no workers are covered by a pension and one where all are covered by a pension. Growth in the percentage of older workers was 6.1 percentage points higher between 2001 and 2007 and 12.8 points higher between 2007 and 2019 in an industry where all workers were covered by a pension as compared to an industry where none were covered.

2. (2) The share of older workers grew most between 2007 and 2019 in the industries with the highest ratios of high-tech capital to labor. The capital–labor ratio itself was weakly and inversely related to the growth in the share of older workers in an industry. To examine the practical magnitude of this relationship, consider the following industry comparison. The mean high-tech capital–labor ratio across all industries in 2007 was 19.5; the standard deviation was 28.5. Compare two industries: one with the mean high-tech capital–labor ratio and one where the ratio was twice as high. Considering that a doubling of the high-tech capital–labor ratio also leads to an increase in the overall capital–labor ratio, the growth in the percentage of older workers is 0.85 percentage points higher in the industry with the higher high-tech capital ratio. Admittedly this is not a huge difference, especially over a 12-year period. However, the key takeaway is that the employment share of older workers was growing fastest in high-tech industries.

3. (3) The percentage of older workers in an industry decreased in those industries with the most rapid output growth in the 10 years preceding the sample period. This no doubt reflects the fact that expanding firms hired mostly young workers. The magnitude of the coefficient is small; a 10% increase in output growth is associated with a 0.1 percentage point decline in the percentage of older workers.

4. (4) The growth in the share of older workers in an industry is unrelated to the relative wage differential between the old and the young. The coefficient of the wage variable is both small and measured with little precision. Further, the coefficients of the other variables are not sensitive to the addition of the wage variable. There is no evidence of increased demand for older workers within industries.

5. (5) There were two counterintuitive results. The growth in the share of older workers was lowest in industries with the largest share of college graduates and in industries that had relatively large numbers of workers with 20 or more years of tenure in the 1990s. This could reflect higher initial values of the percentage of older workers in these industries that limited opportunities for large first differences.

6. (6) There is not a stable relationship between the change in the share of older workers and the independent variables examined here. The coefficients for 2001–2007 and 2007–2019 are often quite different, sometimes with opposite signs.

Table 1. Regression results: first difference in percent older workers

Standard errors in parentheses.

* p < 0.10, **p < 0.05, ***p < 0.01.

These results are based on first difference analysis of employment levels by age group in 60 industries. Employment levels vary considerably across industries. The average industry in the sample had 1.9 million workers in 2001, with a range from 33,000 (pipeline transportation) to 14 million (retail trade). If some very large industries ended up being statistical outliers, the results could change considerably if the regression were weighted by industry size. Also, hours per person vary across industries, with some making intensive use of part-time workers and others relying heavily on overtime. To address these considerations, the models in Table 1 were re-examined by (1) weighting each observation by the sum of employment at the beginning and end of the sample period and (2) recalculating the dependent variable so that it is measured in labor hours instead of employees. The results, reported in Tables A4 and A5 in the Appendix, show that neither weighting the regression nor changing the dependent variable made any meaningful difference in the findings.

The pension coverage variable does not distinguish between DB and DC plans. Estimates of the percentage covered by each type of plan were derived from IRS Form 5500 data for 1999 by counting the number of active participants in DB and DC plans for each of the 60 industry groups. The models in Table 1 were then re-estimated using separate variables for the percentage of workers covered by DB and DC plans; the results are reported in Table A6 in the Appendix. In 2001–2007 and 2007–2019 the coefficient for DC plans is roughly the same as the coefficients for all plans in Table 1, whereas the coefficient for DB plans is not measured precisely. For the 2001–2019 period, the coefficient for DB coverage is 50% larger than the coefficient for DC coverage but the hypothesis that the two coefficients are equal cannot be rejected. Although the impact of DB and DC plans on retirement and retention might be expected to be different, this does not show up in this exercise.

One might question how robust the results for high-tech capital in Table 1 are to potential changes in the classification of which types of capital are considered high tech. The measure used in the regression models includes 14 types of equipment and five types of intellectual property products (IPP). The BEA provides data on 20 additional categories of IPP. To examine the sensitivity of the results to the inclusion of IPP, three additional high-tech capital–labor ratio variables were examined. One of the variables included high-tech equipment but no IPP. One added software-related IPP, namely prepackaged software, custom software, and own account software, while omitting software publishing and computer systems design. The third added all 25 IPP categories to the high-tech equipment, including IPP in aerospace, motor vehicles, and pharmaceuticals. As shown in Table A7, the coefficients of the first two alternate variables in 2007–2019 are like that of the one in Table 1. In contrast, the coefficient for the most inclusive measure is consistently smaller than its standard error. Overall, it is clear that as long as high-tech capital is defined as the usage of information technology then the results for this variable are quite robust. On the other hand, the presence of other types of IPP in an industry does not seem to have any relationship to its increased usage of older workers.

This empirical framework has focused on aggregate industry data. It is entirely possible that the changes in the percentage of older workers within an industry vary by skill; managerial and professional workers may have delayed retirement but those in other jobs have not. To explore this issue, the industry cells in ACS were split by education level, with one set of data points corresponding to those with 12 years or less of completed schooling and another set consisting of those with more than 12 years of schooling. Industries with a high percentage of older workers in one schooling group also tend to have a high percentage of older workers in the other group; the correlation coefficients for the 60-industry sample are 0.57 in 2001 and 0.70 in 2019. Also, industries with the biggest increases in the percentage of older workers who have higher education levels between 2001 and 2019 tend to be the industries with the largest increases in that percentage for workers with less education; the correlation coefficient is 0.58. The message to draw from this exercise is that the aging patterns within an industry tend to be similar across education levels.

Although aging patterns within industries tend to be similar across different education levels, there is still the question of whether the coefficients for key variables such as pension coverage and high-tech capital vary by schooling levels. The model in Table 1 was re-estimated over two different samples: one where the variables from the ACS all pertained to those with 12 years of schooling or less and another where the ACS variables all pertain to those with more than 12 years of schooling. This framework allows for complete interactions between all the independent variables and the two schooling categories. The results for the pension and high-tech capital–labor ratio variables are reported in Table A8.

Pension coverage continues to be strongly associated with a rising percentage of older workers in an industry for both groups over the entire sample period and for those with 12 years or less of schooling in 2007–2019. The association between pension coverage and aging is weaker for both schooling groups in 2001–2007 and for the group with higher schooling in 2007–2019. One possible explanation for this pattern is that pensions for those with no post-secondary schooling shifted from DB to DC plans over the sample period whereas pensions for those with post-secondary schooling were DC throughout, resulting in more delayed retirement among those with no post-secondary schooling.

The high-tech capital–labor ratio results from Table 1 continue to hold for workers with post-secondary schooling, but not for their counterparts with less schooling. The coefficients in Table A8 of this variable for 2007–2019 for the two groups are quite close to each other; they are also quite close to the coefficient in Table 1. However, the standard errors for the group with no post-secondary schooling are considerably larger. The argument that older workers are complements to high-tech capital appears to hold much more strongly for those with post-secondary schooling, perhaps because more schooling is needed to be an effective complement to such capital.

The results reported so far reflect changes in the share of older workers compared to the combined share of younger and middle-aged workers. The last logical step is to compare the growth in employment of older workers to that of each of the other two groups by estimating equations (3a) and (3b). These estimates are reported in Tables 2 and 3, using the same independent variables as before.

Table 2. Regression results: relative log employment growth of older and younger workers

Standard errors in parentheses.

* p < 0.10, **p < 0.05, ***p < 0.01.

Table 3. Regression results: relative log employment growth of older and middle-aged workers

Standard errors in parentheses.

* p < 0.10, **p < 0.05, ***p < 0.01.

Overall, the main results from the analysis of inter-industry differences in the percentage of older workers hold when we separately examine young-old and middle-aged-old differences. Employment growth of older workers was more rapid than employment growth of younger workers between 2001 and 2007 in industries with higher levels of pension coverage. This was the case for the employment growth differential between older and middle-aged workers for the entire sample period. Industries with the highest ratios of high-tech capital to labor saw the largest growth in the employment of older workers relative to employment of the other age groups (although the relationship for middle-aged workers is somewhat weak in 2001–2007). Output growth narrowed the spread in employment growth between older workers and their middle-aged and younger counterparts. The anomalous results for industries with high percentages of college graduates and industries with a tradition of having long employment relationships continue to appear.

Three new patterns do appear in Tables 2 and 3. First, the growth of employment for older workers was much slower than that for younger workers in industries with high percentages of unionized workers. These industries tend to still have DB pensions in place for production workers, potentially limiting the growth of employment of older workers. Union density has a mean of 19% and a standard deviation of 16%. Compare two industries, one with 20% union members and one with 40% union members. The industry with more union members would have 0.12 higher log employment growth among younger workers than older workers between 2007 and 2019. Second, the growth in employment of older workers compared to middle-aged and younger workers was lower in industries with high percentages of women. This could reflect higher percentages of women in the 2 younger age groups. Third, the change in employment of older workers relative to young or middle-aged workers was lowest in industries with the highest overall capital–labor ratios. This relationship was particularly strong for the old versus young results in Table 2 for 2001–2007. Perhaps older workers are substitutes for traditional capital equipment and complements for high-tech capital.

In summary, two major themes arise from this analysis. First, pension coverage and pension characteristics are strongly related to changes in the age structure of industries over time. One possible interpretation of the results is that as the first generation of workers covered largely by DC plans hit the later stages of their working career, they decided to stay on the job longer. At the same time the union results in Table 2 suggest that DB plans work in the opposite direction, generating earlier exits for older workers and more opportunities for younger workers. Second, there does not seem to be a technological backlash toward the employment of older workers, especially those with post-secondary schooling. To the contrary, there was actually more growth in the percentage of older workers in those industries that use the most high-tech capital.

5.1 Are younger workers being squeezed out?

As more older workers delay retirement, some have speculated that this had resulted in fewer opportunities for younger workers. The simple scatterplots in Figures A1 and A2 indicated that there did not seem to be a relationship between the change in the share of older workers in an industry and the share of younger workers. Now that we know variables such as pension coverage and the capital–labor ratio have an impact on changes in the deployment of older workers in an industry, it would be logical to revisit that issue in a regression framework.

The challenge is that the shares of older, middle-aged, and younger workers in an industry are not independent variables. Further, there is no genuine source of exogenous variation in the ability of firms to hire or retain workers in different age brackets across different industries. What can be done here is to see what the data tell us about any possible tradeoff between jobs for older and younger workers within a given industry. This is done in three ways in Table 4. First, to capture the raw data pattern we report a simple regression of the change in the share of younger workers on the change in the share of older workers. Second, the percentage of older workers will be used as an independent variable in an OLS model of changes in the percentage of younger workers over time. This will tell us whether covariates have any impact on the relationship. Third, even though there are no a priori reasons to exclude some of the independent variables in the model for older workers from the model for younger workers, there are correlation patterns suggesting that they could be excluded because of their explanatory power for one age group and lack of explanatory power for the other. The control variables are the same as those used in the previous models; results with and without the relative wage of older to younger workers are reported.

Table 4. Regression results: relationship between shares of older and younger workers

All equations were estimated over the 60-industry sample. Instrumental variables for 2001–07 included percentage female, GDP growth and pension coverage. Instrumental variables for 2007–19 included percentage college graduates and percentage of employees with 20 or more years of tenure in 1980s.

The key finding across all the results reported in Table 4 is that there is no evidence of any declines in the share of younger workers being related to increases in the share of older workers. The coefficients for 2007–2019 are quite small, ranging between 0.1 and −0.1. The coefficients for 2001–2007 and 2001–2019 are larger, running from 0 to −0.5. The null hypothesis cannot be rejected in any of the models. The conclusion that can best be drawn from this exercise is that, despite the best efforts being made to find a relationship between the shares of older and younger workers across industries, there is no such relationship to be found in this data set.

5.2 Imports and older workers

China joined the World Trade Association in 2001 and the resulting reduction in trade barriers led to a surge of imports into the USA. In 2001, the USA imported $8.5 billion worth of goods from China, increasing to $26.8 billion by 2007. Chinese imports peaked at $44.9 billion in 2018 and subsequently dropped to $37.6 billion in 2019 after both China and the USA took retaliatory trade measures.

Studies such as Autor et al. (Reference Autor, Dorn and Hanson2013) have established that the surge of imports from China resulted in a decline in manufacturing jobs in the USA. The question examined here is how older workers were impacted relative to younger workers. The 2001–2007 sample period used in our data set coincides with the period of the most rapid increase in Chinese imports, so this is likely to be the period where the impact of expanded trade with China has the largest impact. The 2007–2019 sample contains both the Great Recession and the ramping up of tariffs and other trade barriers after the 2016 US Presidential Election, so the results for that period may be less clear-cut.

One challenge that arises when examining this question concerns how to handle the 37 industries in the data set outside of primary goods and manufacturing. Here two approaches are considered. The first is to restrict the sample to the 23 industries for which trade data are tabulated. This requires a reduction in the number of independent variables to allow enough degrees of freedom to obtain precise estimates of the import penetration variables.

The second is to assign values of zero to the import penetration variables for non-traded goods as well as services. This is a reasonable approach for personal services such as haircuts and spa treatments. On the surface this approach would seem less reasonable for services such as travel; American tourists in Shanghai are in effect importing Chinese services. However, there is no evidence of any surge in Chinese service ‘imports’ that is in any way comparable to what has happened in manufacturing. Further, the service industries with zero imports are not total outliers in the distribution. Manufacturing industries with little to no change in Chinese import penetration during this period include food products, petroleum and coal products, chemicals, and primary metals.

Separate measures for Chinese and all other imports were created from USA Trade Online to estimate the impact of increased import competition on the age structure of employees by industry. One variable is the change in Chinese imports in a given industry over the sample period divided by gross output in that industry in the initial year of the sample period.Footnote ¹⁰ The second variable is the change in imports from all other countries divided by initial gross output. Both variables are included to allow the impact of Chinese imports on employment to vary from that of the impact of the imports from other countries.

The empirical models have so far included as many as 12 independent variables, a strategy that is not likely to be successful when adding two more variables to a data set with 23 observations. The set of independent variables in Table 5 for the 23-industry sample is restricted to those that have proven to be of critical importance to the model: GDP growth, overall capital–labor ratio, high-tech capital–labor ratio, pension coverage, and the relative wage of older to younger workers. The full set of independent variables is used for the 60-industry sample.

Table 5. Regression results: impact of Chinese and other imports

Independent variables in 23-industry sample include GDP growth, log capital–labor ratio, log high-tech capital–labor ratio, pension coverage, and log wage ratio of older to younger workers. Independent variables in 60-industry sample are the same as in Tables 1–3.

The results for both samples show that the percentage of older workers increased more in those industries with the largest surges in Chinese imports in 2001–2007. Compare two industries one with a 20% change in import penetration and one with no change in import penetration. The growth in the percentage of older workers is 0.8–1.0 percentage points higher between 2001 and 2007 in the industry with the higher degree of new import competition. In the 23-industry sample there is no correlation between Chinese import penetration and the share of older workers between 2007 and 2019. The coefficient for Chinese import penetration for the 60-industry sample is actually more than twice as large in 2007–2019 but the standard error increases to an even greater degree, making it unwise to draw any conclusions for that sample in that time period.

Focusing further on the 2001–2007 period, separate equations estimating the change in the percentage of younger workers were estimated with the same independent variables for the two samples. In the 23-industry sample, the China imports coefficient (S.E.) for young workers was −0.038 (0.053), but it was −0.085 (0.031) in the 60-industry sample. This indicates the surge in Chinese imports led to employment reductions among younger workers.

As for import penetration from countries other than China, the results are mixed. In the 23-industry sample, the percentage of older workers grew more slowly in 2007–2019 in industries with the fastest growth in imports from other countries. However, there was no relationship in any period between import growth from these countries and the change in the share of older workers in the 60-industry sample.

The takeaway from this analysis is that Chinese import growth had a sizable impact on the age structure of industries between 2001 and 2007, mainly by reducing the employment of younger workers relative to older workers. This impact appears to have dissipated in 2007–2019, perhaps because the rate of import growth slowed down.